Trauma

This discussion was recorded on Jan. 9, 2023. This transcript has been edited for clarity.

Robert D. Glatter, MD: Welcome. I’m Dr. Robert D. Glatter, medical adviser for Medscape Emergency Medicine. Today, we have Dr. Paul E. Pepe, an emergency medicine physician based in Florida and a highly recognized expert in emergency medical services (EMS), critical care, sports and event medicine, and resuscitation. Also joining us is Dr. Michael S. (“Mick”) Malloy, an emergency medicine physician based in Ireland, also an expert in prehospital care, resuscitation, and sports and event medicine. Welcome, gentlemen.

Dr. Pepe: Thanks for having us here.

Dr. Glatter: We have a serious event to discuss today. We’re going to be talking about what happened to Damar Hamlin, the Buffalo Bills safety who went down suffering a cardiac arrest in front of millions of people. Although we don’t know the exact cause of the events that transpired, the goal of our discussion is to guide our audience through a systematic approach to evaluation and management of an athlete suffering blunt force chest and neck trauma, and then suffering a cardiac arrest. We do know, obviously, that Damar was successfully resuscitated, thanks to the medical staff and trainers.

Almost 50 years ago, Chuck Hughes, a Detroit Lions receiver, went down and died with just a minute to go in the game and, unfortunately, didn’t survive.

Paul, can you tell me your impressions after viewing the replay of the events that evening? What were the most likely causes of this syncopal event and the subsequent cardiac arrest?

Dr. Pepe: We don’t know anything specifically. It’s being kept private about what the events were. It’s a little bit complicated in a sense that he basically had an extended resuscitation in the hospital. My experience has been that most people that have ventricular fibrillation, from whatever cause, will most likely be waking up on the field if you get to them. I’ve had personal experience with that.

More importantly than when it starts, when someone goes down on the field, both Dr. Malloy and I take a broader view. We don’t get tunnel vision and think, “Oh, it was a traumatic event,” or “It was cardiac event,” and we just have our minds open. There are many things that could make you stop breathing on the field. It could be a neck or a severe head injury, and then any kind of other internal injury that occurs.

When I saw in the video that Damar Hamlin stood up, that made it a less likely to be a spinal injury. He seemed to be physically functioning, and then he suddenly collapsed. That went along with something that looks like a ventricular fibrillation or ventricular tachycardia type of event and made me think right away that it was commotio cordis. I’m not a Latin scholar, but commotio is like commotion. A literal translation might be an agitation of the heart. I was thinking that he probably got hit somewhere in the middle of the chest at the right moment where the heart is resetting in that repolarization phase, like an R-on-T phenomenon, and then caused this sudden ventricular dysrhythmia.

Most people associate it to that because we have a couple of dozen cases a year of people getting hockey pucks or a baseball hitting their chest, which is very common with adolescents. On the other hand, you can’t get it from a blunt injury like this, and it was too early for it to be, say, a direct cardiac contusion, unless there was a direct injury there. It just happened so quickly.

In Europe, they’ve had a large amount of experience with this same kind of problem before, even just from a direct shoulder hit, for example. Mick Malloy is the dean of the faculty of sports and exercise medicine at the Royal College of Surgeons in Ireland and has vast experience, and now he is the person overseeing the procedures for this. Mick, have you had those kinds of experiences as well?

Dr. Molloy: Yes. It’s something that has occurred over recent decades and has been more recognized. I note that in professional sports, it’s a very different thing because you’ve got such huge teams and teams trained to respond very quickly. And that’s the most important thing in this scenario – having a team that is well functioning as a high-class emergency response team ready to get out on to that field very quickly after the person collapses, getting the automated external defibrillator (AED) on, and then recognizing whether there needs to be a shock given or not. The machine will tell you all that.

In our scenario, we run courses called CARES (Care of the Athlete Resuscitation and Emergencies in Sport) to make sure that our team physicians and team physiotherapists and trainers are all speaking as one when an emergency arises.

I don’t worry so much about the professional sport. It’s more with the amateur sports and the kids sports that I get a bit more concerned because there isn’t the same level of medical care there. Having everybody trained in basic life support would be very important to reduce unnecessary deaths from these types of conditions.

As Paul mentioned, there is a very specific cardiac cause in some of these circumstances, where you get hit just at the wrong time and that hit occurs at a particular electrical point in time. It causes this ventricular fibrillation, and the only real treatment there is the defibrillator as quickly as possible.

Dr. Glatter: What you’re saying ultimately is an important part about rapid defibrillation, and at first, cardiopulmonary resuscitation (CPR). People are concerned about whether they should begin CPR. We’re talking about out-of-hospital cardiac arrest that is outside of a football stadium, for example. Some people are obsessed with taking a person’s pulse, and that’s been a point of contention. If someone is unconscious and not breathing, we should start CPR. Wouldn›t you agree? They will wake up quickly if you begin chest compressions if they’re not necessary.

Dr. Pepe: I tell people, just do it. You’re right, people will wake up and feel it if they don’t need it.

Getting back to Mick’s point of having things ready to go, for example, 8 years ago, we had a professional player on the bench who suddenly collapsed right there in front of the entire audience. We immediately did CPR, and we got the AED on. We shocked him and he was ready, willing, and able to get back on the bench again. It turns out he had underlying coronary artery disease, but we got him back right away.

I did an initial study where we placed an AED in a public place at the Chicago O’Hare Airport to see if the public would use these. Most cardiac arrests occur at home, of course, but in public places, that was a good place to try it. We had almost 10 cases the first year. What was fascinating was that we had almost no survivors over the previous decade, even though there were paramedics at the airport. When we put these out there, we had nine people go down that first year, and six people who had never operated an AED or seen one before knew to get one and use it. Every one of those people survived neurologically intact, and almost every person was waking up before traditional responders got there. That’s how effective this is, but you need to know where the AED is.

Dr. Glatter: How to turn it on, where it is, and how to operate it.

Dr. Pepe: That was the point: These rescuers saved lives in the first year, and it was tremendous. Two points I make about it are that one, you need to know where it is, and two, just go turn it on. It gives you the instructions to follow through; just be in the Nike mode, because it basically won’t hurt a person. It’s rare that there’s ever been any complication of that. The machine algorithms are so good.

Dr. Glatter: Mick, I want to turn to you about the European experience. Specifically in Denmark, we know that there’s a large public health initiative to have AEDs accessible. There have been studies showing that when the public is engaged, especially with studies looking at an app when access is available, survivability doubled in the past 10 years from having access to AEDs. What’s your experience in Ireland in terms of public access to defibrillators?

Dr. Molloy: We’ve got two different streams here. There was a big push to have more AEDs at all sports venues. That was great, but some of the sporting clubs put them inside the locked door. I said that there’s no point to that because nobody can access it. You need to have an external building and you need to leave it open. If somebody needs to use it, they need to know how to get it, open it, and get away, and not get in through a locked door to get access to a defibrillator. We have AEDs now in most stadiums and even in small rural areas, where you might have only 200 people turn up for a game.

From another public access side, if you dial in – in our scenario, it’s 112, not 911 –we have Community First Responder groups. In the rural areas, you have local people who’ve been trained in basic life support and community first response who have AEDs. They’ll have periods of the day where they come home from work as a teacher, a nurse, a policeman, or a fireman, and they turn on an app on their phone and say, “I’m available for the next 5 hours.” If there’s a cardiac arrest rung in within 5 miles of their community, they will drive directly there with the AED that they have. We’ve had numerous saves from that in the country because it could take 40 minutes to get an EMS vehicle there, and obviously, time is crucial in these scenarios. Our dispatchers will talk people through CPR, and then the community responders arrive with the AED. It has been a fantastic initiative.

Dr. Pepe: In many places, people have apps on their phones where they’re locked into the system, and it will go off and tell them there is something nearby and even GPS them into it, and it’s been fantastic.

The two points I want to make to responding to what we just heard Dean Malloy say is one, we always have a designated spot to have these in various places. If I’m at City Hall, we always have them near the red elevators on every floor and down at security. In all the public high schools, we always have one right below the clock where everybody can see it. We set it up in a very standardized form that anybody and everybody will know where it is at the time an event happens.

The other point he made about having the response teams is fantastic. I live in a large high rise and there are two complexes with many people here, and many are older, so there’s going to be a higher risk for having an event. In fact, we’ve just had one recently. The concept we developed here was a community emergency response team, where we sometimes have doctors, nurses, and paramedics who live here be on call and be responsible, or you could try to find an AED. More importantly, we made sure everybody here knew where they were and where to get them. We’ve got most of the people trained, and we’re doing more training in what actions to take during these periods of time when such events happen.

Dr. Glatter: Yes, it’s critical. I wanted to point out that we’ve looked at the use of drones, especially here in the United States. There have been some pilot studies looking at their utility in the setting of out-of-hospital cardiac arrest. I want to get both of your thoughts on this and the feasibility of this.

Dr. Molloy: In a rural area, it’s a fantastic idea. You’re going to get something there as the crow flies very quickly. You probably have to look at exactly in, say, a rural area like Ireland of 32,000 square kilometers, how many you›ll have to put, what kind of distances they can realistically cover, and make sure the batteries are charged. Certainly, that’s a very good initiative because with the AEDs, you can’t do anything wrong. You can’t give a shock unless a shock needs to be given. The machine directs you what to do, so somebody who has had no training can pick one of these out of the box and start to work with it quickly and confidently that they can’t do anything wrong.

It’s a great idea. It would be a little expensive potentially at the moment in getting the drones and having that volume of drones around. In the U.S., you have completely different air traffic than we have, and in cities, you have more helicopters flying around. We certainly wouldn’t have that in our cities because that could cause a challenge if you’ve got drones flying around as well. It’s about making it safe that nothing else can go wrong from a drone in somebody else’s flight path.

Dr. Pepe: In my experience, the earlier the intervention, the better the results. There is a limit here in terms of the drones if they just can’t get there soon enough. Having said that, we are so fortunate in the city of Seattle to have most citizens knowing CPR, and we’d get that person resuscitated because they were doing such a good job with the CPR up front.

That’s why you’re going to see the Buffalo Bills player survive neurologically intact – because he did get immediate treatment right then and there. In the future, we may even have some better devices that will actually even restore normal blood flow right then and there while you’re still in cardiac arrest. There are limitations in every case. But on the other hand, it’s exciting and it paid off in this case recently.

Dr. Molloy: Just a point of interest coming from this small little country over here. The first portable defibrillator was developed in Belfast, Ireland, in the back of a cardiac response car. Despite us being a tiny little country, we do have some advances ahead of the United States.
 

Dr. Pepe: That was a breakthrough. Dr. Frank Pantridge and John Geddes did this great work and that caught the imagination of everybody here. At first, they were just going out to give people oxygen and sedate them for their chest pain. It turned out that their defibrillators are what made the difference as they went out there. Absolutely, I have to acknowledge the folks in Ireland for giving us this. Many of the EMS systems got started because of the article they published in The Lancet back in 1967.

Dr. Glatter: I wanted to briefly talk about screening of the athletes at the high school/college level, but also at the professional level. Obviously, there are issues, including the risk for false-positives in terms of low incidence, but there are also false negatives, as the case with Christian Eriksen, who had a cardiac arrest in 2021 and who has been through extensive testing. We can debate the validity of such testing, but I wanted to get both of your takes on the utility of screening in such a population.

Dr. Molloy: That’s a very emotive subject. False-positives are difficult because you’re now saying to somebody that they can’t compete in your sport at a decent level. The difficult part is telling somebody that this is the end of their career.

The false-negative is a little bit more difficult. I don’t know Christian Eriksen and I’m not involved in his team in any way, but that is a one-point examination, and you’re dependent on the scale of the process interpreting the ECG, which is again only a couple of seconds and that particular arrhythmia may not have shown up on that.

Also, athletes, by nature of what they’re doing, are operating at 99% of efficiency on a frequent basis. They are at the peak of their physiologic fitness, and it does make them a little bit more prone to picking up viral illnesses from time to time. They may get a small viral myopericarditis, which causes a new arrhythmia that nobody knew about. They had the screening 2 or 3 years ago, and they now developed a new problem because of what they do, which just may not show up.

I was actually surprised that the gentleman came through it very well, which is fantastic. He wasn’t allowed to play football in the country where he was employed, and he has now moved to another country and is playing football with a defibrillator inserted. I don’t know what the rules are in American football where you can play with implantable defibrillators. I’m not so sure it’s a great idea to do that.

Dr. Pepe: One thing that we should bring up is that there are athletes with underlying cardiomyopathies or hypertrophies and things like that, but that was unlikely in this case. It’s possible, but it’s unlikely, because it would have manifested itself before. In terms of screening, I’ve met some very smart medical doctors who have run those tests, and they have been very encouraged even at the high school levels to have screenings done, whether it’s electrocardiography, echocardiography, and so on. I have to reiterate what Dr Malloy just said in that it may have its downsides as well. If you can pick up real obvious cases, I think that may be of value.

Dr. Glatter: I want to conclude and get some pearls and takeaways from each of you regarding the events that transpired and what our audience can really hold onto.

Dr. Molloy: Look at Formula One in the past 50 years. In Formula One, in the beginning it was a 2-minute job to change a tire. Now, they have this down where they’re measuring in fractions of a second and criticizing each other if one guy is 2.6 seconds and the other guy is 2.9 seconds. For me, that’s phenomenal. It takes me 25 minutes to change a tire.

We’ve looked at that from a resuscitation perspective, and we now do pit crew resuscitation before our events. We’ve planned our team and know who’s going to be occupying what role. After the events at the UEFA championships, we had a new rule brought in by UEFA where they handed me a new document saying, “This is what we would like you to do for resuscitation.” It was a three-man triangle, and I said, “No, we’re not going to do that here.” And they said, “Why, you have to; it’s our rule.”

I said, “No, our rule in Ireland is we have a six-person triangle. We’re not downing our standards because of what you have internationally. You’re covering games in some very low-resource environments, I know that. We have a particular standard here that we’re sticking to. We have a six-person group. We know what we’re all doing; we come very quickly to those downed players and get involved and we’ve had good outcomes, so we’re not going to change the standards.”

That’s the thing: You need to practice these things. The players don’t go out on the weekend and do a move for the very first time without practicing it hundreds of times. We need to look at it the same way as the medical team who are looking after that group of players and the crowd because we also look after the crowd.

A particular challenge in some of our stadiums is that the upper decks are so steep, and it’s very hard to get a patient onto a trolley and do CPR as you’re bringing them down to a zone to get them flat. We’ve had to come up with some innovative techniques to try and do that and accommodate that using some of the mechanical CPR devices. That’s the result you’ll only get from having practiced these events and trying to extricate patients. We want to check response times, so you have to practice your response team activity very frequently.

Dr. Pepe: There are two points made by Mick that I want to react to. One, the pit crew approach is critical in so many ways. We do the same thing in what we call the medical first attack, where we knew who the A, B, and C person would be. When we took it out to the NBA trainers, I recommended for them to have a similar approach so that if an event does happen right in the middle of prime time, they are coordinated.

The second point is that we do mass-gathering medicine. It’s not just the sportspeople on the field or the entertainers that we’re looking after; it is the people in the stands. We will see a cardiac arrest once a month. If you think about it, you might see a cardiac arrest occur in any community on a regular basis. Now you’ve got 100,000 people in one stadium, and something is bound to go wrong over those 3 or 4 hours where they are there and may have a critical emergency. Preparation for all of that is really important as well.

The final point is that on a day-to-day basis, most cardiac arrests do occur in the home. Granted, 80% of them are nonshockable cases, but the people who are more apt to survive are going to be the ones who have an electrical event. In fact, when we looked at our data years ago, we found that, of the cases of people with ventricular fibrillation that we resuscitated, half didn’t even have heart damage. Their enzymes were normal. It was a pure electrical event, and they were more resuscitable. They may have an underlying problem, but we can fix that once we get them back.

Everybody needs to know how to do bystander CPR, and second, we must make sure we have AEDs strategically placed, as I alluded to before. We also go out to other parts of the community and give them advice. All those things must be put in place, but more importantly, just get the training and make the training simple. It’s really a “just do it” philosophy, but make it simple.

For example, when I teach a course, I can do it in 15 minutes, and people retain it because I keep reiterating things like, “Okay, there’s one thing you need to know about choking: Pop the cork.” You give them a physiologic image of what’s happening. Everybody says, “I remember you saying to just do it, pop the cork.”

With AEDs, know where it is – that’s why we should have it in standardized places. Go get it, turn it on, and then follow the instructions. Also, the most important thing is making sure you’re doing quality compressions; and there are videos that can help you with that, as well as classes that you can take that will get you through it.

Dr. Glatter: Absolutely. The public still has the misconception that you need to do mouth-to-mouth resuscitation. The message has not permeated through society that you don’t need to do mouth-to-mouth. Hands-only CPR is the gold standard now.

Dr. Pepe: If people have a reversible cause like ventricular fibrillation, often they’re already gasping, which is better than a delivered breath, by the way. Most important, then, are the compressions to make sure you have oxygen going up to the brain, because you’re still theoretically loaded with oxygen in your bloodstream if you had a sudden cardiac arrest from a ventricular fibrillation.

Your points are well taken, and we found that we had better outcomes when we just gave instructions to do compressions only, and that became the standard. Mick, you’ve had some experiences with that as well.

Dr. Molloy: If we’re going to have a long-term benefit from all this, we have to start doing this in elementary school and teaching kids basic life support and some basic health messaging.

I remember trying to get this across to a teacher one day and the teacher saying, “But why would we teach young kids to resuscitate each other?” I said, “I think you forget that the only 60-year-old person in the room is you. You train them, and we train them. They’re the ones who are going to respond and keep you alive. That’s the way you should be looking at this.” That completely changed the mindset of whether we should be doing this for the kids or not.

Dr. Pepe: In fact, what we find is that that’s exactly who gets saved. I had case after case where the kids at the school had learned CPR and saved the teachers or the administrator at the high school or elementary school. It’s a fantastic point that you bring up, Dr. Malloy.

Dr. Glatter: One other brief thing we can interject here is that the team was excellent on field in that they evaluated Damar Hamlin in a primary survey sense of ABCs (i.e., airway, breathing, and circulation) for things like a tension pneumothorax. In the sense in which he was hit, there are reversible causes. Making sure he didn’t have a tension pneumothorax that caused the arrest, in my mind, was critical.

Dr. Pepe: We do the same thing on a day-to-day basis with a car wreck, because it could be that the person had ventricular fibrillation and then had the wreck. It’s not always trauma. That’s a fantastic point that you’re making. That’s exactly what I think happened, and that’s what we do.

Dr. Glatter: Well, thank you, gentlemen. This was an informative and helpful discussion for our audience. I appreciate your time and expertise.



Dr. Glatter, is an attending physician at Lenox Hill Hospital in New York City and assistant professor of emergency medicine at Zucker School of Medicine at Hofstra/Northwell in Hempstead, New York. He is an editorial adviser and hosts the Hot Topics in EM series on Medscape. He is also a medical contributor for Forbes.

Dr. Pepe is a professor of internal medicine, surgery, pediatrics, public health, and emergency medicine at University of Texas Health Science Center in Houston. He’s also a global coordinator of the U.S. Metropolitan Municipalities EMS Medical Directors (“Eagles”) Coalition.

Dr. Molloy works clinically as a consultant in emergency medicine in Wexford General Hospital, part of the Ireland East Hospital Group (IEHG). Internationally, he is a member of the Disaster Medicine Section of the European Society of Emergency Medicine (EUSEM) and has been appointed by the Irish Medical Organization (IMO) as one of two Irish delegates to serve on the European Board and Section of Emergency Medicine of the European Union of Medical Specialists (UEMS), having served for a number of years on its predecessor, the Multidisciplinary Joint Committee on Emergency Medicine.

A version of this article first appeared on Medscape.com.

This discussion was recorded on Jan. 9, 2023. This transcript has been edited for clarity.

Robert D. Glatter, MD: Welcome. I’m Dr. Robert D. Glatter, medical adviser for Medscape Emergency Medicine. Today, we have Dr. Paul E. Pepe, an emergency medicine physician based in Florida and a highly recognized expert in emergency medical services (EMS), critical care, sports and event medicine, and resuscitation. Also joining us is Dr. Michael S. (“Mick”) Malloy, an emergency medicine physician based in Ireland, also an expert in prehospital care, resuscitation, and sports and event medicine. Welcome, gentlemen.

Dr. Pepe: Thanks for having us here.

Dr. Glatter: We have a serious event to discuss today. We’re going to be talking about what happened to Damar Hamlin, the Buffalo Bills safety who went down suffering a cardiac arrest in front of millions of people. Although we don’t know the exact cause of the events that transpired, the goal of our discussion is to guide our audience through a systematic approach to evaluation and management of an athlete suffering blunt force chest and neck trauma, and then suffering a cardiac arrest. We do know, obviously, that Damar was successfully resuscitated, thanks to the medical staff and trainers.

Almost 50 years ago, Chuck Hughes, a Detroit Lions receiver, went down and died with just a minute to go in the game and, unfortunately, didn’t survive.

Paul, can you tell me your impressions after viewing the replay of the events that evening? What were the most likely causes of this syncopal event and the subsequent cardiac arrest?

Dr. Pepe: We don’t know anything specifically. It’s being kept private about what the events were. It’s a little bit complicated in a sense that he basically had an extended resuscitation in the hospital. My experience has been that most people that have ventricular fibrillation, from whatever cause, will most likely be waking up on the field if you get to them. I’ve had personal experience with that.

More importantly than when it starts, when someone goes down on the field, both Dr. Malloy and I take a broader view. We don’t get tunnel vision and think, “Oh, it was a traumatic event,” or “It was cardiac event,” and we just have our minds open. There are many things that could make you stop breathing on the field. It could be a neck or a severe head injury, and then any kind of other internal injury that occurs.

When I saw in the video that Damar Hamlin stood up, that made it a less likely to be a spinal injury. He seemed to be physically functioning, and then he suddenly collapsed. That went along with something that looks like a ventricular fibrillation or ventricular tachycardia type of event and made me think right away that it was commotio cordis. I’m not a Latin scholar, but commotio is like commotion. A literal translation might be an agitation of the heart. I was thinking that he probably got hit somewhere in the middle of the chest at the right moment where the heart is resetting in that repolarization phase, like an R-on-T phenomenon, and then caused this sudden ventricular dysrhythmia.

Most people associate it to that because we have a couple of dozen cases a year of people getting hockey pucks or a baseball hitting their chest, which is very common with adolescents. On the other hand, you can’t get it from a blunt injury like this, and it was too early for it to be, say, a direct cardiac contusion, unless there was a direct injury there. It just happened so quickly.

In Europe, they’ve had a large amount of experience with this same kind of problem before, even just from a direct shoulder hit, for example. Mick Malloy is the dean of the faculty of sports and exercise medicine at the Royal College of Surgeons in Ireland and has vast experience, and now he is the person overseeing the procedures for this. Mick, have you had those kinds of experiences as well?

Dr. Molloy: Yes. It’s something that has occurred over recent decades and has been more recognized. I note that in professional sports, it’s a very different thing because you’ve got such huge teams and teams trained to respond very quickly. And that’s the most important thing in this scenario – having a team that is well functioning as a high-class emergency response team ready to get out on to that field very quickly after the person collapses, getting the automated external defibrillator (AED) on, and then recognizing whether there needs to be a shock given or not. The machine will tell you all that.

In our scenario, we run courses called CARES (Care of the Athlete Resuscitation and Emergencies in Sport) to make sure that our team physicians and team physiotherapists and trainers are all speaking as one when an emergency arises.

I don’t worry so much about the professional sport. It’s more with the amateur sports and the kids sports that I get a bit more concerned because there isn’t the same level of medical care there. Having everybody trained in basic life support would be very important to reduce unnecessary deaths from these types of conditions.

As Paul mentioned, there is a very specific cardiac cause in some of these circumstances, where you get hit just at the wrong time and that hit occurs at a particular electrical point in time. It causes this ventricular fibrillation, and the only real treatment there is the defibrillator as quickly as possible.

Dr. Glatter: What you’re saying ultimately is an important part about rapid defibrillation, and at first, cardiopulmonary resuscitation (CPR). People are concerned about whether they should begin CPR. We’re talking about out-of-hospital cardiac arrest that is outside of a football stadium, for example. Some people are obsessed with taking a person’s pulse, and that’s been a point of contention. If someone is unconscious and not breathing, we should start CPR. Wouldn›t you agree? They will wake up quickly if you begin chest compressions if they’re not necessary.

Dr. Pepe: I tell people, just do it. You’re right, people will wake up and feel it if they don’t need it.

Getting back to Mick’s point of having things ready to go, for example, 8 years ago, we had a professional player on the bench who suddenly collapsed right there in front of the entire audience. We immediately did CPR, and we got the AED on. We shocked him and he was ready, willing, and able to get back on the bench again. It turns out he had underlying coronary artery disease, but we got him back right away.

I did an initial study where we placed an AED in a public place at the Chicago O’Hare Airport to see if the public would use these. Most cardiac arrests occur at home, of course, but in public places, that was a good place to try it. We had almost 10 cases the first year. What was fascinating was that we had almost no survivors over the previous decade, even though there were paramedics at the airport. When we put these out there, we had nine people go down that first year, and six people who had never operated an AED or seen one before knew to get one and use it. Every one of those people survived neurologically intact, and almost every person was waking up before traditional responders got there. That’s how effective this is, but you need to know where the AED is.

Dr. Glatter: How to turn it on, where it is, and how to operate it.

Dr. Pepe: That was the point: These rescuers saved lives in the first year, and it was tremendous. Two points I make about it are that one, you need to know where it is, and two, just go turn it on. It gives you the instructions to follow through; just be in the Nike mode, because it basically won’t hurt a person. It’s rare that there’s ever been any complication of that. The machine algorithms are so good.

Dr. Glatter: Mick, I want to turn to you about the European experience. Specifically in Denmark, we know that there’s a large public health initiative to have AEDs accessible. There have been studies showing that when the public is engaged, especially with studies looking at an app when access is available, survivability doubled in the past 10 years from having access to AEDs. What’s your experience in Ireland in terms of public access to defibrillators?

Dr. Molloy: We’ve got two different streams here. There was a big push to have more AEDs at all sports venues. That was great, but some of the sporting clubs put them inside the locked door. I said that there’s no point to that because nobody can access it. You need to have an external building and you need to leave it open. If somebody needs to use it, they need to know how to get it, open it, and get away, and not get in through a locked door to get access to a defibrillator. We have AEDs now in most stadiums and even in small rural areas, where you might have only 200 people turn up for a game.

From another public access side, if you dial in – in our scenario, it’s 112, not 911 –we have Community First Responder groups. In the rural areas, you have local people who’ve been trained in basic life support and community first response who have AEDs. They’ll have periods of the day where they come home from work as a teacher, a nurse, a policeman, or a fireman, and they turn on an app on their phone and say, “I’m available for the next 5 hours.” If there’s a cardiac arrest rung in within 5 miles of their community, they will drive directly there with the AED that they have. We’ve had numerous saves from that in the country because it could take 40 minutes to get an EMS vehicle there, and obviously, time is crucial in these scenarios. Our dispatchers will talk people through CPR, and then the community responders arrive with the AED. It has been a fantastic initiative.

Dr. Pepe: In many places, people have apps on their phones where they’re locked into the system, and it will go off and tell them there is something nearby and even GPS them into it, and it’s been fantastic.

The two points I want to make to responding to what we just heard Dean Malloy say is one, we always have a designated spot to have these in various places. If I’m at City Hall, we always have them near the red elevators on every floor and down at security. In all the public high schools, we always have one right below the clock where everybody can see it. We set it up in a very standardized form that anybody and everybody will know where it is at the time an event happens.

The other point he made about having the response teams is fantastic. I live in a large high rise and there are two complexes with many people here, and many are older, so there’s going to be a higher risk for having an event. In fact, we’ve just had one recently. The concept we developed here was a community emergency response team, where we sometimes have doctors, nurses, and paramedics who live here be on call and be responsible, or you could try to find an AED. More importantly, we made sure everybody here knew where they were and where to get them. We’ve got most of the people trained, and we’re doing more training in what actions to take during these periods of time when such events happen.

Dr. Glatter: Yes, it’s critical. I wanted to point out that we’ve looked at the use of drones, especially here in the United States. There have been some pilot studies looking at their utility in the setting of out-of-hospital cardiac arrest. I want to get both of your thoughts on this and the feasibility of this.

Dr. Molloy: In a rural area, it’s a fantastic idea. You’re going to get something there as the crow flies very quickly. You probably have to look at exactly in, say, a rural area like Ireland of 32,000 square kilometers, how many you›ll have to put, what kind of distances they can realistically cover, and make sure the batteries are charged. Certainly, that’s a very good initiative because with the AEDs, you can’t do anything wrong. You can’t give a shock unless a shock needs to be given. The machine directs you what to do, so somebody who has had no training can pick one of these out of the box and start to work with it quickly and confidently that they can’t do anything wrong.

It’s a great idea. It would be a little expensive potentially at the moment in getting the drones and having that volume of drones around. In the U.S., you have completely different air traffic than we have, and in cities, you have more helicopters flying around. We certainly wouldn’t have that in our cities because that could cause a challenge if you’ve got drones flying around as well. It’s about making it safe that nothing else can go wrong from a drone in somebody else’s flight path.

Dr. Pepe: In my experience, the earlier the intervention, the better the results. There is a limit here in terms of the drones if they just can’t get there soon enough. Having said that, we are so fortunate in the city of Seattle to have most citizens knowing CPR, and we’d get that person resuscitated because they were doing such a good job with the CPR up front.

That’s why you’re going to see the Buffalo Bills player survive neurologically intact – because he did get immediate treatment right then and there. In the future, we may even have some better devices that will actually even restore normal blood flow right then and there while you’re still in cardiac arrest. There are limitations in every case. But on the other hand, it’s exciting and it paid off in this case recently.

Dr. Molloy: Just a point of interest coming from this small little country over here. The first portable defibrillator was developed in Belfast, Ireland, in the back of a cardiac response car. Despite us being a tiny little country, we do have some advances ahead of the United States.
 

Dr. Pepe: That was a breakthrough. Dr. Frank Pantridge and John Geddes did this great work and that caught the imagination of everybody here. At first, they were just going out to give people oxygen and sedate them for their chest pain. It turned out that their defibrillators are what made the difference as they went out there. Absolutely, I have to acknowledge the folks in Ireland for giving us this. Many of the EMS systems got started because of the article they published in The Lancet back in 1967.

Dr. Glatter: I wanted to briefly talk about screening of the athletes at the high school/college level, but also at the professional level. Obviously, there are issues, including the risk for false-positives in terms of low incidence, but there are also false negatives, as the case with Christian Eriksen, who had a cardiac arrest in 2021 and who has been through extensive testing. We can debate the validity of such testing, but I wanted to get both of your takes on the utility of screening in such a population.

Dr. Molloy: That’s a very emotive subject. False-positives are difficult because you’re now saying to somebody that they can’t compete in your sport at a decent level. The difficult part is telling somebody that this is the end of their career.

The false-negative is a little bit more difficult. I don’t know Christian Eriksen and I’m not involved in his team in any way, but that is a one-point examination, and you’re dependent on the scale of the process interpreting the ECG, which is again only a couple of seconds and that particular arrhythmia may not have shown up on that.

Also, athletes, by nature of what they’re doing, are operating at 99% of efficiency on a frequent basis. They are at the peak of their physiologic fitness, and it does make them a little bit more prone to picking up viral illnesses from time to time. They may get a small viral myopericarditis, which causes a new arrhythmia that nobody knew about. They had the screening 2 or 3 years ago, and they now developed a new problem because of what they do, which just may not show up.

I was actually surprised that the gentleman came through it very well, which is fantastic. He wasn’t allowed to play football in the country where he was employed, and he has now moved to another country and is playing football with a defibrillator inserted. I don’t know what the rules are in American football where you can play with implantable defibrillators. I’m not so sure it’s a great idea to do that.

Dr. Pepe: One thing that we should bring up is that there are athletes with underlying cardiomyopathies or hypertrophies and things like that, but that was unlikely in this case. It’s possible, but it’s unlikely, because it would have manifested itself before. In terms of screening, I’ve met some very smart medical doctors who have run those tests, and they have been very encouraged even at the high school levels to have screenings done, whether it’s electrocardiography, echocardiography, and so on. I have to reiterate what Dr Malloy just said in that it may have its downsides as well. If you can pick up real obvious cases, I think that may be of value.

Dr. Glatter: I want to conclude and get some pearls and takeaways from each of you regarding the events that transpired and what our audience can really hold onto.

Dr. Molloy: Look at Formula One in the past 50 years. In Formula One, in the beginning it was a 2-minute job to change a tire. Now, they have this down where they’re measuring in fractions of a second and criticizing each other if one guy is 2.6 seconds and the other guy is 2.9 seconds. For me, that’s phenomenal. It takes me 25 minutes to change a tire.

We’ve looked at that from a resuscitation perspective, and we now do pit crew resuscitation before our events. We’ve planned our team and know who’s going to be occupying what role. After the events at the UEFA championships, we had a new rule brought in by UEFA where they handed me a new document saying, “This is what we would like you to do for resuscitation.” It was a three-man triangle, and I said, “No, we’re not going to do that here.” And they said, “Why, you have to; it’s our rule.”

I said, “No, our rule in Ireland is we have a six-person triangle. We’re not downing our standards because of what you have internationally. You’re covering games in some very low-resource environments, I know that. We have a particular standard here that we’re sticking to. We have a six-person group. We know what we’re all doing; we come very quickly to those downed players and get involved and we’ve had good outcomes, so we’re not going to change the standards.”

That’s the thing: You need to practice these things. The players don’t go out on the weekend and do a move for the very first time without practicing it hundreds of times. We need to look at it the same way as the medical team who are looking after that group of players and the crowd because we also look after the crowd.

A particular challenge in some of our stadiums is that the upper decks are so steep, and it’s very hard to get a patient onto a trolley and do CPR as you’re bringing them down to a zone to get them flat. We’ve had to come up with some innovative techniques to try and do that and accommodate that using some of the mechanical CPR devices. That’s the result you’ll only get from having practiced these events and trying to extricate patients. We want to check response times, so you have to practice your response team activity very frequently.

Dr. Pepe: There are two points made by Mick that I want to react to. One, the pit crew approach is critical in so many ways. We do the same thing in what we call the medical first attack, where we knew who the A, B, and C person would be. When we took it out to the NBA trainers, I recommended for them to have a similar approach so that if an event does happen right in the middle of prime time, they are coordinated.

The second point is that we do mass-gathering medicine. It’s not just the sportspeople on the field or the entertainers that we’re looking after; it is the people in the stands. We will see a cardiac arrest once a month. If you think about it, you might see a cardiac arrest occur in any community on a regular basis. Now you’ve got 100,000 people in one stadium, and something is bound to go wrong over those 3 or 4 hours where they are there and may have a critical emergency. Preparation for all of that is really important as well.

The final point is that on a day-to-day basis, most cardiac arrests do occur in the home. Granted, 80% of them are nonshockable cases, but the people who are more apt to survive are going to be the ones who have an electrical event. In fact, when we looked at our data years ago, we found that, of the cases of people with ventricular fibrillation that we resuscitated, half didn’t even have heart damage. Their enzymes were normal. It was a pure electrical event, and they were more resuscitable. They may have an underlying problem, but we can fix that once we get them back.

Everybody needs to know how to do bystander CPR, and second, we must make sure we have AEDs strategically placed, as I alluded to before. We also go out to other parts of the community and give them advice. All those things must be put in place, but more importantly, just get the training and make the training simple. It’s really a “just do it” philosophy, but make it simple.

For example, when I teach a course, I can do it in 15 minutes, and people retain it because I keep reiterating things like, “Okay, there’s one thing you need to know about choking: Pop the cork.” You give them a physiologic image of what’s happening. Everybody says, “I remember you saying to just do it, pop the cork.”

With AEDs, know where it is – that’s why we should have it in standardized places. Go get it, turn it on, and then follow the instructions. Also, the most important thing is making sure you’re doing quality compressions; and there are videos that can help you with that, as well as classes that you can take that will get you through it.

Dr. Glatter: Absolutely. The public still has the misconception that you need to do mouth-to-mouth resuscitation. The message has not permeated through society that you don’t need to do mouth-to-mouth. Hands-only CPR is the gold standard now.

Dr. Pepe: If people have a reversible cause like ventricular fibrillation, often they’re already gasping, which is better than a delivered breath, by the way. Most important, then, are the compressions to make sure you have oxygen going up to the brain, because you’re still theoretically loaded with oxygen in your bloodstream if you had a sudden cardiac arrest from a ventricular fibrillation.

Your points are well taken, and we found that we had better outcomes when we just gave instructions to do compressions only, and that became the standard. Mick, you’ve had some experiences with that as well.

Dr. Molloy: If we’re going to have a long-term benefit from all this, we have to start doing this in elementary school and teaching kids basic life support and some basic health messaging.

I remember trying to get this across to a teacher one day and the teacher saying, “But why would we teach young kids to resuscitate each other?” I said, “I think you forget that the only 60-year-old person in the room is you. You train them, and we train them. They’re the ones who are going to respond and keep you alive. That’s the way you should be looking at this.” That completely changed the mindset of whether we should be doing this for the kids or not.

Dr. Pepe: In fact, what we find is that that’s exactly who gets saved. I had case after case where the kids at the school had learned CPR and saved the teachers or the administrator at the high school or elementary school. It’s a fantastic point that you bring up, Dr. Malloy.

Dr. Glatter: One other brief thing we can interject here is that the team was excellent on field in that they evaluated Damar Hamlin in a primary survey sense of ABCs (i.e., airway, breathing, and circulation) for things like a tension pneumothorax. In the sense in which he was hit, there are reversible causes. Making sure he didn’t have a tension pneumothorax that caused the arrest, in my mind, was critical.

Dr. Pepe: We do the same thing on a day-to-day basis with a car wreck, because it could be that the person had ventricular fibrillation and then had the wreck. It’s not always trauma. That’s a fantastic point that you’re making. That’s exactly what I think happened, and that’s what we do.

Dr. Glatter: Well, thank you, gentlemen. This was an informative and helpful discussion for our audience. I appreciate your time and expertise.



Dr. Glatter, is an attending physician at Lenox Hill Hospital in New York City and assistant professor of emergency medicine at Zucker School of Medicine at Hofstra/Northwell in Hempstead, New York. He is an editorial adviser and hosts the Hot Topics in EM series on Medscape. He is also a medical contributor for Forbes.

Dr. Pepe is a professor of internal medicine, surgery, pediatrics, public health, and emergency medicine at University of Texas Health Science Center in Houston. He’s also a global coordinator of the U.S. Metropolitan Municipalities EMS Medical Directors (“Eagles”) Coalition.

Dr. Molloy works clinically as a consultant in emergency medicine in Wexford General Hospital, part of the Ireland East Hospital Group (IEHG). Internationally, he is a member of the Disaster Medicine Section of the European Society of Emergency Medicine (EUSEM) and has been appointed by the Irish Medical Organization (IMO) as one of two Irish delegates to serve on the European Board and Section of Emergency Medicine of the European Union of Medical Specialists (UEMS), having served for a number of years on its predecessor, the Multidisciplinary Joint Committee on Emergency Medicine.

A version of this article first appeared on Medscape.com.

This discussion was recorded on Jan. 9, 2023. This transcript has been edited for clarity.

Robert D. Glatter, MD: Welcome. I’m Dr. Robert D. Glatter, medical adviser for Medscape Emergency Medicine. Today, we have Dr. Paul E. Pepe, an emergency medicine physician based in Florida and a highly recognized expert in emergency medical services (EMS), critical care, sports and event medicine, and resuscitation. Also joining us is Dr. Michael S. (“Mick”) Malloy, an emergency medicine physician based in Ireland, also an expert in prehospital care, resuscitation, and sports and event medicine. Welcome, gentlemen.

Dr. Pepe: Thanks for having us here.

Dr. Glatter: We have a serious event to discuss today. We’re going to be talking about what happened to Damar Hamlin, the Buffalo Bills safety who went down suffering a cardiac arrest in front of millions of people. Although we don’t know the exact cause of the events that transpired, the goal of our discussion is to guide our audience through a systematic approach to evaluation and management of an athlete suffering blunt force chest and neck trauma, and then suffering a cardiac arrest. We do know, obviously, that Damar was successfully resuscitated, thanks to the medical staff and trainers.

Almost 50 years ago, Chuck Hughes, a Detroit Lions receiver, went down and died with just a minute to go in the game and, unfortunately, didn’t survive.

Paul, can you tell me your impressions after viewing the replay of the events that evening? What were the most likely causes of this syncopal event and the subsequent cardiac arrest?

Dr. Pepe: We don’t know anything specifically. It’s being kept private about what the events were. It’s a little bit complicated in a sense that he basically had an extended resuscitation in the hospital. My experience has been that most people that have ventricular fibrillation, from whatever cause, will most likely be waking up on the field if you get to them. I’ve had personal experience with that.

More importantly than when it starts, when someone goes down on the field, both Dr. Malloy and I take a broader view. We don’t get tunnel vision and think, “Oh, it was a traumatic event,” or “It was cardiac event,” and we just have our minds open. There are many things that could make you stop breathing on the field. It could be a neck or a severe head injury, and then any kind of other internal injury that occurs.

When I saw in the video that Damar Hamlin stood up, that made it a less likely to be a spinal injury. He seemed to be physically functioning, and then he suddenly collapsed. That went along with something that looks like a ventricular fibrillation or ventricular tachycardia type of event and made me think right away that it was commotio cordis. I’m not a Latin scholar, but commotio is like commotion. A literal translation might be an agitation of the heart. I was thinking that he probably got hit somewhere in the middle of the chest at the right moment where the heart is resetting in that repolarization phase, like an R-on-T phenomenon, and then caused this sudden ventricular dysrhythmia.

Most people associate it to that because we have a couple of dozen cases a year of people getting hockey pucks or a baseball hitting their chest, which is very common with adolescents. On the other hand, you can’t get it from a blunt injury like this, and it was too early for it to be, say, a direct cardiac contusion, unless there was a direct injury there. It just happened so quickly.

In Europe, they’ve had a large amount of experience with this same kind of problem before, even just from a direct shoulder hit, for example. Mick Malloy is the dean of the faculty of sports and exercise medicine at the Royal College of Surgeons in Ireland and has vast experience, and now he is the person overseeing the procedures for this. Mick, have you had those kinds of experiences as well?

Dr. Molloy: Yes. It’s something that has occurred over recent decades and has been more recognized. I note that in professional sports, it’s a very different thing because you’ve got such huge teams and teams trained to respond very quickly. And that’s the most important thing in this scenario – having a team that is well functioning as a high-class emergency response team ready to get out on to that field very quickly after the person collapses, getting the automated external defibrillator (AED) on, and then recognizing whether there needs to be a shock given or not. The machine will tell you all that.

In our scenario, we run courses called CARES (Care of the Athlete Resuscitation and Emergencies in Sport) to make sure that our team physicians and team physiotherapists and trainers are all speaking as one when an emergency arises.

I don’t worry so much about the professional sport. It’s more with the amateur sports and the kids sports that I get a bit more concerned because there isn’t the same level of medical care there. Having everybody trained in basic life support would be very important to reduce unnecessary deaths from these types of conditions.

As Paul mentioned, there is a very specific cardiac cause in some of these circumstances, where you get hit just at the wrong time and that hit occurs at a particular electrical point in time. It causes this ventricular fibrillation, and the only real treatment there is the defibrillator as quickly as possible.

Dr. Glatter: What you’re saying ultimately is an important part about rapid defibrillation, and at first, cardiopulmonary resuscitation (CPR). People are concerned about whether they should begin CPR. We’re talking about out-of-hospital cardiac arrest that is outside of a football stadium, for example. Some people are obsessed with taking a person’s pulse, and that’s been a point of contention. If someone is unconscious and not breathing, we should start CPR. Wouldn›t you agree? They will wake up quickly if you begin chest compressions if they’re not necessary.

Dr. Pepe: I tell people, just do it. You’re right, people will wake up and feel it if they don’t need it.

Getting back to Mick’s point of having things ready to go, for example, 8 years ago, we had a professional player on the bench who suddenly collapsed right there in front of the entire audience. We immediately did CPR, and we got the AED on. We shocked him and he was ready, willing, and able to get back on the bench again. It turns out he had underlying coronary artery disease, but we got him back right away.

I did an initial study where we placed an AED in a public place at the Chicago O’Hare Airport to see if the public would use these. Most cardiac arrests occur at home, of course, but in public places, that was a good place to try it. We had almost 10 cases the first year. What was fascinating was that we had almost no survivors over the previous decade, even though there were paramedics at the airport. When we put these out there, we had nine people go down that first year, and six people who had never operated an AED or seen one before knew to get one and use it. Every one of those people survived neurologically intact, and almost every person was waking up before traditional responders got there. That’s how effective this is, but you need to know where the AED is.

Dr. Glatter: How to turn it on, where it is, and how to operate it.

Dr. Pepe: That was the point: These rescuers saved lives in the first year, and it was tremendous. Two points I make about it are that one, you need to know where it is, and two, just go turn it on. It gives you the instructions to follow through; just be in the Nike mode, because it basically won’t hurt a person. It’s rare that there’s ever been any complication of that. The machine algorithms are so good.

Dr. Glatter: Mick, I want to turn to you about the European experience. Specifically in Denmark, we know that there’s a large public health initiative to have AEDs accessible. There have been studies showing that when the public is engaged, especially with studies looking at an app when access is available, survivability doubled in the past 10 years from having access to AEDs. What’s your experience in Ireland in terms of public access to defibrillators?

Dr. Molloy: We’ve got two different streams here. There was a big push to have more AEDs at all sports venues. That was great, but some of the sporting clubs put them inside the locked door. I said that there’s no point to that because nobody can access it. You need to have an external building and you need to leave it open. If somebody needs to use it, they need to know how to get it, open it, and get away, and not get in through a locked door to get access to a defibrillator. We have AEDs now in most stadiums and even in small rural areas, where you might have only 200 people turn up for a game.

From another public access side, if you dial in – in our scenario, it’s 112, not 911 –we have Community First Responder groups. In the rural areas, you have local people who’ve been trained in basic life support and community first response who have AEDs. They’ll have periods of the day where they come home from work as a teacher, a nurse, a policeman, or a fireman, and they turn on an app on their phone and say, “I’m available for the next 5 hours.” If there’s a cardiac arrest rung in within 5 miles of their community, they will drive directly there with the AED that they have. We’ve had numerous saves from that in the country because it could take 40 minutes to get an EMS vehicle there, and obviously, time is crucial in these scenarios. Our dispatchers will talk people through CPR, and then the community responders arrive with the AED. It has been a fantastic initiative.

Dr. Pepe: In many places, people have apps on their phones where they’re locked into the system, and it will go off and tell them there is something nearby and even GPS them into it, and it’s been fantastic.

The two points I want to make to responding to what we just heard Dean Malloy say is one, we always have a designated spot to have these in various places. If I’m at City Hall, we always have them near the red elevators on every floor and down at security. In all the public high schools, we always have one right below the clock where everybody can see it. We set it up in a very standardized form that anybody and everybody will know where it is at the time an event happens.

The other point he made about having the response teams is fantastic. I live in a large high rise and there are two complexes with many people here, and many are older, so there’s going to be a higher risk for having an event. In fact, we’ve just had one recently. The concept we developed here was a community emergency response team, where we sometimes have doctors, nurses, and paramedics who live here be on call and be responsible, or you could try to find an AED. More importantly, we made sure everybody here knew where they were and where to get them. We’ve got most of the people trained, and we’re doing more training in what actions to take during these periods of time when such events happen.

Dr. Glatter: Yes, it’s critical. I wanted to point out that we’ve looked at the use of drones, especially here in the United States. There have been some pilot studies looking at their utility in the setting of out-of-hospital cardiac arrest. I want to get both of your thoughts on this and the feasibility of this.

Dr. Molloy: In a rural area, it’s a fantastic idea. You’re going to get something there as the crow flies very quickly. You probably have to look at exactly in, say, a rural area like Ireland of 32,000 square kilometers, how many you›ll have to put, what kind of distances they can realistically cover, and make sure the batteries are charged. Certainly, that’s a very good initiative because with the AEDs, you can’t do anything wrong. You can’t give a shock unless a shock needs to be given. The machine directs you what to do, so somebody who has had no training can pick one of these out of the box and start to work with it quickly and confidently that they can’t do anything wrong.

It’s a great idea. It would be a little expensive potentially at the moment in getting the drones and having that volume of drones around. In the U.S., you have completely different air traffic than we have, and in cities, you have more helicopters flying around. We certainly wouldn’t have that in our cities because that could cause a challenge if you’ve got drones flying around as well. It’s about making it safe that nothing else can go wrong from a drone in somebody else’s flight path.

Dr. Pepe: In my experience, the earlier the intervention, the better the results. There is a limit here in terms of the drones if they just can’t get there soon enough. Having said that, we are so fortunate in the city of Seattle to have most citizens knowing CPR, and we’d get that person resuscitated because they were doing such a good job with the CPR up front.

That’s why you’re going to see the Buffalo Bills player survive neurologically intact – because he did get immediate treatment right then and there. In the future, we may even have some better devices that will actually even restore normal blood flow right then and there while you’re still in cardiac arrest. There are limitations in every case. But on the other hand, it’s exciting and it paid off in this case recently.

Dr. Molloy: Just a point of interest coming from this small little country over here. The first portable defibrillator was developed in Belfast, Ireland, in the back of a cardiac response car. Despite us being a tiny little country, we do have some advances ahead of the United States.
 

Dr. Pepe: That was a breakthrough. Dr. Frank Pantridge and John Geddes did this great work and that caught the imagination of everybody here. At first, they were just going out to give people oxygen and sedate them for their chest pain. It turned out that their defibrillators are what made the difference as they went out there. Absolutely, I have to acknowledge the folks in Ireland for giving us this. Many of the EMS systems got started because of the article they published in The Lancet back in 1967.

Dr. Glatter: I wanted to briefly talk about screening of the athletes at the high school/college level, but also at the professional level. Obviously, there are issues, including the risk for false-positives in terms of low incidence, but there are also false negatives, as the case with Christian Eriksen, who had a cardiac arrest in 2021 and who has been through extensive testing. We can debate the validity of such testing, but I wanted to get both of your takes on the utility of screening in such a population.

Dr. Molloy: That’s a very emotive subject. False-positives are difficult because you’re now saying to somebody that they can’t compete in your sport at a decent level. The difficult part is telling somebody that this is the end of their career.

The false-negative is a little bit more difficult. I don’t know Christian Eriksen and I’m not involved in his team in any way, but that is a one-point examination, and you’re dependent on the scale of the process interpreting the ECG, which is again only a couple of seconds and that particular arrhythmia may not have shown up on that.

Also, athletes, by nature of what they’re doing, are operating at 99% of efficiency on a frequent basis. They are at the peak of their physiologic fitness, and it does make them a little bit more prone to picking up viral illnesses from time to time. They may get a small viral myopericarditis, which causes a new arrhythmia that nobody knew about. They had the screening 2 or 3 years ago, and they now developed a new problem because of what they do, which just may not show up.

I was actually surprised that the gentleman came through it very well, which is fantastic. He wasn’t allowed to play football in the country where he was employed, and he has now moved to another country and is playing football with a defibrillator inserted. I don’t know what the rules are in American football where you can play with implantable defibrillators. I’m not so sure it’s a great idea to do that.

Dr. Pepe: One thing that we should bring up is that there are athletes with underlying cardiomyopathies or hypertrophies and things like that, but that was unlikely in this case. It’s possible, but it’s unlikely, because it would have manifested itself before. In terms of screening, I’ve met some very smart medical doctors who have run those tests, and they have been very encouraged even at the high school levels to have screenings done, whether it’s electrocardiography, echocardiography, and so on. I have to reiterate what Dr Malloy just said in that it may have its downsides as well. If you can pick up real obvious cases, I think that may be of value.

Dr. Glatter: I want to conclude and get some pearls and takeaways from each of you regarding the events that transpired and what our audience can really hold onto.

Dr. Molloy: Look at Formula One in the past 50 years. In Formula One, in the beginning it was a 2-minute job to change a tire. Now, they have this down where they’re measuring in fractions of a second and criticizing each other if one guy is 2.6 seconds and the other guy is 2.9 seconds. For me, that’s phenomenal. It takes me 25 minutes to change a tire.

We’ve looked at that from a resuscitation perspective, and we now do pit crew resuscitation before our events. We’ve planned our team and know who’s going to be occupying what role. After the events at the UEFA championships, we had a new rule brought in by UEFA where they handed me a new document saying, “This is what we would like you to do for resuscitation.” It was a three-man triangle, and I said, “No, we’re not going to do that here.” And they said, “Why, you have to; it’s our rule.”

I said, “No, our rule in Ireland is we have a six-person triangle. We’re not downing our standards because of what you have internationally. You’re covering games in some very low-resource environments, I know that. We have a particular standard here that we’re sticking to. We have a six-person group. We know what we’re all doing; we come very quickly to those downed players and get involved and we’ve had good outcomes, so we’re not going to change the standards.”

That’s the thing: You need to practice these things. The players don’t go out on the weekend and do a move for the very first time without practicing it hundreds of times. We need to look at it the same way as the medical team who are looking after that group of players and the crowd because we also look after the crowd.

A particular challenge in some of our stadiums is that the upper decks are so steep, and it’s very hard to get a patient onto a trolley and do CPR as you’re bringing them down to a zone to get them flat. We’ve had to come up with some innovative techniques to try and do that and accommodate that using some of the mechanical CPR devices. That’s the result you’ll only get from having practiced these events and trying to extricate patients. We want to check response times, so you have to practice your response team activity very frequently.

Dr. Pepe: There are two points made by Mick that I want to react to. One, the pit crew approach is critical in so many ways. We do the same thing in what we call the medical first attack, where we knew who the A, B, and C person would be. When we took it out to the NBA trainers, I recommended for them to have a similar approach so that if an event does happen right in the middle of prime time, they are coordinated.

The second point is that we do mass-gathering medicine. It’s not just the sportspeople on the field or the entertainers that we’re looking after; it is the people in the stands. We will see a cardiac arrest once a month. If you think about it, you might see a cardiac arrest occur in any community on a regular basis. Now you’ve got 100,000 people in one stadium, and something is bound to go wrong over those 3 or 4 hours where they are there and may have a critical emergency. Preparation for all of that is really important as well.

The final point is that on a day-to-day basis, most cardiac arrests do occur in the home. Granted, 80% of them are nonshockable cases, but the people who are more apt to survive are going to be the ones who have an electrical event. In fact, when we looked at our data years ago, we found that, of the cases of people with ventricular fibrillation that we resuscitated, half didn’t even have heart damage. Their enzymes were normal. It was a pure electrical event, and they were more resuscitable. They may have an underlying problem, but we can fix that once we get them back.

Everybody needs to know how to do bystander CPR, and second, we must make sure we have AEDs strategically placed, as I alluded to before. We also go out to other parts of the community and give them advice. All those things must be put in place, but more importantly, just get the training and make the training simple. It’s really a “just do it” philosophy, but make it simple.

For example, when I teach a course, I can do it in 15 minutes, and people retain it because I keep reiterating things like, “Okay, there’s one thing you need to know about choking: Pop the cork.” You give them a physiologic image of what’s happening. Everybody says, “I remember you saying to just do it, pop the cork.”

With AEDs, know where it is – that’s why we should have it in standardized places. Go get it, turn it on, and then follow the instructions. Also, the most important thing is making sure you’re doing quality compressions; and there are videos that can help you with that, as well as classes that you can take that will get you through it.

Dr. Glatter: Absolutely. The public still has the misconception that you need to do mouth-to-mouth resuscitation. The message has not permeated through society that you don’t need to do mouth-to-mouth. Hands-only CPR is the gold standard now.

Dr. Pepe: If people have a reversible cause like ventricular fibrillation, often they’re already gasping, which is better than a delivered breath, by the way. Most important, then, are the compressions to make sure you have oxygen going up to the brain, because you’re still theoretically loaded with oxygen in your bloodstream if you had a sudden cardiac arrest from a ventricular fibrillation.

Your points are well taken, and we found that we had better outcomes when we just gave instructions to do compressions only, and that became the standard. Mick, you’ve had some experiences with that as well.

Dr. Molloy: If we’re going to have a long-term benefit from all this, we have to start doing this in elementary school and teaching kids basic life support and some basic health messaging.

I remember trying to get this across to a teacher one day and the teacher saying, “But why would we teach young kids to resuscitate each other?” I said, “I think you forget that the only 60-year-old person in the room is you. You train them, and we train them. They’re the ones who are going to respond and keep you alive. That’s the way you should be looking at this.” That completely changed the mindset of whether we should be doing this for the kids or not.

Dr. Pepe: In fact, what we find is that that’s exactly who gets saved. I had case after case where the kids at the school had learned CPR and saved the teachers or the administrator at the high school or elementary school. It’s a fantastic point that you bring up, Dr. Malloy.

Dr. Glatter: One other brief thing we can interject here is that the team was excellent on field in that they evaluated Damar Hamlin in a primary survey sense of ABCs (i.e., airway, breathing, and circulation) for things like a tension pneumothorax. In the sense in which he was hit, there are reversible causes. Making sure he didn’t have a tension pneumothorax that caused the arrest, in my mind, was critical.

Dr. Pepe: We do the same thing on a day-to-day basis with a car wreck, because it could be that the person had ventricular fibrillation and then had the wreck. It’s not always trauma. That’s a fantastic point that you’re making. That’s exactly what I think happened, and that’s what we do.

Dr. Glatter: Well, thank you, gentlemen. This was an informative and helpful discussion for our audience. I appreciate your time and expertise.



Dr. Glatter, is an attending physician at Lenox Hill Hospital in New York City and assistant professor of emergency medicine at Zucker School of Medicine at Hofstra/Northwell in Hempstead, New York. He is an editorial adviser and hosts the Hot Topics in EM series on Medscape. He is also a medical contributor for Forbes.

Dr. Pepe is a professor of internal medicine, surgery, pediatrics, public health, and emergency medicine at University of Texas Health Science Center in Houston. He’s also a global coordinator of the U.S. Metropolitan Municipalities EMS Medical Directors (“Eagles”) Coalition.

Dr. Molloy works clinically as a consultant in emergency medicine in Wexford General Hospital, part of the Ireland East Hospital Group (IEHG). Internationally, he is a member of the Disaster Medicine Section of the European Society of Emergency Medicine (EUSEM) and has been appointed by the Irish Medical Organization (IMO) as one of two Irish delegates to serve on the European Board and Section of Emergency Medicine of the European Union of Medical Specialists (UEMS), having served for a number of years on its predecessor, the Multidisciplinary Joint Committee on Emergency Medicine.

A version of this article first appeared on Medscape.com.

North central Washington state is a lot of nothing other than fields. Every year, the Federal Aviation Administration closes the airspace in a remote part of the area for a model rocket competition, the National Association of Rocketry Annual Meet. It’s a 2-day event and a pretty big deal. People come from all over the country to be there.

When you were a kid, you probably saw those rockets that are 3 feet tall. You launch them up in the air, they have a little parachute that comes out and they come back down to the ground. Well, picture that on ultimate steroids. There are anywhere from 3-foot to almost 20-foot-long rockets at this thing. People show up with horse trailers full of rockets and components. I mean, it’s an obsession.

Some of these rockets are super sophisticated. They have different stages where the first stage burns out and the second takes over. They go up thousands of feet to the edge of the stratosphere. Most of them have GoPro cameras, so you get to see when the rocket reaches the top of its trajectory and the last engine burns out. As it starts to descend, a parachute deploys and it can drift back anywhere from pretty close to where you launched it to a couple miles away. Then you use your little GPS to find it.

I have a nephew who worked for Boeing, and he and his son had a 6-foot entry in this competition. He invited me to come out and see it go off. Why not? I drove out there and parked my Jeep and was walking over to the competition when I noticed something off. A bigger commotion than there should have been.

Here’s what happened 2 minutes before I got there:

A 5-foot-long rocket, 2½ inches in diameter, had reached the top of its several thousand–foot trajectory and was ready to come back to Earth. But its parachute didn’t deploy. It turned itself point-down and literally shot back to earth like a rocket.

It had gone up pretty darn straight and came down just as straight – right into a circle of people sitting in lawn chairs.

It hit a middle-aged man. But you can’t imagine how. First of all, who knows how fast it was going. The point glanced off his forehead and ... how to describe the rest. The man was pretty heavy. So the rocket impaled him through the abdomen and stuck right into the ground. As in, the point entered the top of his belly just below chest level and came out the bottom of his belly. The rocket pinned him to the ground through his belly.

Well, this was not how I planned on spending my day. But my spectator time was over. There were a lot of people running around in circles where he was pinned, not really knowing what to do.

When I said I was an emergency physician, instantly 15 heads looked right at me for direction like, Oh my gosh, please take over! A lot of people were asking: “What can I do? What can I do?” I said: “Well, we don’t need to do CPR. What we really need to do is get this rocket out of the ground. We need to keep him still while we dig out the rocket and get him flat.”

People gently dug around the nose of the rocket. It was in about 6 or 8 inches, enough that we didn’t want to just yank on it (I still marvel at how fast it must have been traveling to both impale the man the way it did and also jam into the ground like that). We wanted to loosen it up and ease it out of the ground.

We managed to dig the nose out and get the guy on his back. Needless to say, he wasn’t particularly comfortable. He looked pretty ashen, like he was in pretty good trouble.

The festival had an EMS kit with some bandages in it, but not a whole lot else. There’s the old joke in emergency medicine: What can you do with duct tape, a Swiss army knife, and a paper clip? It’s like, what has anybody got that might work here?

What we really needed to do was keep both the rocket and the man from moving. We cut off his shirt and got his pants down so that I could better see where it entered and exited. Then we used a couple of clean T-shirts to stabilize the rocket so it didn’t move while he lay flat. It didn’t bleed all that much. And his belly wasn’t massively expanding like he was bleeding internally. I mean, he looked crappy. But so would I!

We were about an hour away from the closest EMS and only a couple people even had cell service out there. But we managed to get hold of EMS. It was also one of those 92-degree days with no shade for 50 miles in any direction.

There was a volunteer firefighter there to man the fire rig. He helped carry the guy into an air-conditioned trailer without moving him very much.

Basically, we stabilized him by keeping him super still and as comfortable as we could until EMS arrived. I rode with him about an hour and a half to the closest trauma center in Central Washington. He was conscious, which was lousy for him but reassuring for me. “You’re still talking to me,” I said. “I think you’re going to be okay.”

One of the take-home points from a medical point of view is never try to remove something sticking out of someone when you’re out in the field. If it’s pushing against something vital, you could do a lot of damage, and if it’s up against a blood vessel, that vessel’s going to bleed uncontrollably.

We got to the trauma center and they took him to the OR. By the grace of friendships, somebody got his wife to the hospital. She was calmer than I think I would have been if my spouse had been hit by a rocket.

The full diagnostic story: The rocket bouncing off his forehead gave him a small skull fracture and slight concussion. That was no big deal. But picture this: The rocket only went through his belly fat. It didn’t hit any of his abdominal organs! I still think this is absolutely amazing. If he had been leaning forward in his lawn chair even a few inches, the rocket would’ve gone through his head and that would’ve been all they wrote.

He stayed in the hospital for a couple of days. I never saw him again, but I received follow-up from the surgeon. And I read the paper the next day. Let me tell you, in Central Washington, this is pretty big news.

It wasn’t the way I’d planned my morning. But you just can’t predict that kind of thing. I don’t know, maybe spiritually or karma wise, I was meant to show up about 90 seconds after he’d been hit. The only emergency physician at the whole event, just by chance. My work blesses me with a certain skill set. I know when to really worry, how to go about keeping somebody safe until you can get them to the ED. It’s something I thank my stars for every single day.

As I said to the guy on the way to the hospital: “Well, it’s not your lucky day, but it sure as heck could have been a whole lot unluckier.”

Stephen Anderson, MD, is an emergency medicine physician in Auburn, Washington and is affiliated with MultiCare Auburn Medical Center.

A version of this article first appeared on Medscape.com.

North central Washington state is a lot of nothing other than fields. Every year, the Federal Aviation Administration closes the airspace in a remote part of the area for a model rocket competition, the National Association of Rocketry Annual Meet. It’s a 2-day event and a pretty big deal. People come from all over the country to be there.

When you were a kid, you probably saw those rockets that are 3 feet tall. You launch them up in the air, they have a little parachute that comes out and they come back down to the ground. Well, picture that on ultimate steroids. There are anywhere from 3-foot to almost 20-foot-long rockets at this thing. People show up with horse trailers full of rockets and components. I mean, it’s an obsession.

Some of these rockets are super sophisticated. They have different stages where the first stage burns out and the second takes over. They go up thousands of feet to the edge of the stratosphere. Most of them have GoPro cameras, so you get to see when the rocket reaches the top of its trajectory and the last engine burns out. As it starts to descend, a parachute deploys and it can drift back anywhere from pretty close to where you launched it to a couple miles away. Then you use your little GPS to find it.

I have a nephew who worked for Boeing, and he and his son had a 6-foot entry in this competition. He invited me to come out and see it go off. Why not? I drove out there and parked my Jeep and was walking over to the competition when I noticed something off. A bigger commotion than there should have been.

Here’s what happened 2 minutes before I got there:

A 5-foot-long rocket, 2½ inches in diameter, had reached the top of its several thousand–foot trajectory and was ready to come back to Earth. But its parachute didn’t deploy. It turned itself point-down and literally shot back to earth like a rocket.

It had gone up pretty darn straight and came down just as straight – right into a circle of people sitting in lawn chairs.

It hit a middle-aged man. But you can’t imagine how. First of all, who knows how fast it was going. The point glanced off his forehead and ... how to describe the rest. The man was pretty heavy. So the rocket impaled him through the abdomen and stuck right into the ground. As in, the point entered the top of his belly just below chest level and came out the bottom of his belly. The rocket pinned him to the ground through his belly.

Well, this was not how I planned on spending my day. But my spectator time was over. There were a lot of people running around in circles where he was pinned, not really knowing what to do.

When I said I was an emergency physician, instantly 15 heads looked right at me for direction like, Oh my gosh, please take over! A lot of people were asking: “What can I do? What can I do?” I said: “Well, we don’t need to do CPR. What we really need to do is get this rocket out of the ground. We need to keep him still while we dig out the rocket and get him flat.”

People gently dug around the nose of the rocket. It was in about 6 or 8 inches, enough that we didn’t want to just yank on it (I still marvel at how fast it must have been traveling to both impale the man the way it did and also jam into the ground like that). We wanted to loosen it up and ease it out of the ground.

We managed to dig the nose out and get the guy on his back. Needless to say, he wasn’t particularly comfortable. He looked pretty ashen, like he was in pretty good trouble.

The festival had an EMS kit with some bandages in it, but not a whole lot else. There’s the old joke in emergency medicine: What can you do with duct tape, a Swiss army knife, and a paper clip? It’s like, what has anybody got that might work here?

What we really needed to do was keep both the rocket and the man from moving. We cut off his shirt and got his pants down so that I could better see where it entered and exited. Then we used a couple of clean T-shirts to stabilize the rocket so it didn’t move while he lay flat. It didn’t bleed all that much. And his belly wasn’t massively expanding like he was bleeding internally. I mean, he looked crappy. But so would I!

We were about an hour away from the closest EMS and only a couple people even had cell service out there. But we managed to get hold of EMS. It was also one of those 92-degree days with no shade for 50 miles in any direction.

There was a volunteer firefighter there to man the fire rig. He helped carry the guy into an air-conditioned trailer without moving him very much.

Basically, we stabilized him by keeping him super still and as comfortable as we could until EMS arrived. I rode with him about an hour and a half to the closest trauma center in Central Washington. He was conscious, which was lousy for him but reassuring for me. “You’re still talking to me,” I said. “I think you’re going to be okay.”

One of the take-home points from a medical point of view is never try to remove something sticking out of someone when you’re out in the field. If it’s pushing against something vital, you could do a lot of damage, and if it’s up against a blood vessel, that vessel’s going to bleed uncontrollably.

We got to the trauma center and they took him to the OR. By the grace of friendships, somebody got his wife to the hospital. She was calmer than I think I would have been if my spouse had been hit by a rocket.

The full diagnostic story: The rocket bouncing off his forehead gave him a small skull fracture and slight concussion. That was no big deal. But picture this: The rocket only went through his belly fat. It didn’t hit any of his abdominal organs! I still think this is absolutely amazing. If he had been leaning forward in his lawn chair even a few inches, the rocket would’ve gone through his head and that would’ve been all they wrote.

He stayed in the hospital for a couple of days. I never saw him again, but I received follow-up from the surgeon. And I read the paper the next day. Let me tell you, in Central Washington, this is pretty big news.

It wasn’t the way I’d planned my morning. But you just can’t predict that kind of thing. I don’t know, maybe spiritually or karma wise, I was meant to show up about 90 seconds after he’d been hit. The only emergency physician at the whole event, just by chance. My work blesses me with a certain skill set. I know when to really worry, how to go about keeping somebody safe until you can get them to the ED. It’s something I thank my stars for every single day.

As I said to the guy on the way to the hospital: “Well, it’s not your lucky day, but it sure as heck could have been a whole lot unluckier.”

Stephen Anderson, MD, is an emergency medicine physician in Auburn, Washington and is affiliated with MultiCare Auburn Medical Center.

A version of this article first appeared on Medscape.com.

North central Washington state is a lot of nothing other than fields. Every year, the Federal Aviation Administration closes the airspace in a remote part of the area for a model rocket competition, the National Association of Rocketry Annual Meet. It’s a 2-day event and a pretty big deal. People come from all over the country to be there.

When you were a kid, you probably saw those rockets that are 3 feet tall. You launch them up in the air, they have a little parachute that comes out and they come back down to the ground. Well, picture that on ultimate steroids. There are anywhere from 3-foot to almost 20-foot-long rockets at this thing. People show up with horse trailers full of rockets and components. I mean, it’s an obsession.

Some of these rockets are super sophisticated. They have different stages where the first stage burns out and the second takes over. They go up thousands of feet to the edge of the stratosphere. Most of them have GoPro cameras, so you get to see when the rocket reaches the top of its trajectory and the last engine burns out. As it starts to descend, a parachute deploys and it can drift back anywhere from pretty close to where you launched it to a couple miles away. Then you use your little GPS to find it.

I have a nephew who worked for Boeing, and he and his son had a 6-foot entry in this competition. He invited me to come out and see it go off. Why not? I drove out there and parked my Jeep and was walking over to the competition when I noticed something off. A bigger commotion than there should have been.

Here’s what happened 2 minutes before I got there:

A 5-foot-long rocket, 2½ inches in diameter, had reached the top of its several thousand–foot trajectory and was ready to come back to Earth. But its parachute didn’t deploy. It turned itself point-down and literally shot back to earth like a rocket.

It had gone up pretty darn straight and came down just as straight – right into a circle of people sitting in lawn chairs.

It hit a middle-aged man. But you can’t imagine how. First of all, who knows how fast it was going. The point glanced off his forehead and ... how to describe the rest. The man was pretty heavy. So the rocket impaled him through the abdomen and stuck right into the ground. As in, the point entered the top of his belly just below chest level and came out the bottom of his belly. The rocket pinned him to the ground through his belly.

Well, this was not how I planned on spending my day. But my spectator time was over. There were a lot of people running around in circles where he was pinned, not really knowing what to do.

When I said I was an emergency physician, instantly 15 heads looked right at me for direction like, Oh my gosh, please take over! A lot of people were asking: “What can I do? What can I do?” I said: “Well, we don’t need to do CPR. What we really need to do is get this rocket out of the ground. We need to keep him still while we dig out the rocket and get him flat.”

People gently dug around the nose of the rocket. It was in about 6 or 8 inches, enough that we didn’t want to just yank on it (I still marvel at how fast it must have been traveling to both impale the man the way it did and also jam into the ground like that). We wanted to loosen it up and ease it out of the ground.

We managed to dig the nose out and get the guy on his back. Needless to say, he wasn’t particularly comfortable. He looked pretty ashen, like he was in pretty good trouble.

The festival had an EMS kit with some bandages in it, but not a whole lot else. There’s the old joke in emergency medicine: What can you do with duct tape, a Swiss army knife, and a paper clip? It’s like, what has anybody got that might work here?

What we really needed to do was keep both the rocket and the man from moving. We cut off his shirt and got his pants down so that I could better see where it entered and exited. Then we used a couple of clean T-shirts to stabilize the rocket so it didn’t move while he lay flat. It didn’t bleed all that much. And his belly wasn’t massively expanding like he was bleeding internally. I mean, he looked crappy. But so would I!

We were about an hour away from the closest EMS and only a couple people even had cell service out there. But we managed to get hold of EMS. It was also one of those 92-degree days with no shade for 50 miles in any direction.

There was a volunteer firefighter there to man the fire rig. He helped carry the guy into an air-conditioned trailer without moving him very much.

Basically, we stabilized him by keeping him super still and as comfortable as we could until EMS arrived. I rode with him about an hour and a half to the closest trauma center in Central Washington. He was conscious, which was lousy for him but reassuring for me. “You’re still talking to me,” I said. “I think you’re going to be okay.”

One of the take-home points from a medical point of view is never try to remove something sticking out of someone when you’re out in the field. If it’s pushing against something vital, you could do a lot of damage, and if it’s up against a blood vessel, that vessel’s going to bleed uncontrollably.

We got to the trauma center and they took him to the OR. By the grace of friendships, somebody got his wife to the hospital. She was calmer than I think I would have been if my spouse had been hit by a rocket.

The full diagnostic story: The rocket bouncing off his forehead gave him a small skull fracture and slight concussion. That was no big deal. But picture this: The rocket only went through his belly fat. It didn’t hit any of his abdominal organs! I still think this is absolutely amazing. If he had been leaning forward in his lawn chair even a few inches, the rocket would’ve gone through his head and that would’ve been all they wrote.

He stayed in the hospital for a couple of days. I never saw him again, but I received follow-up from the surgeon. And I read the paper the next day. Let me tell you, in Central Washington, this is pretty big news.

It wasn’t the way I’d planned my morning. But you just can’t predict that kind of thing. I don’t know, maybe spiritually or karma wise, I was meant to show up about 90 seconds after he’d been hit. The only emergency physician at the whole event, just by chance. My work blesses me with a certain skill set. I know when to really worry, how to go about keeping somebody safe until you can get them to the ED. It’s something I thank my stars for every single day.

As I said to the guy on the way to the hospital: “Well, it’s not your lucky day, but it sure as heck could have been a whole lot unluckier.”

Stephen Anderson, MD, is an emergency medicine physician in Auburn, Washington and is affiliated with MultiCare Auburn Medical Center.

A version of this article first appeared on Medscape.com.

Children and teens with concussions who returned to school sooner showed fewer symptoms after 2 weeks than those who returned to school later, based on data from more than 1,600 individuals aged 5-18 years.

The timing for return to school after a concussion has been the subject of guidelines, but data on how the timing of school returns affects later symptom burdens are limited, Christopher G. Vaughan, PhD, of Children’s National Hospital, Rockville, Md., and colleagues wrote.

Examining how the timing of return to school (RTS) affects later symptoms is needed to inform early postinjury management, they said.

In the new study published in JAMA Network Open, the researchers identified 1,630 children and teens aged 5-18 years who were treated for concussions at nine Canadian pediatric EDs. The primary outcome was symptom burden at 14 days post concussion, based on the Post-Concussion Symptom Inventory (PCSI). Early RTS was defined as missing fewer than 3 days of school post concussion.

Overall, the mean number of missed school days was 3.74 (excluding weekends). When divided by age, the mean number of missed days was 2.61 for children aged 5-7 years, 3.26 for those aged 8-12 years, and 4.71 for those aged 13-18 years.

Slightly more than half (53.7%) of the participants had an early RTS of 2 missed days or fewer. Later RTS was most common in the oldest age group, followed by the middle and younger age groups.

The researchers used a propensity score–matched analysis to determine associations. At 14 days, an early RTS was associated with reduced symptoms among 8- to 12-year-olds and 13- to 18-year-olds, though not in the youngest patients aged 5-7 years. In addition, the researchers created quantiles based on initial symptom ratings.

For the youngest age group, the association between early RTS and reduced symptoms at day 14 was higher among those with lower initial symptoms.

For the two older groups, the association was higher for those with higher initial symptoms (based on the PCSI).

The findings that earlier RTS was associated with a lower symptom burden at day 14 for those with higher levels of symptoms at baseline was surprising, but the mechanisms of the timing and effect of RTS requires more study, the researchers wrote in their discussion.

The effect of early RTS on symptoms may be in part related to factors such as “the benefits of socialization, reduced stress from not missing too much school, maintaining or returning to a normal sleep-wake schedule, and returning to light to moderate physical activity (gym class and recreational activities),” the researchers noted.

Another study related to recovery and concussion recently appeared in Neurology. In that study, the authors found that those athletes who took a longer time to recover from a sports-related concussion could still return to play with additional time off, but the methods and populations differed from the current study, which focused on RTS rather than returning to play.

The current study findings were limited by several factors including the lack of randomization for RTS timing and a lack of data on the variety of potential supports and accommodations students received, the researchers noted.

However, the results were strengthened by the large size and diverse nature of the concussions, and the roughly equal representation of boys and girls, they said.

Although randomized trials are needed to determine the best timing for RTS, the current study suggests that RTS within 2 days of a concussion is associated with improved symptoms, “and may directly or indirectly promote faster recovery,” they concluded.
 

Early return remains feasible for most children and teens

“Return to school can be a complicated issue for children and teens with concussions,” said Caitlyn Mooney, MD, a pediatrician and specialist in sports medicine at the University of Texas Health Science Center, San Antonio, said in an interview. Although much research has focused on diagnosis and return to sport after a concussion, there has been less focus on returning to school and learning. Various issues post concussion can make schooling difficult, and students may experience trouble with vision, concentration, sleep, headaches, and more.

Despite this knowledge, studies that specifically address recommended school protocols are limited, Dr. Mooney said. “Additionally, all concussions are different; while some students will need minimal help to return and succeed in school, others may need individualized learning plans and accommodations for school.” A return to school ideally would be a team-based approach with input from the parent, patient, physician, and educators.

“The theory of cognitive rest stems from the idea that a concussion causes metabolic dysfunction in the brain, and that increasing the metabolic demands of the brain can result in symptoms and a delayed return to school,” said Dr. Mooney.

Evidence suggests that those who start resting early after a concussion improve more quickly, “but there has been ongoing discussion over the years of what is the correct balance of cognitive rest to returning to modified activity,” she said. “This has led to the current general recommendation of rest for 24-48 hours followed by a gradual return to school as tolerated.”

Although the current study is large, it is limited by the lack of randomization, Dr. Mooney noted, therefore conclusions cannot be made that the cause of the improved symptoms is a quicker return to school.

However, the results support data from previous studies, in that both of the older age groups showed less disease burden at 14 days after an earlier return to school, she said.

“With prolonged absences, adolescents get isolated at home away from friends, and they may have increased mood symptoms. Additionally, I have found a high number of my patients who do not go to school as quickly have more sleep disturbance, which seems to increase symptoms such as difficulty concentrating or headaches,” she said. “It seems like the students do benefit from a routine schedule even if they have to have some accommodations at school, especially older students who may have more stress about missing school and falling behind on schoolwork.”

The message for pediatricians is that return to school should be individualized, Dr. Mooney said.

Although the current study does not dictate the optimal return to school, the results support those of previous studies in showing that, after 1-2 days of rest, an early return does not harm children and teens and may improve symptoms in many cases, she said. “In my experience, sometimes schools find it easier to keep the student at home rather than manage rest or special accommodations,” but the current study suggests that delaying return to school may not be the right choice for many patients.

“I hope this study empowers clinicians to advocate for these students, that the right place for them is in the classroom even with rest, extra time, or other accommodations,” said Dr. Mooney.

“Each concussion should be evaluated and treated individually; there will likely be a few who may need to stay home for a longer period of time, but this study suggests that the majority of students will suffer no ill effects from returning to the normal routine after a 2-day rest,” she noted.

The study was supported by the Canadian Institutes for Health Research. Dr. Vaughan and several coauthors disclosed being authors of the Postconcussion Symptom Inventory outside of the current study. Dr. Mooney had no financial conflicts to disclose.

Children and teens with concussions who returned to school sooner showed fewer symptoms after 2 weeks than those who returned to school later, based on data from more than 1,600 individuals aged 5-18 years.

The timing for return to school after a concussion has been the subject of guidelines, but data on how the timing of school returns affects later symptom burdens are limited, Christopher G. Vaughan, PhD, of Children’s National Hospital, Rockville, Md., and colleagues wrote.

Examining how the timing of return to school (RTS) affects later symptoms is needed to inform early postinjury management, they said.

In the new study published in JAMA Network Open, the researchers identified 1,630 children and teens aged 5-18 years who were treated for concussions at nine Canadian pediatric EDs. The primary outcome was symptom burden at 14 days post concussion, based on the Post-Concussion Symptom Inventory (PCSI). Early RTS was defined as missing fewer than 3 days of school post concussion.

Overall, the mean number of missed school days was 3.74 (excluding weekends). When divided by age, the mean number of missed days was 2.61 for children aged 5-7 years, 3.26 for those aged 8-12 years, and 4.71 for those aged 13-18 years.

Slightly more than half (53.7%) of the participants had an early RTS of 2 missed days or fewer. Later RTS was most common in the oldest age group, followed by the middle and younger age groups.

The researchers used a propensity score–matched analysis to determine associations. At 14 days, an early RTS was associated with reduced symptoms among 8- to 12-year-olds and 13- to 18-year-olds, though not in the youngest patients aged 5-7 years. In addition, the researchers created quantiles based on initial symptom ratings.

For the youngest age group, the association between early RTS and reduced symptoms at day 14 was higher among those with lower initial symptoms.

For the two older groups, the association was higher for those with higher initial symptoms (based on the PCSI).

The findings that earlier RTS was associated with a lower symptom burden at day 14 for those with higher levels of symptoms at baseline was surprising, but the mechanisms of the timing and effect of RTS requires more study, the researchers wrote in their discussion.

The effect of early RTS on symptoms may be in part related to factors such as “the benefits of socialization, reduced stress from not missing too much school, maintaining or returning to a normal sleep-wake schedule, and returning to light to moderate physical activity (gym class and recreational activities),” the researchers noted.

Another study related to recovery and concussion recently appeared in Neurology. In that study, the authors found that those athletes who took a longer time to recover from a sports-related concussion could still return to play with additional time off, but the methods and populations differed from the current study, which focused on RTS rather than returning to play.

The current study findings were limited by several factors including the lack of randomization for RTS timing and a lack of data on the variety of potential supports and accommodations students received, the researchers noted.

However, the results were strengthened by the large size and diverse nature of the concussions, and the roughly equal representation of boys and girls, they said.

Although randomized trials are needed to determine the best timing for RTS, the current study suggests that RTS within 2 days of a concussion is associated with improved symptoms, “and may directly or indirectly promote faster recovery,” they concluded.
 

Early return remains feasible for most children and teens

“Return to school can be a complicated issue for children and teens with concussions,” said Caitlyn Mooney, MD, a pediatrician and specialist in sports medicine at the University of Texas Health Science Center, San Antonio, said in an interview. Although much research has focused on diagnosis and return to sport after a concussion, there has been less focus on returning to school and learning. Various issues post concussion can make schooling difficult, and students may experience trouble with vision, concentration, sleep, headaches, and more.

Despite this knowledge, studies that specifically address recommended school protocols are limited, Dr. Mooney said. “Additionally, all concussions are different; while some students will need minimal help to return and succeed in school, others may need individualized learning plans and accommodations for school.” A return to school ideally would be a team-based approach with input from the parent, patient, physician, and educators.

“The theory of cognitive rest stems from the idea that a concussion causes metabolic dysfunction in the brain, and that increasing the metabolic demands of the brain can result in symptoms and a delayed return to school,” said Dr. Mooney.

Evidence suggests that those who start resting early after a concussion improve more quickly, “but there has been ongoing discussion over the years of what is the correct balance of cognitive rest to returning to modified activity,” she said. “This has led to the current general recommendation of rest for 24-48 hours followed by a gradual return to school as tolerated.”

Although the current study is large, it is limited by the lack of randomization, Dr. Mooney noted, therefore conclusions cannot be made that the cause of the improved symptoms is a quicker return to school.

However, the results support data from previous studies, in that both of the older age groups showed less disease burden at 14 days after an earlier return to school, she said.

“With prolonged absences, adolescents get isolated at home away from friends, and they may have increased mood symptoms. Additionally, I have found a high number of my patients who do not go to school as quickly have more sleep disturbance, which seems to increase symptoms such as difficulty concentrating or headaches,” she said. “It seems like the students do benefit from a routine schedule even if they have to have some accommodations at school, especially older students who may have more stress about missing school and falling behind on schoolwork.”

The message for pediatricians is that return to school should be individualized, Dr. Mooney said.

Although the current study does not dictate the optimal return to school, the results support those of previous studies in showing that, after 1-2 days of rest, an early return does not harm children and teens and may improve symptoms in many cases, she said. “In my experience, sometimes schools find it easier to keep the student at home rather than manage rest or special accommodations,” but the current study suggests that delaying return to school may not be the right choice for many patients.

“I hope this study empowers clinicians to advocate for these students, that the right place for them is in the classroom even with rest, extra time, or other accommodations,” said Dr. Mooney.

“Each concussion should be evaluated and treated individually; there will likely be a few who may need to stay home for a longer period of time, but this study suggests that the majority of students will suffer no ill effects from returning to the normal routine after a 2-day rest,” she noted.

The study was supported by the Canadian Institutes for Health Research. Dr. Vaughan and several coauthors disclosed being authors of the Postconcussion Symptom Inventory outside of the current study. Dr. Mooney had no financial conflicts to disclose.

Children and teens with concussions who returned to school sooner showed fewer symptoms after 2 weeks than those who returned to school later, based on data from more than 1,600 individuals aged 5-18 years.

The timing for return to school after a concussion has been the subject of guidelines, but data on how the timing of school returns affects later symptom burdens are limited, Christopher G. Vaughan, PhD, of Children’s National Hospital, Rockville, Md., and colleagues wrote.

Examining how the timing of return to school (RTS) affects later symptoms is needed to inform early postinjury management, they said.

In the new study published in JAMA Network Open, the researchers identified 1,630 children and teens aged 5-18 years who were treated for concussions at nine Canadian pediatric EDs. The primary outcome was symptom burden at 14 days post concussion, based on the Post-Concussion Symptom Inventory (PCSI). Early RTS was defined as missing fewer than 3 days of school post concussion.

Overall, the mean number of missed school days was 3.74 (excluding weekends). When divided by age, the mean number of missed days was 2.61 for children aged 5-7 years, 3.26 for those aged 8-12 years, and 4.71 for those aged 13-18 years.

Slightly more than half (53.7%) of the participants had an early RTS of 2 missed days or fewer. Later RTS was most common in the oldest age group, followed by the middle and younger age groups.

The researchers used a propensity score–matched analysis to determine associations. At 14 days, an early RTS was associated with reduced symptoms among 8- to 12-year-olds and 13- to 18-year-olds, though not in the youngest patients aged 5-7 years. In addition, the researchers created quantiles based on initial symptom ratings.

For the youngest age group, the association between early RTS and reduced symptoms at day 14 was higher among those with lower initial symptoms.

For the two older groups, the association was higher for those with higher initial symptoms (based on the PCSI).

The findings that earlier RTS was associated with a lower symptom burden at day 14 for those with higher levels of symptoms at baseline was surprising, but the mechanisms of the timing and effect of RTS requires more study, the researchers wrote in their discussion.

The effect of early RTS on symptoms may be in part related to factors such as “the benefits of socialization, reduced stress from not missing too much school, maintaining or returning to a normal sleep-wake schedule, and returning to light to moderate physical activity (gym class and recreational activities),” the researchers noted.

Another study related to recovery and concussion recently appeared in Neurology. In that study, the authors found that those athletes who took a longer time to recover from a sports-related concussion could still return to play with additional time off, but the methods and populations differed from the current study, which focused on RTS rather than returning to play.

The current study findings were limited by several factors including the lack of randomization for RTS timing and a lack of data on the variety of potential supports and accommodations students received, the researchers noted.

However, the results were strengthened by the large size and diverse nature of the concussions, and the roughly equal representation of boys and girls, they said.

Although randomized trials are needed to determine the best timing for RTS, the current study suggests that RTS within 2 days of a concussion is associated with improved symptoms, “and may directly or indirectly promote faster recovery,” they concluded.
 

Early return remains feasible for most children and teens

“Return to school can be a complicated issue for children and teens with concussions,” said Caitlyn Mooney, MD, a pediatrician and specialist in sports medicine at the University of Texas Health Science Center, San Antonio, said in an interview. Although much research has focused on diagnosis and return to sport after a concussion, there has been less focus on returning to school and learning. Various issues post concussion can make schooling difficult, and students may experience trouble with vision, concentration, sleep, headaches, and more.

Despite this knowledge, studies that specifically address recommended school protocols are limited, Dr. Mooney said. “Additionally, all concussions are different; while some students will need minimal help to return and succeed in school, others may need individualized learning plans and accommodations for school.” A return to school ideally would be a team-based approach with input from the parent, patient, physician, and educators.

“The theory of cognitive rest stems from the idea that a concussion causes metabolic dysfunction in the brain, and that increasing the metabolic demands of the brain can result in symptoms and a delayed return to school,” said Dr. Mooney.

Evidence suggests that those who start resting early after a concussion improve more quickly, “but there has been ongoing discussion over the years of what is the correct balance of cognitive rest to returning to modified activity,” she said. “This has led to the current general recommendation of rest for 24-48 hours followed by a gradual return to school as tolerated.”

Although the current study is large, it is limited by the lack of randomization, Dr. Mooney noted, therefore conclusions cannot be made that the cause of the improved symptoms is a quicker return to school.

However, the results support data from previous studies, in that both of the older age groups showed less disease burden at 14 days after an earlier return to school, she said.

“With prolonged absences, adolescents get isolated at home away from friends, and they may have increased mood symptoms. Additionally, I have found a high number of my patients who do not go to school as quickly have more sleep disturbance, which seems to increase symptoms such as difficulty concentrating or headaches,” she said. “It seems like the students do benefit from a routine schedule even if they have to have some accommodations at school, especially older students who may have more stress about missing school and falling behind on schoolwork.”

The message for pediatricians is that return to school should be individualized, Dr. Mooney said.

Although the current study does not dictate the optimal return to school, the results support those of previous studies in showing that, after 1-2 days of rest, an early return does not harm children and teens and may improve symptoms in many cases, she said. “In my experience, sometimes schools find it easier to keep the student at home rather than manage rest or special accommodations,” but the current study suggests that delaying return to school may not be the right choice for many patients.

“I hope this study empowers clinicians to advocate for these students, that the right place for them is in the classroom even with rest, extra time, or other accommodations,” said Dr. Mooney.

“Each concussion should be evaluated and treated individually; there will likely be a few who may need to stay home for a longer period of time, but this study suggests that the majority of students will suffer no ill effects from returning to the normal routine after a 2-day rest,” she noted.

The study was supported by the Canadian Institutes for Health Research. Dr. Vaughan and several coauthors disclosed being authors of the Postconcussion Symptom Inventory outside of the current study. Dr. Mooney had no financial conflicts to disclose.

Delay in treatment will cost hospital millions

A Texas hospital must pay a multimillion-dollar judgment for failing to treat a woman’s spinal injury in time to prevent paralysis, according to a report on WFAA.com, among other news sites.

On March 21, 2019, Judy “Jessie” Adams, then part of a singing-songwriting duo with her husband, Richard, went to Premier Interventional Pain Management, in Flower Mound, Tex., prior to the couple’s drive to Ohio for a funeral. At Premier, Jesse received an epidural steroid injection (ESI) that she hoped would ease her back pain during the long drive.

Instead, the injection ended up increasing her pain.

“He [the pain physician] gave me the shot, but I couldn’t feel my legs. They were tingling, but I couldn’t feel them,” Mrs. Adams explained. “The pain was so bad in my back.” In their suit, Adams and her husband alleged that the doctor had probably “nicked a blood vessel during the ESI procedure, causing Jessie to hemorrhage.” (The couple’s suit against the doctor was settled prior to trial.)

Mrs. Adams remained under observation at the pain facility for about 1½ hours, at which point she was taken by ambulance to nearby Texas Health Presbyterian Hospital. There, in the emergency department, staff ordered a “STAT MRI” in preparation for an emergency laminectomy.

For reasons that remain murky, the MRI wasn’t performed for 1 hour and 37 minutes. The emergency laminectomy itself wasn’t started until more than 5 hours after Adams had been admitted to the ED. This was a direct violation of hospital protocol, which required that emergency surgeries be performed within 1 hour of admittance in the first available surgical suite. (At trial, Mrs. Adams’s attorneys from Lyons & Simmons offered evidence that a suite became available 49 minutes after Adams had arrived at the ED.)

During the wait, Mrs. Adams continued to experience excruciating pain. “I kept screaming: ‘Help me,’ ” she recalled. At trial, her attorneys argued that the hospital’s delay in addressing her spinal emergency led directly to her current paralysis, which keeps her confined to a wheelchair and renders her incontinent.

The hospital disagreed. In court, it maintained that Mrs. Adams was already paralyzed when she arrived at the ED and that there was no delay in care.

The jury saw things differently, however. Siding with the plaintiffs, it awarded Mrs. Adams and her husband $10.1 million, including $500,000 for Mr. Adams’s loss of future earnings and $1 million for his “loss of consortium” with his wife.

Their music career now effectively over, Mr. Adams spends most of his time taking care of Mrs. Adams.

“Music was our lifeblood for so many years, and he can’t do it anymore,” Mrs. Adams said. “He goes upstairs to play his guitar and write, and suddenly I need him to come and cath me. I just feel like I’m going to wake up from this bad dream, but it’s the same routine.”
 

Two doctors are absolved in woman’s sudden death

In a 3-2 decision in December 2022, the Pennsylvania Supreme Court ruled that the state’s 2-year statute of limitations in wrongful-death cases applies even in cases in which plaintiffs fail to identify the cause of death in a timely manner, as a report in the Claims Journal indicates.

The decision stems from a lawsuit filed by Linda Reibenstein on behalf of her mother, Mary Ann Whitman, who died in late April 2010 from a ruptured aortic aneurysm.

On April 12, 2010, Ms. Whitman visited Patrick D. Conaboy, MD, a Scranton family physician, complaining of a persistent cough, fever, and lower-back pain. Following an initial examination, Dr. Conaboy ordered an aortic duplex ultrasound scan and a CT scan of the patient’s abdomen.

The ultrasound was performed by radiologist Charles Barax, MD, who reviewed both scans. He identified a “poorly visualized aortic aneurysm.” At this point, Dr. Conaboy referred Ms. Whitman to a vascular surgeon. But before this visit could take place, Whitman’s aneurysm ruptured, killing her. This was listed as the medical cause of death on the patient’s death certificate.

In April 2011, Ms. Reibenstein filed a claim against Dr. Barax, alleging that he had failed to gauge the severity of her mother’s condition. Ms. Reibenstein’s attorney wasn’t able to question Dr. Barax on the record until well after the state’s 2-year statute of limitations had elapsed. When he did testify, Dr. Barax explained that the scans’ image quality prevented him from determining whether Whitman’s aneurysm was rupturing or simply bleeding. Despite this, he insisted that he had warned Dr. Conaboy of the potential for Ms. Whitman’s aneurysm to rupture.

In March 2016, nearly 6 years after her mother’s death, Ms. Reibenstein filed a new lawsuit, this one against Dr. Conaboy, whom she alleged had failed to properly treat her mother’s condition. Dr. Conaboy, in turn, asked the court for summary judgment – that is, a judgment in his favor without a full trial – arguing that the state’s window for filing a wrongful-death claim had long since closed. For their part, Ms. Reibenstein and her attorney argued that the state’s 2-year statute of limitations didn’t start until the plaintiff had discovered the cause of her mother’s death.

Initially refusing to dismiss the case, a lower court reconsidered Dr. Conaboy’s motion for summary judgment and ruled that Ms. Reibenstein had failed to present any evidence of “affirmative misrepresentation or fraudulent concealment.” In other words, in the absence of any willful attempt on the part of the defendant to hide the legal cause of death, which includes “acts, omissions, or events having some causative connection with the death,” the statute of limitations remained in effect, and the defendant’s motion was thereby granted.

Continuing the legal seesaw, a state appeals court reversed the lower-court ruling. Noting that the Pennsylvania malpractice statute was ambiguous, the court argued that it should be interpreted in a way that protects plaintiffs who seek “fair compensation” but encounter willfully erected obstacles in pursuit of their claim.

Dr. Conaboy then took his case to the state’s highest court. In its majority decision, the Pennsylvania Supreme Court staked out a narrow definition of cause of death – one based on the death certificate – and ruled that only willful fraud in that document would constitute the necessary condition for halting the claim’s clock. Furthermore, the high court said, when lawmakers adopted the Medical Care Availability and Reduction of Error Act in 2002, they did so with no guarantee “that all of the information necessary to sustain a claim will be gathered in the limitations period.”

Similarly, the court ruled, “at some point the clock must run out, lest health care providers remain subject to liability exposure indefinitely, with the prospect of a trial marred by the death or diminished memory of material witnesses or the loss of critical evidence.”

A version of this article first appeared on Medscape.com.

Delay in treatment will cost hospital millions

A Texas hospital must pay a multimillion-dollar judgment for failing to treat a woman’s spinal injury in time to prevent paralysis, according to a report on WFAA.com, among other news sites.

On March 21, 2019, Judy “Jessie” Adams, then part of a singing-songwriting duo with her husband, Richard, went to Premier Interventional Pain Management, in Flower Mound, Tex., prior to the couple’s drive to Ohio for a funeral. At Premier, Jesse received an epidural steroid injection (ESI) that she hoped would ease her back pain during the long drive.

Instead, the injection ended up increasing her pain.

“He [the pain physician] gave me the shot, but I couldn’t feel my legs. They were tingling, but I couldn’t feel them,” Mrs. Adams explained. “The pain was so bad in my back.” In their suit, Adams and her husband alleged that the doctor had probably “nicked a blood vessel during the ESI procedure, causing Jessie to hemorrhage.” (The couple’s suit against the doctor was settled prior to trial.)

Mrs. Adams remained under observation at the pain facility for about 1½ hours, at which point she was taken by ambulance to nearby Texas Health Presbyterian Hospital. There, in the emergency department, staff ordered a “STAT MRI” in preparation for an emergency laminectomy.

For reasons that remain murky, the MRI wasn’t performed for 1 hour and 37 minutes. The emergency laminectomy itself wasn’t started until more than 5 hours after Adams had been admitted to the ED. This was a direct violation of hospital protocol, which required that emergency surgeries be performed within 1 hour of admittance in the first available surgical suite. (At trial, Mrs. Adams’s attorneys from Lyons & Simmons offered evidence that a suite became available 49 minutes after Adams had arrived at the ED.)

During the wait, Mrs. Adams continued to experience excruciating pain. “I kept screaming: ‘Help me,’ ” she recalled. At trial, her attorneys argued that the hospital’s delay in addressing her spinal emergency led directly to her current paralysis, which keeps her confined to a wheelchair and renders her incontinent.

The hospital disagreed. In court, it maintained that Mrs. Adams was already paralyzed when she arrived at the ED and that there was no delay in care.

The jury saw things differently, however. Siding with the plaintiffs, it awarded Mrs. Adams and her husband $10.1 million, including $500,000 for Mr. Adams’s loss of future earnings and $1 million for his “loss of consortium” with his wife.

Their music career now effectively over, Mr. Adams spends most of his time taking care of Mrs. Adams.

“Music was our lifeblood for so many years, and he can’t do it anymore,” Mrs. Adams said. “He goes upstairs to play his guitar and write, and suddenly I need him to come and cath me. I just feel like I’m going to wake up from this bad dream, but it’s the same routine.”
 

Two doctors are absolved in woman’s sudden death

In a 3-2 decision in December 2022, the Pennsylvania Supreme Court ruled that the state’s 2-year statute of limitations in wrongful-death cases applies even in cases in which plaintiffs fail to identify the cause of death in a timely manner, as a report in the Claims Journal indicates.

The decision stems from a lawsuit filed by Linda Reibenstein on behalf of her mother, Mary Ann Whitman, who died in late April 2010 from a ruptured aortic aneurysm.

On April 12, 2010, Ms. Whitman visited Patrick D. Conaboy, MD, a Scranton family physician, complaining of a persistent cough, fever, and lower-back pain. Following an initial examination, Dr. Conaboy ordered an aortic duplex ultrasound scan and a CT scan of the patient’s abdomen.

The ultrasound was performed by radiologist Charles Barax, MD, who reviewed both scans. He identified a “poorly visualized aortic aneurysm.” At this point, Dr. Conaboy referred Ms. Whitman to a vascular surgeon. But before this visit could take place, Whitman’s aneurysm ruptured, killing her. This was listed as the medical cause of death on the patient’s death certificate.

In April 2011, Ms. Reibenstein filed a claim against Dr. Barax, alleging that he had failed to gauge the severity of her mother’s condition. Ms. Reibenstein’s attorney wasn’t able to question Dr. Barax on the record until well after the state’s 2-year statute of limitations had elapsed. When he did testify, Dr. Barax explained that the scans’ image quality prevented him from determining whether Whitman’s aneurysm was rupturing or simply bleeding. Despite this, he insisted that he had warned Dr. Conaboy of the potential for Ms. Whitman’s aneurysm to rupture.

In March 2016, nearly 6 years after her mother’s death, Ms. Reibenstein filed a new lawsuit, this one against Dr. Conaboy, whom she alleged had failed to properly treat her mother’s condition. Dr. Conaboy, in turn, asked the court for summary judgment – that is, a judgment in his favor without a full trial – arguing that the state’s window for filing a wrongful-death claim had long since closed. For their part, Ms. Reibenstein and her attorney argued that the state’s 2-year statute of limitations didn’t start until the plaintiff had discovered the cause of her mother’s death.

Initially refusing to dismiss the case, a lower court reconsidered Dr. Conaboy’s motion for summary judgment and ruled that Ms. Reibenstein had failed to present any evidence of “affirmative misrepresentation or fraudulent concealment.” In other words, in the absence of any willful attempt on the part of the defendant to hide the legal cause of death, which includes “acts, omissions, or events having some causative connection with the death,” the statute of limitations remained in effect, and the defendant’s motion was thereby granted.

Continuing the legal seesaw, a state appeals court reversed the lower-court ruling. Noting that the Pennsylvania malpractice statute was ambiguous, the court argued that it should be interpreted in a way that protects plaintiffs who seek “fair compensation” but encounter willfully erected obstacles in pursuit of their claim.

Dr. Conaboy then took his case to the state’s highest court. In its majority decision, the Pennsylvania Supreme Court staked out a narrow definition of cause of death – one based on the death certificate – and ruled that only willful fraud in that document would constitute the necessary condition for halting the claim’s clock. Furthermore, the high court said, when lawmakers adopted the Medical Care Availability and Reduction of Error Act in 2002, they did so with no guarantee “that all of the information necessary to sustain a claim will be gathered in the limitations period.”

Similarly, the court ruled, “at some point the clock must run out, lest health care providers remain subject to liability exposure indefinitely, with the prospect of a trial marred by the death or diminished memory of material witnesses or the loss of critical evidence.”

A version of this article first appeared on Medscape.com.

Delay in treatment will cost hospital millions

A Texas hospital must pay a multimillion-dollar judgment for failing to treat a woman’s spinal injury in time to prevent paralysis, according to a report on WFAA.com, among other news sites.

On March 21, 2019, Judy “Jessie” Adams, then part of a singing-songwriting duo with her husband, Richard, went to Premier Interventional Pain Management, in Flower Mound, Tex., prior to the couple’s drive to Ohio for a funeral. At Premier, Jesse received an epidural steroid injection (ESI) that she hoped would ease her back pain during the long drive.

Instead, the injection ended up increasing her pain.

“He [the pain physician] gave me the shot, but I couldn’t feel my legs. They were tingling, but I couldn’t feel them,” Mrs. Adams explained. “The pain was so bad in my back.” In their suit, Adams and her husband alleged that the doctor had probably “nicked a blood vessel during the ESI procedure, causing Jessie to hemorrhage.” (The couple’s suit against the doctor was settled prior to trial.)

Mrs. Adams remained under observation at the pain facility for about 1½ hours, at which point she was taken by ambulance to nearby Texas Health Presbyterian Hospital. There, in the emergency department, staff ordered a “STAT MRI” in preparation for an emergency laminectomy.

For reasons that remain murky, the MRI wasn’t performed for 1 hour and 37 minutes. The emergency laminectomy itself wasn’t started until more than 5 hours after Adams had been admitted to the ED. This was a direct violation of hospital protocol, which required that emergency surgeries be performed within 1 hour of admittance in the first available surgical suite. (At trial, Mrs. Adams’s attorneys from Lyons & Simmons offered evidence that a suite became available 49 minutes after Adams had arrived at the ED.)

During the wait, Mrs. Adams continued to experience excruciating pain. “I kept screaming: ‘Help me,’ ” she recalled. At trial, her attorneys argued that the hospital’s delay in addressing her spinal emergency led directly to her current paralysis, which keeps her confined to a wheelchair and renders her incontinent.

The hospital disagreed. In court, it maintained that Mrs. Adams was already paralyzed when she arrived at the ED and that there was no delay in care.

The jury saw things differently, however. Siding with the plaintiffs, it awarded Mrs. Adams and her husband $10.1 million, including $500,000 for Mr. Adams’s loss of future earnings and $1 million for his “loss of consortium” with his wife.

Their music career now effectively over, Mr. Adams spends most of his time taking care of Mrs. Adams.

“Music was our lifeblood for so many years, and he can’t do it anymore,” Mrs. Adams said. “He goes upstairs to play his guitar and write, and suddenly I need him to come and cath me. I just feel like I’m going to wake up from this bad dream, but it’s the same routine.”
 

Two doctors are absolved in woman’s sudden death

In a 3-2 decision in December 2022, the Pennsylvania Supreme Court ruled that the state’s 2-year statute of limitations in wrongful-death cases applies even in cases in which plaintiffs fail to identify the cause of death in a timely manner, as a report in the Claims Journal indicates.

The decision stems from a lawsuit filed by Linda Reibenstein on behalf of her mother, Mary Ann Whitman, who died in late April 2010 from a ruptured aortic aneurysm.

On April 12, 2010, Ms. Whitman visited Patrick D. Conaboy, MD, a Scranton family physician, complaining of a persistent cough, fever, and lower-back pain. Following an initial examination, Dr. Conaboy ordered an aortic duplex ultrasound scan and a CT scan of the patient’s abdomen.

The ultrasound was performed by radiologist Charles Barax, MD, who reviewed both scans. He identified a “poorly visualized aortic aneurysm.” At this point, Dr. Conaboy referred Ms. Whitman to a vascular surgeon. But before this visit could take place, Whitman’s aneurysm ruptured, killing her. This was listed as the medical cause of death on the patient’s death certificate.

In April 2011, Ms. Reibenstein filed a claim against Dr. Barax, alleging that he had failed to gauge the severity of her mother’s condition. Ms. Reibenstein’s attorney wasn’t able to question Dr. Barax on the record until well after the state’s 2-year statute of limitations had elapsed. When he did testify, Dr. Barax explained that the scans’ image quality prevented him from determining whether Whitman’s aneurysm was rupturing or simply bleeding. Despite this, he insisted that he had warned Dr. Conaboy of the potential for Ms. Whitman’s aneurysm to rupture.

In March 2016, nearly 6 years after her mother’s death, Ms. Reibenstein filed a new lawsuit, this one against Dr. Conaboy, whom she alleged had failed to properly treat her mother’s condition. Dr. Conaboy, in turn, asked the court for summary judgment – that is, a judgment in his favor without a full trial – arguing that the state’s window for filing a wrongful-death claim had long since closed. For their part, Ms. Reibenstein and her attorney argued that the state’s 2-year statute of limitations didn’t start until the plaintiff had discovered the cause of her mother’s death.

Initially refusing to dismiss the case, a lower court reconsidered Dr. Conaboy’s motion for summary judgment and ruled that Ms. Reibenstein had failed to present any evidence of “affirmative misrepresentation or fraudulent concealment.” In other words, in the absence of any willful attempt on the part of the defendant to hide the legal cause of death, which includes “acts, omissions, or events having some causative connection with the death,” the statute of limitations remained in effect, and the defendant’s motion was thereby granted.

Continuing the legal seesaw, a state appeals court reversed the lower-court ruling. Noting that the Pennsylvania malpractice statute was ambiguous, the court argued that it should be interpreted in a way that protects plaintiffs who seek “fair compensation” but encounter willfully erected obstacles in pursuit of their claim.

Dr. Conaboy then took his case to the state’s highest court. In its majority decision, the Pennsylvania Supreme Court staked out a narrow definition of cause of death – one based on the death certificate – and ruled that only willful fraud in that document would constitute the necessary condition for halting the claim’s clock. Furthermore, the high court said, when lawmakers adopted the Medical Care Availability and Reduction of Error Act in 2002, they did so with no guarantee “that all of the information necessary to sustain a claim will be gathered in the limitations period.”

Similarly, the court ruled, “at some point the clock must run out, lest health care providers remain subject to liability exposure indefinitely, with the prospect of a trial marred by the death or diminished memory of material witnesses or the loss of critical evidence.”

A version of this article first appeared on Medscape.com.

It started as a mountain biking excursion with two friends. When we drove into the trailhead parking lot, we saw several emergency vehicles. Then a helicopter passed overhead. As we got on our bikes, a police officer told us there’d been an accident out on the trail and to be careful because emergency personnel were going to be bringing in the patient. So we started the ride cautiously, ready to yield to emergency medical services.

Half a mile down the trail, we encountered another police officer. He asked if we would be willing to go back to get an oxygen tank from the ambulance and carry it out to the scene. The three of us turned around, went back to the parking lot and were able to snag a tank of oxygen. We put it in a backpack and biked out again.

We found the scene about a mile down the trail. An adult male was lying on his back in the dirt after a crash. His eyes were closed and he wasn’t moving except for occasional breaths. Six emergency medical personnel huddled around him, one assisting breaths with a bag mask. I didn’t introduce myself initially. I just listened to hear what was happening.

They were debating the dose of medication to give him in order to intubate. I knew the answer to that question, so I introduced myself. They were happy to have somebody else to assist.

They already had an IV in place and quite a lot of supplies. They administered the meds and the paramedic attempted to intubate through the mouth. Within a few seconds, she pulled the intubating blade out and said, “I’m not going to be able to get this. His tongue is too big.”

I took the blade myself and kneeled at the head of the victim. I made three attempts at intubating, and each time couldn’t view the landmarks. I wasn’t sure if his tongue was too large or if there was some traumatic injury. To make it more difficult, a lot of secretions clogged the airway. The paramedics had a portable suction, which was somewhat functional, but I still couldn’t visualize the landmarks.

I started asking about alternative methods of establishing an airway. They had an i-gel, which is a supraglottic device that goes into the back of the mouth. So, we placed it. But when we attached the bag, air still wasn’t getting into the lungs.

We removed it and put the bag mask back on. Now I was worried. We were having difficulty keeping his oxygen above 90%. I examined the chest and abdomen again. I was wondering if perhaps he was having some gastric distention, which can result from prolonged bagging, but that didn’t seem to be the case.

Bagging became progressively more difficult, and the oxygen slowly trended down through the 80s. Then the 70s. Heart rate dropped below 60 beats per minute. The trajectory was obvious.

That’s when I asked if they had the tools for a surgical airway.

No one thought the question was crazy. In fact, they pulled out a scalpel from an equipment bag.

But now I had to actually do it. I knelt next to the patient, trying to palpate the front of the neck to identify the correct location to cut. I had difficulty finding the appropriate landmarks there as well. Frustrating.

I glanced at the monitor. O₂ was now in the 60s. Later the paramedic told me the heart rate was down to 30.

One of the medics looked me in the eye and said, “We’ve got to do something. The time is now.” That helped me snap out of it and act. I made my large vertical incision on the front of the victim’s neck, which of course resulted in quite a bit of bleeding.

My two friends, who were watching, later told me this was the moment the intensity of the scene really increased (it was already pretty intense for me, thanks).

Next, I made the horizontal stab incision. Then I probed with my finger, but it seems the incision hadn’t reached the trachea. I had to make the stab much deeper than I would’ve thought.

And then air bubbled out through the blood. A paramedic was ready with the ET tube in hand and she put it through the incision. We attached the bag. We had air movement into the lungs, and within minutes the oxygen came up.

Not long after, the flight paramedics from the helicopter showed up, having jogged a mile through the woods. They seemed rather surprised to find a patient with a cricothyrotomy. We filled them in on the situation. Now we had to get the patient out of the woods (literally and figuratively).

The emergency responders had a really great transport device: A litter with one big wheel underneath in the middle so we could roll the patient down the mountain bike trail over rocks relatively safely. One person’s job was to hold the tube as we went since we didn’t have suture to hold it in place.

We got back to the parking lot and loaded him into the ambulance, which drove another mile to the helicopter, which then had to take him a hundred miles to the hospital.

To be honest, I thought the prognosis was poor. I suspected he had an intercranial bleed slowly squeezing his brain (that later turned out to not be the case). Even though we had established an airway, it took us so long to get him to the ambulance.

The director of the local EMS called me that evening and said the patient had made it to the hospital. I had never been a part of anything with this intensity. I definitely lost sleep over it. Partly just from the uncertainty of not knowing what the outcome would be. But also second-guessing if I had done everything that I could have.

The story doesn’t quite end there, however.

A week later, a friend of the patient called me. He had recovered well and was going to be discharged from the hospital. He’d chosen to share the story with the media, and the local TV station was going to interview him. They had asked if I would agree to be interviewed.

After the local news story ran, it was kind of a media blitz. In came numerous media requests. But honestly, the portrayal of the story made me feel really weird. It was overly dramatized and not entirely accurate. It really didn’t sit well with me.

Friends all over the country saw the story, and here’s what they got from the coverage:

I was biking behind the patient when he crashed.

I had my own tools. Even the patient himself was told I used my own blade to make the incision.

The true story is what I just told you: A half-dozen emergency medical personnel were already there when I arrived. It was a combination of all of us – together – in the right place at the right time.

A month later, the patient and his family drove to the city where I live to take me out to lunch. It was emotional. There were plenty of tears. His wife and daughter were expressing a lot of gratitude and had some gifts for me. I was able to get his version of the story and learned some details. He had facial trauma in the past with some reconstruction. I realized that perhaps those anatomical changes affected my ability to do the intubation.

I hope to never again have to do this outside of the hospital. But I suppose I’m more prepared than ever now. I’ve reviewed my cricothyrotomy technique many times since then.

I was trained as a family doctor and did clinic and hospital medicine for several years. It was only in 2020 that I transitioned to doing emergency medicine work in a rural hospital. So, 2 years earlier, I’m not sure I would’ve been able to do what I did that day. To me, it was almost symbolic of the transition of my practice to emergency medicine.

I’m still in touch with the patient. We’ve talked about biking together. That hasn’t happened yet, but it may very well happen someday.

Jesse Coenen, MD, is an emergency medicine physician at Hayward Area Memorial Hospital in Hayward, Wisc.

A version of this article first appeared on Medscape.com.

It started as a mountain biking excursion with two friends. When we drove into the trailhead parking lot, we saw several emergency vehicles. Then a helicopter passed overhead. As we got on our bikes, a police officer told us there’d been an accident out on the trail and to be careful because emergency personnel were going to be bringing in the patient. So we started the ride cautiously, ready to yield to emergency medical services.

Half a mile down the trail, we encountered another police officer. He asked if we would be willing to go back to get an oxygen tank from the ambulance and carry it out to the scene. The three of us turned around, went back to the parking lot and were able to snag a tank of oxygen. We put it in a backpack and biked out again.

We found the scene about a mile down the trail. An adult male was lying on his back in the dirt after a crash. His eyes were closed and he wasn’t moving except for occasional breaths. Six emergency medical personnel huddled around him, one assisting breaths with a bag mask. I didn’t introduce myself initially. I just listened to hear what was happening.

They were debating the dose of medication to give him in order to intubate. I knew the answer to that question, so I introduced myself. They were happy to have somebody else to assist.

They already had an IV in place and quite a lot of supplies. They administered the meds and the paramedic attempted to intubate through the mouth. Within a few seconds, she pulled the intubating blade out and said, “I’m not going to be able to get this. His tongue is too big.”

I took the blade myself and kneeled at the head of the victim. I made three attempts at intubating, and each time couldn’t view the landmarks. I wasn’t sure if his tongue was too large or if there was some traumatic injury. To make it more difficult, a lot of secretions clogged the airway. The paramedics had a portable suction, which was somewhat functional, but I still couldn’t visualize the landmarks.

I started asking about alternative methods of establishing an airway. They had an i-gel, which is a supraglottic device that goes into the back of the mouth. So, we placed it. But when we attached the bag, air still wasn’t getting into the lungs.

We removed it and put the bag mask back on. Now I was worried. We were having difficulty keeping his oxygen above 90%. I examined the chest and abdomen again. I was wondering if perhaps he was having some gastric distention, which can result from prolonged bagging, but that didn’t seem to be the case.

Bagging became progressively more difficult, and the oxygen slowly trended down through the 80s. Then the 70s. Heart rate dropped below 60 beats per minute. The trajectory was obvious.

That’s when I asked if they had the tools for a surgical airway.

No one thought the question was crazy. In fact, they pulled out a scalpel from an equipment bag.

But now I had to actually do it. I knelt next to the patient, trying to palpate the front of the neck to identify the correct location to cut. I had difficulty finding the appropriate landmarks there as well. Frustrating.

I glanced at the monitor. O₂ was now in the 60s. Later the paramedic told me the heart rate was down to 30.

One of the medics looked me in the eye and said, “We’ve got to do something. The time is now.” That helped me snap out of it and act. I made my large vertical incision on the front of the victim’s neck, which of course resulted in quite a bit of bleeding.

My two friends, who were watching, later told me this was the moment the intensity of the scene really increased (it was already pretty intense for me, thanks).

Next, I made the horizontal stab incision. Then I probed with my finger, but it seems the incision hadn’t reached the trachea. I had to make the stab much deeper than I would’ve thought.

And then air bubbled out through the blood. A paramedic was ready with the ET tube in hand and she put it through the incision. We attached the bag. We had air movement into the lungs, and within minutes the oxygen came up.

Not long after, the flight paramedics from the helicopter showed up, having jogged a mile through the woods. They seemed rather surprised to find a patient with a cricothyrotomy. We filled them in on the situation. Now we had to get the patient out of the woods (literally and figuratively).

The emergency responders had a really great transport device: A litter with one big wheel underneath in the middle so we could roll the patient down the mountain bike trail over rocks relatively safely. One person’s job was to hold the tube as we went since we didn’t have suture to hold it in place.

We got back to the parking lot and loaded him into the ambulance, which drove another mile to the helicopter, which then had to take him a hundred miles to the hospital.

To be honest, I thought the prognosis was poor. I suspected he had an intercranial bleed slowly squeezing his brain (that later turned out to not be the case). Even though we had established an airway, it took us so long to get him to the ambulance.

The director of the local EMS called me that evening and said the patient had made it to the hospital. I had never been a part of anything with this intensity. I definitely lost sleep over it. Partly just from the uncertainty of not knowing what the outcome would be. But also second-guessing if I had done everything that I could have.

The story doesn’t quite end there, however.

A week later, a friend of the patient called me. He had recovered well and was going to be discharged from the hospital. He’d chosen to share the story with the media, and the local TV station was going to interview him. They had asked if I would agree to be interviewed.

After the local news story ran, it was kind of a media blitz. In came numerous media requests. But honestly, the portrayal of the story made me feel really weird. It was overly dramatized and not entirely accurate. It really didn’t sit well with me.

Friends all over the country saw the story, and here’s what they got from the coverage:

I was biking behind the patient when he crashed.

I had my own tools. Even the patient himself was told I used my own blade to make the incision.

The true story is what I just told you: A half-dozen emergency medical personnel were already there when I arrived. It was a combination of all of us – together – in the right place at the right time.

A month later, the patient and his family drove to the city where I live to take me out to lunch. It was emotional. There were plenty of tears. His wife and daughter were expressing a lot of gratitude and had some gifts for me. I was able to get his version of the story and learned some details. He had facial trauma in the past with some reconstruction. I realized that perhaps those anatomical changes affected my ability to do the intubation.

I hope to never again have to do this outside of the hospital. But I suppose I’m more prepared than ever now. I’ve reviewed my cricothyrotomy technique many times since then.

I was trained as a family doctor and did clinic and hospital medicine for several years. It was only in 2020 that I transitioned to doing emergency medicine work in a rural hospital. So, 2 years earlier, I’m not sure I would’ve been able to do what I did that day. To me, it was almost symbolic of the transition of my practice to emergency medicine.

I’m still in touch with the patient. We’ve talked about biking together. That hasn’t happened yet, but it may very well happen someday.

Jesse Coenen, MD, is an emergency medicine physician at Hayward Area Memorial Hospital in Hayward, Wisc.

A version of this article first appeared on Medscape.com.

It started as a mountain biking excursion with two friends. When we drove into the trailhead parking lot, we saw several emergency vehicles. Then a helicopter passed overhead. As we got on our bikes, a police officer told us there’d been an accident out on the trail and to be careful because emergency personnel were going to be bringing in the patient. So we started the ride cautiously, ready to yield to emergency medical services.

Half a mile down the trail, we encountered another police officer. He asked if we would be willing to go back to get an oxygen tank from the ambulance and carry it out to the scene. The three of us turned around, went back to the parking lot and were able to snag a tank of oxygen. We put it in a backpack and biked out again.

We found the scene about a mile down the trail. An adult male was lying on his back in the dirt after a crash. His eyes were closed and he wasn’t moving except for occasional breaths. Six emergency medical personnel huddled around him, one assisting breaths with a bag mask. I didn’t introduce myself initially. I just listened to hear what was happening.

They were debating the dose of medication to give him in order to intubate. I knew the answer to that question, so I introduced myself. They were happy to have somebody else to assist.

They already had an IV in place and quite a lot of supplies. They administered the meds and the paramedic attempted to intubate through the mouth. Within a few seconds, she pulled the intubating blade out and said, “I’m not going to be able to get this. His tongue is too big.”

I took the blade myself and kneeled at the head of the victim. I made three attempts at intubating, and each time couldn’t view the landmarks. I wasn’t sure if his tongue was too large or if there was some traumatic injury. To make it more difficult, a lot of secretions clogged the airway. The paramedics had a portable suction, which was somewhat functional, but I still couldn’t visualize the landmarks.

I started asking about alternative methods of establishing an airway. They had an i-gel, which is a supraglottic device that goes into the back of the mouth. So, we placed it. But when we attached the bag, air still wasn’t getting into the lungs.

We removed it and put the bag mask back on. Now I was worried. We were having difficulty keeping his oxygen above 90%. I examined the chest and abdomen again. I was wondering if perhaps he was having some gastric distention, which can result from prolonged bagging, but that didn’t seem to be the case.

Bagging became progressively more difficult, and the oxygen slowly trended down through the 80s. Then the 70s. Heart rate dropped below 60 beats per minute. The trajectory was obvious.

That’s when I asked if they had the tools for a surgical airway.

No one thought the question was crazy. In fact, they pulled out a scalpel from an equipment bag.

But now I had to actually do it. I knelt next to the patient, trying to palpate the front of the neck to identify the correct location to cut. I had difficulty finding the appropriate landmarks there as well. Frustrating.

I glanced at the monitor. O₂ was now in the 60s. Later the paramedic told me the heart rate was down to 30.

One of the medics looked me in the eye and said, “We’ve got to do something. The time is now.” That helped me snap out of it and act. I made my large vertical incision on the front of the victim’s neck, which of course resulted in quite a bit of bleeding.

My two friends, who were watching, later told me this was the moment the intensity of the scene really increased (it was already pretty intense for me, thanks).

Next, I made the horizontal stab incision. Then I probed with my finger, but it seems the incision hadn’t reached the trachea. I had to make the stab much deeper than I would’ve thought.

And then air bubbled out through the blood. A paramedic was ready with the ET tube in hand and she put it through the incision. We attached the bag. We had air movement into the lungs, and within minutes the oxygen came up.

Not long after, the flight paramedics from the helicopter showed up, having jogged a mile through the woods. They seemed rather surprised to find a patient with a cricothyrotomy. We filled them in on the situation. Now we had to get the patient out of the woods (literally and figuratively).

The emergency responders had a really great transport device: A litter with one big wheel underneath in the middle so we could roll the patient down the mountain bike trail over rocks relatively safely. One person’s job was to hold the tube as we went since we didn’t have suture to hold it in place.

We got back to the parking lot and loaded him into the ambulance, which drove another mile to the helicopter, which then had to take him a hundred miles to the hospital.

To be honest, I thought the prognosis was poor. I suspected he had an intercranial bleed slowly squeezing his brain (that later turned out to not be the case). Even though we had established an airway, it took us so long to get him to the ambulance.

The director of the local EMS called me that evening and said the patient had made it to the hospital. I had never been a part of anything with this intensity. I definitely lost sleep over it. Partly just from the uncertainty of not knowing what the outcome would be. But also second-guessing if I had done everything that I could have.

The story doesn’t quite end there, however.

A week later, a friend of the patient called me. He had recovered well and was going to be discharged from the hospital. He’d chosen to share the story with the media, and the local TV station was going to interview him. They had asked if I would agree to be interviewed.

After the local news story ran, it was kind of a media blitz. In came numerous media requests. But honestly, the portrayal of the story made me feel really weird. It was overly dramatized and not entirely accurate. It really didn’t sit well with me.

Friends all over the country saw the story, and here’s what they got from the coverage:

I was biking behind the patient when he crashed.

I had my own tools. Even the patient himself was told I used my own blade to make the incision.

The true story is what I just told you: A half-dozen emergency medical personnel were already there when I arrived. It was a combination of all of us – together – in the right place at the right time.

A month later, the patient and his family drove to the city where I live to take me out to lunch. It was emotional. There were plenty of tears. His wife and daughter were expressing a lot of gratitude and had some gifts for me. I was able to get his version of the story and learned some details. He had facial trauma in the past with some reconstruction. I realized that perhaps those anatomical changes affected my ability to do the intubation.

I hope to never again have to do this outside of the hospital. But I suppose I’m more prepared than ever now. I’ve reviewed my cricothyrotomy technique many times since then.

I was trained as a family doctor and did clinic and hospital medicine for several years. It was only in 2020 that I transitioned to doing emergency medicine work in a rural hospital. So, 2 years earlier, I’m not sure I would’ve been able to do what I did that day. To me, it was almost symbolic of the transition of my practice to emergency medicine.

I’m still in touch with the patient. We’ve talked about biking together. That hasn’t happened yet, but it may very well happen someday.

Jesse Coenen, MD, is an emergency medicine physician at Hayward Area Memorial Hospital in Hayward, Wisc.

A version of this article first appeared on Medscape.com.

The homicide rate among children in the United States rose by more than 4% per year since 2013 but jumped nearly 28% from 2019 to 2020, new data show.

Although long-term trends varied by region and demographics, with some groups and areas seeing declines in killings, the increases were the highest among Black children and boys aged 11-17, according to the researchers, who attribute the surge in violent deaths to a recent rise in firearm-related killings in children. Gun violence is now the leading cause of death for children in the United States, claiming what the American Academy of Pediatrics has equated to a classroomful of lives each day.

“There are troubling recent rate increases among several groups, warranting immediate attention, with some racial and ethnic disparities persisting for more than 20 years,” said Rebecca F. Wilson, PhD, of the U.S. Centers for Disease Control and Prevention, who helped conduct the study.

Dr. Wilson and her colleagues, whose findings appear in JAMA Pediatrics, examined data on 38,362 homicide victims in the United States aged 0-17 years who were killed between 1999 and 2020.

The nation’s overall homicide rate for youth fell by 5.6% per year from 2007 to 2013 before reversing course. Between 2013 and 2020, the overall rate rose 4.3% annually.

The figures show that not all children are affected equally. The rate of child homicide has fallen significantly for girls, infants, and children ages 5 years and under – whose deaths often result from caregiver neglect or violence – as well as Asian or Pacific Islanders, Whites, and those living in the Northeast.

But the child homicide rate in the South increased 6.4% per year between 2013 and 2020, while that of children in both rural America and in cities is also rising after years of decline, according to the researchers.

The suspected perpetrator was known in about 64% of child killings. Nearly 80% of those perpetrators were male.

Dr. Wilson and her colleagues also note that the COVID-19 pandemic appears to have precipitated a wave of gun-related violence among children – a link borne out by another recent paper in JAMA Pediatrics. (Recent data suggest that intentional firearm injuries are often misclassified as accidental.)

The study found that gun-related injuries in youth remained elevated through 2021, with non-Hispanic Black children and those with public insurance making up greater proportions of victims during the pandemic. The researchers identified 1,815 firearm injuries per month before the pandemic and 2,759 per month during the outbreak, a 52% increase.

Although the two studies look at different data, both show that Black children are most affected by gun violence, experts said.

“This demonstrates a critical issue for the medical, public health, and legal communities: While homicide is often presented as a criminal justice problem, it is increasingly a racial justice problem,” said Katherine E. Hoops, MD, of the Center for Gun Violence Solutions at Johns Hopkins Bloomberg School of Public Health, Baltimore.

In an editorial about the homicide study, researchers at the University of Pennsylvania, Philadelphia, called the violent deaths “preventable and unacceptable.” Eliminating such deaths “must be among our first priorities,” they wrote.

The editorial authors also noted that researchers know relatively little about nonfatal violent injuries such as those involving firearms. “These injuries are important not only because they may have life-altering consequences for children and families but also because understanding only the most severe form of any health condition (death) will hamper our ability to design and evaluate prevention strategies,” they wrote.

Dr. Wilson’s group identified different causes of youth homicide for different age groups – and the potential interventions for each differ. Although the youngest children are more likely to die from abuse or neglect, those aged 6-10 years were most likely to die by firearm, often associated with abuse that ends in suicide. Meanwhile, adolescents aged 11-17 were more subject to peer violence.

For Dr. Hoops, “each of these differences has important policy implications, including the need for policies that address structural racism, poverty, and systematic disadvantage – but also firearm safe storage to prevent youth violence and suicide [and] reduction of access to lethal means, such as through extreme risk protective orders when someone is at risk of harming themselves or others.”

Dr. Wilson agreed. “We know child homicides are preventable,” she said. “The rate decrease for some groups is encouraging, yet more can be done to protect all children.”

A version of this article first appeared on Medscape.com.

The homicide rate among children in the United States rose by more than 4% per year since 2013 but jumped nearly 28% from 2019 to 2020, new data show.

Although long-term trends varied by region and demographics, with some groups and areas seeing declines in killings, the increases were the highest among Black children and boys aged 11-17, according to the researchers, who attribute the surge in violent deaths to a recent rise in firearm-related killings in children. Gun violence is now the leading cause of death for children in the United States, claiming what the American Academy of Pediatrics has equated to a classroomful of lives each day.

“There are troubling recent rate increases among several groups, warranting immediate attention, with some racial and ethnic disparities persisting for more than 20 years,” said Rebecca F. Wilson, PhD, of the U.S. Centers for Disease Control and Prevention, who helped conduct the study.

Dr. Wilson and her colleagues, whose findings appear in JAMA Pediatrics, examined data on 38,362 homicide victims in the United States aged 0-17 years who were killed between 1999 and 2020.

The nation’s overall homicide rate for youth fell by 5.6% per year from 2007 to 2013 before reversing course. Between 2013 and 2020, the overall rate rose 4.3% annually.

The figures show that not all children are affected equally. The rate of child homicide has fallen significantly for girls, infants, and children ages 5 years and under – whose deaths often result from caregiver neglect or violence – as well as Asian or Pacific Islanders, Whites, and those living in the Northeast.

But the child homicide rate in the South increased 6.4% per year between 2013 and 2020, while that of children in both rural America and in cities is also rising after years of decline, according to the researchers.

The suspected perpetrator was known in about 64% of child killings. Nearly 80% of those perpetrators were male.

Dr. Wilson and her colleagues also note that the COVID-19 pandemic appears to have precipitated a wave of gun-related violence among children – a link borne out by another recent paper in JAMA Pediatrics. (Recent data suggest that intentional firearm injuries are often misclassified as accidental.)

The study found that gun-related injuries in youth remained elevated through 2021, with non-Hispanic Black children and those with public insurance making up greater proportions of victims during the pandemic. The researchers identified 1,815 firearm injuries per month before the pandemic and 2,759 per month during the outbreak, a 52% increase.

Although the two studies look at different data, both show that Black children are most affected by gun violence, experts said.

“This demonstrates a critical issue for the medical, public health, and legal communities: While homicide is often presented as a criminal justice problem, it is increasingly a racial justice problem,” said Katherine E. Hoops, MD, of the Center for Gun Violence Solutions at Johns Hopkins Bloomberg School of Public Health, Baltimore.

In an editorial about the homicide study, researchers at the University of Pennsylvania, Philadelphia, called the violent deaths “preventable and unacceptable.” Eliminating such deaths “must be among our first priorities,” they wrote.

The editorial authors also noted that researchers know relatively little about nonfatal violent injuries such as those involving firearms. “These injuries are important not only because they may have life-altering consequences for children and families but also because understanding only the most severe form of any health condition (death) will hamper our ability to design and evaluate prevention strategies,” they wrote.

Dr. Wilson’s group identified different causes of youth homicide for different age groups – and the potential interventions for each differ. Although the youngest children are more likely to die from abuse or neglect, those aged 6-10 years were most likely to die by firearm, often associated with abuse that ends in suicide. Meanwhile, adolescents aged 11-17 were more subject to peer violence.

For Dr. Hoops, “each of these differences has important policy implications, including the need for policies that address structural racism, poverty, and systematic disadvantage – but also firearm safe storage to prevent youth violence and suicide [and] reduction of access to lethal means, such as through extreme risk protective orders when someone is at risk of harming themselves or others.”

Dr. Wilson agreed. “We know child homicides are preventable,” she said. “The rate decrease for some groups is encouraging, yet more can be done to protect all children.”

A version of this article first appeared on Medscape.com.

The homicide rate among children in the United States rose by more than 4% per year since 2013 but jumped nearly 28% from 2019 to 2020, new data show.

Although long-term trends varied by region and demographics, with some groups and areas seeing declines in killings, the increases were the highest among Black children and boys aged 11-17, according to the researchers, who attribute the surge in violent deaths to a recent rise in firearm-related killings in children. Gun violence is now the leading cause of death for children in the United States, claiming what the American Academy of Pediatrics has equated to a classroomful of lives each day.

“There are troubling recent rate increases among several groups, warranting immediate attention, with some racial and ethnic disparities persisting for more than 20 years,” said Rebecca F. Wilson, PhD, of the U.S. Centers for Disease Control and Prevention, who helped conduct the study.

Dr. Wilson and her colleagues, whose findings appear in JAMA Pediatrics, examined data on 38,362 homicide victims in the United States aged 0-17 years who were killed between 1999 and 2020.

The nation’s overall homicide rate for youth fell by 5.6% per year from 2007 to 2013 before reversing course. Between 2013 and 2020, the overall rate rose 4.3% annually.

The figures show that not all children are affected equally. The rate of child homicide has fallen significantly for girls, infants, and children ages 5 years and under – whose deaths often result from caregiver neglect or violence – as well as Asian or Pacific Islanders, Whites, and those living in the Northeast.

But the child homicide rate in the South increased 6.4% per year between 2013 and 2020, while that of children in both rural America and in cities is also rising after years of decline, according to the researchers.

The suspected perpetrator was known in about 64% of child killings. Nearly 80% of those perpetrators were male.

Dr. Wilson and her colleagues also note that the COVID-19 pandemic appears to have precipitated a wave of gun-related violence among children – a link borne out by another recent paper in JAMA Pediatrics. (Recent data suggest that intentional firearm injuries are often misclassified as accidental.)

The study found that gun-related injuries in youth remained elevated through 2021, with non-Hispanic Black children and those with public insurance making up greater proportions of victims during the pandemic. The researchers identified 1,815 firearm injuries per month before the pandemic and 2,759 per month during the outbreak, a 52% increase.

Although the two studies look at different data, both show that Black children are most affected by gun violence, experts said.

“This demonstrates a critical issue for the medical, public health, and legal communities: While homicide is often presented as a criminal justice problem, it is increasingly a racial justice problem,” said Katherine E. Hoops, MD, of the Center for Gun Violence Solutions at Johns Hopkins Bloomberg School of Public Health, Baltimore.

In an editorial about the homicide study, researchers at the University of Pennsylvania, Philadelphia, called the violent deaths “preventable and unacceptable.” Eliminating such deaths “must be among our first priorities,” they wrote.

The editorial authors also noted that researchers know relatively little about nonfatal violent injuries such as those involving firearms. “These injuries are important not only because they may have life-altering consequences for children and families but also because understanding only the most severe form of any health condition (death) will hamper our ability to design and evaluate prevention strategies,” they wrote.

Dr. Wilson’s group identified different causes of youth homicide for different age groups – and the potential interventions for each differ. Although the youngest children are more likely to die from abuse or neglect, those aged 6-10 years were most likely to die by firearm, often associated with abuse that ends in suicide. Meanwhile, adolescents aged 11-17 were more subject to peer violence.

For Dr. Hoops, “each of these differences has important policy implications, including the need for policies that address structural racism, poverty, and systematic disadvantage – but also firearm safe storage to prevent youth violence and suicide [and] reduction of access to lethal means, such as through extreme risk protective orders when someone is at risk of harming themselves or others.”

Dr. Wilson agreed. “We know child homicides are preventable,” she said. “The rate decrease for some groups is encouraging, yet more can be done to protect all children.”

A version of this article first appeared on Medscape.com.

In a new updated report, the American Academy of Pediatrics urges pediatricians to understand signs of exploitation and labor/sex trafficking and learn how to support children and adolescents who are targeted.

“It’s incredibly scary when you encounter someone you worry is a victim, and you don’t know how to help them, and they’re not saying what’s going on,” pediatrician and report coauthor Dana Kaplan, MD, of Staten Island (N.Y.) University Hospital, said in an interview. “Every case is so unique and different: There’s no algorithm of ‘If A, then B, then C.’ You have to approach each person as an individual, and it takes time to make sure you’re thinking things through about how to provide what’s needed.”

The AAP published the clinical report, which is intended to provide guidance to pediatricians, in the January 2023 issue of Pediatrics. The organization previously tackled this topic in a 2017 clinical report, and Dr. Kaplan said the new report includes updated recommendations.

As the new report notes, there aren’t reliable estimates of exploited children in the United States, although millions are thought to be trafficked and subjected to forced labor around the world. “By virtue of their young age, children and adolescents are vulnerable to manipulation and exploitation, because they have limited life experiences, a need for attachment and acceptance, an immature prefrontal cortex ... and limited options for action,” the report says.

Dr. Kaplan puts it this way: “By the nature of being a child, you’re vulnerable.”

Still, health care professionals often aren’t trained in regard to human trafficking, the report says, even though it’s clear that they “must remain alert for the possibility.”

Dr. Kaplan, who has special training in child abuse and often sees children at risk, cautioned that children usually don’t directly say that they need help. “That’s generally not the case. They don’t articulate what’s going on around them as unsafe, or concerning, or dangerous. If you go and see a doctor for 10 minutes, are you going to tell them everything?

Instead, clinicians must often rely on their own observations. The report lists multiple possible signs of exploitation.

• The patient is accompanied by a domineering adult who does not allow the child to answer questions or accompanied by an unrelated adult. Inconsistent information is provided by the patient or companion. There’s a delay in seeking medical care.
• The patient has multiple sexually transmitted infections, previous pregnancy or termination, and/or frequent visits for emergency contraception. There are signs of prior sexual abuse, assault, or other maltreatment.
• The patient is withdrawn, fearful, hostile, or has a suspicious demeanor. The patient is constantly checking his or her phone and appears anxious or afraid.

What should clinicians do if they suspect exploitation? The report recommends that health care organizations develop guidelines for workers to follow. For her part, Dr. Kaplan advises colleagues to let patients lead conversations and not dig too deeply into their lives.

“Don’t turn into an investigator. This is not [Law & Order] SVU,” she said. “Stay focused on what you’re trained to do – provide health care.”

That doesn’t mean clinicians should ignore signs of trouble. It’s crucial to develop trust with the patient over time, she said, and turn to a specialist in your community or institution if you have suspicions.

And be careful to not portray victims as perpetrators. The new report emphasizes that “it’s important for health care providers to emphasize to authorities that the patient is a victim of exploitation who needs services rather than a juvenile offender.”

The report also highlights the importance of creating an environment that supports clinicians themselves: “Self-care for the clinician is critical in preventing and addressing secondary traumatic stress. A work environment that fosters peer support, encourages open discussion of work-related stress, and implements reasonable work-life balance policies can help protect providers from secondary stress and its consequences.”

Resources for clinicians include the National Human Trafficking Hotline, the federal Office of Trafficking in Persons, and the Centers for Disease Control and Prevention’s domestic refugee screening guidelines.

The study has no external funding. The authors report no disclosures.

In a new updated report, the American Academy of Pediatrics urges pediatricians to understand signs of exploitation and labor/sex trafficking and learn how to support children and adolescents who are targeted.

“It’s incredibly scary when you encounter someone you worry is a victim, and you don’t know how to help them, and they’re not saying what’s going on,” pediatrician and report coauthor Dana Kaplan, MD, of Staten Island (N.Y.) University Hospital, said in an interview. “Every case is so unique and different: There’s no algorithm of ‘If A, then B, then C.’ You have to approach each person as an individual, and it takes time to make sure you’re thinking things through about how to provide what’s needed.”

The AAP published the clinical report, which is intended to provide guidance to pediatricians, in the January 2023 issue of Pediatrics. The organization previously tackled this topic in a 2017 clinical report, and Dr. Kaplan said the new report includes updated recommendations.

As the new report notes, there aren’t reliable estimates of exploited children in the United States, although millions are thought to be trafficked and subjected to forced labor around the world. “By virtue of their young age, children and adolescents are vulnerable to manipulation and exploitation, because they have limited life experiences, a need for attachment and acceptance, an immature prefrontal cortex ... and limited options for action,” the report says.

Dr. Kaplan puts it this way: “By the nature of being a child, you’re vulnerable.”

Still, health care professionals often aren’t trained in regard to human trafficking, the report says, even though it’s clear that they “must remain alert for the possibility.”

Dr. Kaplan, who has special training in child abuse and often sees children at risk, cautioned that children usually don’t directly say that they need help. “That’s generally not the case. They don’t articulate what’s going on around them as unsafe, or concerning, or dangerous. If you go and see a doctor for 10 minutes, are you going to tell them everything?

Instead, clinicians must often rely on their own observations. The report lists multiple possible signs of exploitation.

• The patient is accompanied by a domineering adult who does not allow the child to answer questions or accompanied by an unrelated adult. Inconsistent information is provided by the patient or companion. There’s a delay in seeking medical care.
• The patient has multiple sexually transmitted infections, previous pregnancy or termination, and/or frequent visits for emergency contraception. There are signs of prior sexual abuse, assault, or other maltreatment.
• The patient is withdrawn, fearful, hostile, or has a suspicious demeanor. The patient is constantly checking his or her phone and appears anxious or afraid.

What should clinicians do if they suspect exploitation? The report recommends that health care organizations develop guidelines for workers to follow. For her part, Dr. Kaplan advises colleagues to let patients lead conversations and not dig too deeply into their lives.

“Don’t turn into an investigator. This is not [Law & Order] SVU,” she said. “Stay focused on what you’re trained to do – provide health care.”

That doesn’t mean clinicians should ignore signs of trouble. It’s crucial to develop trust with the patient over time, she said, and turn to a specialist in your community or institution if you have suspicions.

And be careful to not portray victims as perpetrators. The new report emphasizes that “it’s important for health care providers to emphasize to authorities that the patient is a victim of exploitation who needs services rather than a juvenile offender.”

The report also highlights the importance of creating an environment that supports clinicians themselves: “Self-care for the clinician is critical in preventing and addressing secondary traumatic stress. A work environment that fosters peer support, encourages open discussion of work-related stress, and implements reasonable work-life balance policies can help protect providers from secondary stress and its consequences.”

Resources for clinicians include the National Human Trafficking Hotline, the federal Office of Trafficking in Persons, and the Centers for Disease Control and Prevention’s domestic refugee screening guidelines.

The study has no external funding. The authors report no disclosures.

In a new updated report, the American Academy of Pediatrics urges pediatricians to understand signs of exploitation and labor/sex trafficking and learn how to support children and adolescents who are targeted.

“It’s incredibly scary when you encounter someone you worry is a victim, and you don’t know how to help them, and they’re not saying what’s going on,” pediatrician and report coauthor Dana Kaplan, MD, of Staten Island (N.Y.) University Hospital, said in an interview. “Every case is so unique and different: There’s no algorithm of ‘If A, then B, then C.’ You have to approach each person as an individual, and it takes time to make sure you’re thinking things through about how to provide what’s needed.”

The AAP published the clinical report, which is intended to provide guidance to pediatricians, in the January 2023 issue of Pediatrics. The organization previously tackled this topic in a 2017 clinical report, and Dr. Kaplan said the new report includes updated recommendations.

As the new report notes, there aren’t reliable estimates of exploited children in the United States, although millions are thought to be trafficked and subjected to forced labor around the world. “By virtue of their young age, children and adolescents are vulnerable to manipulation and exploitation, because they have limited life experiences, a need for attachment and acceptance, an immature prefrontal cortex ... and limited options for action,” the report says.

Dr. Kaplan puts it this way: “By the nature of being a child, you’re vulnerable.”

Still, health care professionals often aren’t trained in regard to human trafficking, the report says, even though it’s clear that they “must remain alert for the possibility.”

Dr. Kaplan, who has special training in child abuse and often sees children at risk, cautioned that children usually don’t directly say that they need help. “That’s generally not the case. They don’t articulate what’s going on around them as unsafe, or concerning, or dangerous. If you go and see a doctor for 10 minutes, are you going to tell them everything?

Instead, clinicians must often rely on their own observations. The report lists multiple possible signs of exploitation.

• The patient is accompanied by a domineering adult who does not allow the child to answer questions or accompanied by an unrelated adult. Inconsistent information is provided by the patient or companion. There’s a delay in seeking medical care.
• The patient has multiple sexually transmitted infections, previous pregnancy or termination, and/or frequent visits for emergency contraception. There are signs of prior sexual abuse, assault, or other maltreatment.
• The patient is withdrawn, fearful, hostile, or has a suspicious demeanor. The patient is constantly checking his or her phone and appears anxious or afraid.

What should clinicians do if they suspect exploitation? The report recommends that health care organizations develop guidelines for workers to follow. For her part, Dr. Kaplan advises colleagues to let patients lead conversations and not dig too deeply into their lives.

“Don’t turn into an investigator. This is not [Law & Order] SVU,” she said. “Stay focused on what you’re trained to do – provide health care.”

That doesn’t mean clinicians should ignore signs of trouble. It’s crucial to develop trust with the patient over time, she said, and turn to a specialist in your community or institution if you have suspicions.

And be careful to not portray victims as perpetrators. The new report emphasizes that “it’s important for health care providers to emphasize to authorities that the patient is a victim of exploitation who needs services rather than a juvenile offender.”

The report also highlights the importance of creating an environment that supports clinicians themselves: “Self-care for the clinician is critical in preventing and addressing secondary traumatic stress. A work environment that fosters peer support, encourages open discussion of work-related stress, and implements reasonable work-life balance policies can help protect providers from secondary stress and its consequences.”

Resources for clinicians include the National Human Trafficking Hotline, the federal Office of Trafficking in Persons, and the Centers for Disease Control and Prevention’s domestic refugee screening guidelines.

The study has no external funding. The authors report no disclosures.

More than a quarter of patients who were shot by assailants with guns had their injuries mislabeled as “unintentional” at hospital discharge, according to a review of more than 1,200 cases at three U.S. trauma centers.

These coding inaccuracies could distort our understanding of gun violence in the United States and make it seem like accidental shootings are more common than they really are, researchers reported in JAMA Network Open.

“The systematic error in intent classification is not widely known or acknowledged by researchers in this field,” Philip J. Cook, PhD, of Duke University, Durham, N.C., and Susan T. Parker, of the University of Michigan, Ann Arbor, wrote in an invited commentary about the new findings. “The bulk of all shootings, nonfatal and fatal together, are assaults, which is to say the result of one person intentionally shooting another. An accurate statistical portrait thus suggests that gun violence is predominantly a crime problem.”

In 2020, 79% of all homicides and 53% of all suicides involved firearms, the CDC reported. Gun violence is now the leading cause of death for children in the United States, government data show.

For the new study, Matthew Miller, MD, ScD, of Northeastern University and the Harvard Injury Control Research Center in Boston, and his colleagues examined how International Classification of Diseases (ICD) codes may misclassify the intent behind gunshot injuries.

Dr. Miller’s group looked at 1,227 incidents between 2008 and 2019 at three major trauma centers – Brigham and Women’s Hospital and Massachusetts General Hospital, both in Boston, and Harborview Medical Center in Seattle.

Of those shootings, 837 (68.2%) involved assaults, 168 (13.5%) were unintentional, 124 (9.9%) were deliberate self-harm, and 43 (3.4%) were instances of legal intervention, based on the researchers’ review of medical records.

ICD codes at discharge, however, labeled 581 cases (47.4%) as assaults and 432 (35.2%) as unintentional.

The researchers found that 234 of the 837 assaults (28%) and 9 of the 43 legal interventions (20.9%) were miscoded as unintentional. This problem occurred even when the “medical narrative explicitly indicated that the shooting was an act of interpersonal violence,” such as a drive-by shooting or an act of domestic violence, the researchers reported.

Hospital trauma registrars, who detail the circumstances surrounding injuries, were mostly in agreement with the researchers.

Medical coders “would likely have little trouble characterizing firearm injury intent accurately if incentives were created for them to do so,” the authors wrote.

Trends and interventions

Separately, researchers published studies showing that gun violence tends to affect various demographics differently, and that remediating abandoned houses could help reduce gun crime.

Lindsay Young, of the University of Cincinnati, and Henry Xiang, MD, PhD, director of the Center for Pediatric Trauma Research at Nationwide Children’s Hospital in Columbus, Ohio, analyzed rates of firearm deaths from 1981 to 2020.

They found that the rate of firearm-related homicide was five times higher among males than females, and the rate of suicide involving firearms was nearly seven times higher for men, they reported in PLOS ONE.

Black men were the group most affected by homicide, whereas White men were most affected by suicide, they found.

To see if fixing abandoned properties would improve health and reduce gun violence in low-income, Black neighborhoods in Philadelphia, Eugenia C. South, MD, of the University of Pennsylvania, Philadelphia, and colleagues conducted a randomized trial.

They randomly assigned abandoned properties in some areas to undergo full remediation (installing working windows and doors, cleaning trash, and weeding); trash cleanup and weeding only; or no intervention.

“Abandoned houses that were remediated showed substantial drops in nearby weapons violations (−8.43%), gun assaults (−13.12%), and to a lesser extent shootings (−6.96%),” the researchers reported.

The intervention targets effects of segregation that have resulted from “historical and ongoing government and private-sector policies” that lead to disinvestment in Black, urban communities, they wrote. Abandoned houses can be used to store firearms and for other illegal activity. They also can engender feelings of fear, neglect, and stress in communities, the researchers noted.

Dr. Miller’s study was funded by the National Collaborative on Gun Violence Research; coauthors disclosed corporate, government, and university grants. The full list of disclosures can be found with the original article. Editorialists Dr. Cook and Dr. Parker report no relevant financial relationships. Dr. South’s study was funded by the National Institutes of Health. Dr. South and some coauthors disclosed government grants.
 

A version of this article first appeared on Medscape.com.

More than a quarter of patients who were shot by assailants with guns had their injuries mislabeled as “unintentional” at hospital discharge, according to a review of more than 1,200 cases at three U.S. trauma centers.

These coding inaccuracies could distort our understanding of gun violence in the United States and make it seem like accidental shootings are more common than they really are, researchers reported in JAMA Network Open.

“The systematic error in intent classification is not widely known or acknowledged by researchers in this field,” Philip J. Cook, PhD, of Duke University, Durham, N.C., and Susan T. Parker, of the University of Michigan, Ann Arbor, wrote in an invited commentary about the new findings. “The bulk of all shootings, nonfatal and fatal together, are assaults, which is to say the result of one person intentionally shooting another. An accurate statistical portrait thus suggests that gun violence is predominantly a crime problem.”

In 2020, 79% of all homicides and 53% of all suicides involved firearms, the CDC reported. Gun violence is now the leading cause of death for children in the United States, government data show.

For the new study, Matthew Miller, MD, ScD, of Northeastern University and the Harvard Injury Control Research Center in Boston, and his colleagues examined how International Classification of Diseases (ICD) codes may misclassify the intent behind gunshot injuries.

Dr. Miller’s group looked at 1,227 incidents between 2008 and 2019 at three major trauma centers – Brigham and Women’s Hospital and Massachusetts General Hospital, both in Boston, and Harborview Medical Center in Seattle.

Of those shootings, 837 (68.2%) involved assaults, 168 (13.5%) were unintentional, 124 (9.9%) were deliberate self-harm, and 43 (3.4%) were instances of legal intervention, based on the researchers’ review of medical records.

ICD codes at discharge, however, labeled 581 cases (47.4%) as assaults and 432 (35.2%) as unintentional.

The researchers found that 234 of the 837 assaults (28%) and 9 of the 43 legal interventions (20.9%) were miscoded as unintentional. This problem occurred even when the “medical narrative explicitly indicated that the shooting was an act of interpersonal violence,” such as a drive-by shooting or an act of domestic violence, the researchers reported.

Hospital trauma registrars, who detail the circumstances surrounding injuries, were mostly in agreement with the researchers.

Medical coders “would likely have little trouble characterizing firearm injury intent accurately if incentives were created for them to do so,” the authors wrote.

Trends and interventions

Separately, researchers published studies showing that gun violence tends to affect various demographics differently, and that remediating abandoned houses could help reduce gun crime.

Lindsay Young, of the University of Cincinnati, and Henry Xiang, MD, PhD, director of the Center for Pediatric Trauma Research at Nationwide Children’s Hospital in Columbus, Ohio, analyzed rates of firearm deaths from 1981 to 2020.

They found that the rate of firearm-related homicide was five times higher among males than females, and the rate of suicide involving firearms was nearly seven times higher for men, they reported in PLOS ONE.

Black men were the group most affected by homicide, whereas White men were most affected by suicide, they found.

To see if fixing abandoned properties would improve health and reduce gun violence in low-income, Black neighborhoods in Philadelphia, Eugenia C. South, MD, of the University of Pennsylvania, Philadelphia, and colleagues conducted a randomized trial.

They randomly assigned abandoned properties in some areas to undergo full remediation (installing working windows and doors, cleaning trash, and weeding); trash cleanup and weeding only; or no intervention.

“Abandoned houses that were remediated showed substantial drops in nearby weapons violations (−8.43%), gun assaults (−13.12%), and to a lesser extent shootings (−6.96%),” the researchers reported.

The intervention targets effects of segregation that have resulted from “historical and ongoing government and private-sector policies” that lead to disinvestment in Black, urban communities, they wrote. Abandoned houses can be used to store firearms and for other illegal activity. They also can engender feelings of fear, neglect, and stress in communities, the researchers noted.

Dr. Miller’s study was funded by the National Collaborative on Gun Violence Research; coauthors disclosed corporate, government, and university grants. The full list of disclosures can be found with the original article. Editorialists Dr. Cook and Dr. Parker report no relevant financial relationships. Dr. South’s study was funded by the National Institutes of Health. Dr. South and some coauthors disclosed government grants.
 

A version of this article first appeared on Medscape.com.

More than a quarter of patients who were shot by assailants with guns had their injuries mislabeled as “unintentional” at hospital discharge, according to a review of more than 1,200 cases at three U.S. trauma centers.

These coding inaccuracies could distort our understanding of gun violence in the United States and make it seem like accidental shootings are more common than they really are, researchers reported in JAMA Network Open.

“The systematic error in intent classification is not widely known or acknowledged by researchers in this field,” Philip J. Cook, PhD, of Duke University, Durham, N.C., and Susan T. Parker, of the University of Michigan, Ann Arbor, wrote in an invited commentary about the new findings. “The bulk of all shootings, nonfatal and fatal together, are assaults, which is to say the result of one person intentionally shooting another. An accurate statistical portrait thus suggests that gun violence is predominantly a crime problem.”

In 2020, 79% of all homicides and 53% of all suicides involved firearms, the CDC reported. Gun violence is now the leading cause of death for children in the United States, government data show.

For the new study, Matthew Miller, MD, ScD, of Northeastern University and the Harvard Injury Control Research Center in Boston, and his colleagues examined how International Classification of Diseases (ICD) codes may misclassify the intent behind gunshot injuries.

Dr. Miller’s group looked at 1,227 incidents between 2008 and 2019 at three major trauma centers – Brigham and Women’s Hospital and Massachusetts General Hospital, both in Boston, and Harborview Medical Center in Seattle.

Of those shootings, 837 (68.2%) involved assaults, 168 (13.5%) were unintentional, 124 (9.9%) were deliberate self-harm, and 43 (3.4%) were instances of legal intervention, based on the researchers’ review of medical records.

ICD codes at discharge, however, labeled 581 cases (47.4%) as assaults and 432 (35.2%) as unintentional.

The researchers found that 234 of the 837 assaults (28%) and 9 of the 43 legal interventions (20.9%) were miscoded as unintentional. This problem occurred even when the “medical narrative explicitly indicated that the shooting was an act of interpersonal violence,” such as a drive-by shooting or an act of domestic violence, the researchers reported.

Hospital trauma registrars, who detail the circumstances surrounding injuries, were mostly in agreement with the researchers.

Medical coders “would likely have little trouble characterizing firearm injury intent accurately if incentives were created for them to do so,” the authors wrote.

Trends and interventions

Separately, researchers published studies showing that gun violence tends to affect various demographics differently, and that remediating abandoned houses could help reduce gun crime.

Lindsay Young, of the University of Cincinnati, and Henry Xiang, MD, PhD, director of the Center for Pediatric Trauma Research at Nationwide Children’s Hospital in Columbus, Ohio, analyzed rates of firearm deaths from 1981 to 2020.

They found that the rate of firearm-related homicide was five times higher among males than females, and the rate of suicide involving firearms was nearly seven times higher for men, they reported in PLOS ONE.

Black men were the group most affected by homicide, whereas White men were most affected by suicide, they found.

To see if fixing abandoned properties would improve health and reduce gun violence in low-income, Black neighborhoods in Philadelphia, Eugenia C. South, MD, of the University of Pennsylvania, Philadelphia, and colleagues conducted a randomized trial.

They randomly assigned abandoned properties in some areas to undergo full remediation (installing working windows and doors, cleaning trash, and weeding); trash cleanup and weeding only; or no intervention.

“Abandoned houses that were remediated showed substantial drops in nearby weapons violations (−8.43%), gun assaults (−13.12%), and to a lesser extent shootings (−6.96%),” the researchers reported.

The intervention targets effects of segregation that have resulted from “historical and ongoing government and private-sector policies” that lead to disinvestment in Black, urban communities, they wrote. Abandoned houses can be used to store firearms and for other illegal activity. They also can engender feelings of fear, neglect, and stress in communities, the researchers noted.

Dr. Miller’s study was funded by the National Collaborative on Gun Violence Research; coauthors disclosed corporate, government, and university grants. The full list of disclosures can be found with the original article. Editorialists Dr. Cook and Dr. Parker report no relevant financial relationships. Dr. South’s study was funded by the National Institutes of Health. Dr. South and some coauthors disclosed government grants.
 

A version of this article first appeared on Medscape.com.

Children and young adults who are exposed to a single CT scan of the head or neck before age 22 years are at significantly increased risk of developing a brain tumor, particularly glioma, after at least 5 years, according to results of the large EPI-CT study.

“Translation of our risk estimates to the clinical setting indicates that per 10,000 children who received one head CT examination, about one radiation-induced brain cancer is expected during the 5-15 years following the CT examination,” noted lead author Michael Hauptmann, PhD, from the Institute of Biostatistics and Registry Research, Brandenburg Medical School, Neuruppin, Germany, and coauthors.

“Next to the clinical benefit of most CT scans, there is a small risk of cancer from the radiation exposure,” Dr. Hauptmann told this news organization.

“So, CT examinations should only be used when necessary, and if they are used, the lowest achievable dose should be applied,” he said.

The study was published online in The Lancet Oncology.

“This is a thoughtful and well-conducted study by an outstanding multinational team of scientists that adds further weight to the growing body of evidence that has found exposure to CT scanning increases a child’s risk of developing brain cancer,” commented Rebecca Bindman-Smith, MD, from the University of California, San Francisco, who was not involved in the research.

“The results are real, and important,” she told this news organization, adding that “the authors were conservative in their assumptions, and performed a very large number of sensitivity analyses ... to check that the results were robust to a large range of assumptions – and the results changed relatively little.”

“I do not think there is enough awareness [about this risk],” Dr. Hauptmann said. “There is evidence that a nonnegligible number of CTs is unjustified according to guidelines, and there is evidence that doses vary substantially for the same CT between institutions in the same or different countries.”

Indeed, particularly in the United States, “we perform many CT scans in children and even more so in adults that are simply unnecessary,” agreed Dr. Bindman-Smith, who is professor of epidemiology and biostatistics at the University of California, San Francisco. “It is important for patients and providers to understand that nothing we do in medicine is risk free, including CT scanning. If a CT is necessary, the benefit almost certainly outweighs the risk. But if [not], then it should not be obtained. Both patients and providers must make thoroughly considered decisions before asking for or agreeing to a CT.”

She also pointed out that while this study evaluated the risk only for brain cancer, children who undergo head CTs are also at increased risk for leukemia.
 

Dose/response relationship

The study included 658,752 individuals from nine European countries and 276 hospitals. Each patient had received at least one CT scan between 1977 and 2014 before they turned 22 years of age. Eligibility requirements included their being alive at least 5 years after the first scan and that they had not previously been diagnosed with cancer or benign brain tumor.

The radiation dose absorbed to the brain and 33 other organs and tissues was estimated for each participant using a dose reconstruction model that included historical information on CT machine settings, questionnaire data, and Digital Imaging and Communication in Medicine header metadata. “Mean brain dose per head or neck CT examination increased from 1984 until about 1991, following the introduction of multislice CT scanners at which point thereafter the mean dose decreased and then stabilized around 2010,” note the authors.

During a median follow-up of 5.6 years (starting 5 years after the first scan), 165 brain cancers occurred, including 121 (73%) gliomas, as well as a variety of other morphologic changes.

The mean cumulative brain dose, which lagged by 5 years, was 47.4 mGy overall and 76.0 mGy among people with brain cancer.

“We observed a significant positive association between the cumulative number of head or neck CT examinations and the risk of all brain cancers combined (P < .0001), and of gliomas separately (P = .0002),” the team reports, adding that, for a brain dose of 38 mGy, which was the average dose per head or neck CT in 2012-2014, the relative risk of developing brain cancer was 1.5, compared with not undergoing a CT scan, and the excess absolute risk per 100,000 person-years was 1.1.

These findings “can be used to give the patients and their parents important information on the risks of CT examination to balance against the known benefits,” noted Nobuyuki Hamada, PhD, from the Central Research Institute of Electric Power Industry, Tokyo, and Lydia B. Zablotska, MD, PhD, from the University of California, San Francisco, writing in a linked commentary.

“In recent years, rates of CT use have been steady or declined, and various efforts (for instance, in terms of diagnostic reference levels) have been made to justify and optimize CT examinations. Such continued efforts, along with extended epidemiological investigations, would be needed to minimize the risk of brain cancer after pediatric CT examination,” they add.
 

Keeping dose to a minimum

The study’s finding of a dose-response relationship underscores the importance of keeping doses to a minimum, Dr. Bindman-Smith commented. “I do not believe we are doing this nearly enough,” she added.

“In the UCSF International CT Dose Registry, where we have collected CT scans from 165 hospitals on many millions of patients, we found that the average brain dose for a head CT in a 1-year-old is 42 mGy but that this dose varies tremendously, where some children receive a dose of 100 mGy.

“So, a second message is that not only should CT scans be justified and used judiciously, but also they should be optimized, meaning using the lowest dose possible. I personally think there should be regulatory oversight to ensure that patients receive the absolutely lowest doses possible,” she added. “My team at UCSF has written quality measures endorsed by the National Quality Forum as a start for setting explicit standards for how CT should be performed in order to ensure the cancer risks are as low as possible.”

The study was funded through the Belgian Cancer Registry; La Ligue contre le Cancer, L’Institut National du Cancer, France; the Ministry of Health, Labour and Welfare of Japan; the German Federal Ministry of Education and Research; Worldwide Cancer Research; the Dutch Cancer Society; the Research Council of Norway; Consejo de Seguridad Nuclear, Generalitat deCatalunya, Spain; the U.S. National Cancer Institute; the U.K. National Institute for Health Research; and Public Health England. Dr. Hauptmann has disclosed no relevant financial relationships. Other investigators’ relevant financial relationships are listed in the original article. Dr. Hamada and Dr. Zablotska disclosed no relevant financial relationships.

A version of this article first appeared on Medscape.com.

Children and young adults who are exposed to a single CT scan of the head or neck before age 22 years are at significantly increased risk of developing a brain tumor, particularly glioma, after at least 5 years, according to results of the large EPI-CT study.

“Translation of our risk estimates to the clinical setting indicates that per 10,000 children who received one head CT examination, about one radiation-induced brain cancer is expected during the 5-15 years following the CT examination,” noted lead author Michael Hauptmann, PhD, from the Institute of Biostatistics and Registry Research, Brandenburg Medical School, Neuruppin, Germany, and coauthors.

“Next to the clinical benefit of most CT scans, there is a small risk of cancer from the radiation exposure,” Dr. Hauptmann told this news organization.

“So, CT examinations should only be used when necessary, and if they are used, the lowest achievable dose should be applied,” he said.

The study was published online in The Lancet Oncology.

“This is a thoughtful and well-conducted study by an outstanding multinational team of scientists that adds further weight to the growing body of evidence that has found exposure to CT scanning increases a child’s risk of developing brain cancer,” commented Rebecca Bindman-Smith, MD, from the University of California, San Francisco, who was not involved in the research.

“The results are real, and important,” she told this news organization, adding that “the authors were conservative in their assumptions, and performed a very large number of sensitivity analyses ... to check that the results were robust to a large range of assumptions – and the results changed relatively little.”

“I do not think there is enough awareness [about this risk],” Dr. Hauptmann said. “There is evidence that a nonnegligible number of CTs is unjustified according to guidelines, and there is evidence that doses vary substantially for the same CT between institutions in the same or different countries.”

Indeed, particularly in the United States, “we perform many CT scans in children and even more so in adults that are simply unnecessary,” agreed Dr. Bindman-Smith, who is professor of epidemiology and biostatistics at the University of California, San Francisco. “It is important for patients and providers to understand that nothing we do in medicine is risk free, including CT scanning. If a CT is necessary, the benefit almost certainly outweighs the risk. But if [not], then it should not be obtained. Both patients and providers must make thoroughly considered decisions before asking for or agreeing to a CT.”

She also pointed out that while this study evaluated the risk only for brain cancer, children who undergo head CTs are also at increased risk for leukemia.
 

Dose/response relationship

The study included 658,752 individuals from nine European countries and 276 hospitals. Each patient had received at least one CT scan between 1977 and 2014 before they turned 22 years of age. Eligibility requirements included their being alive at least 5 years after the first scan and that they had not previously been diagnosed with cancer or benign brain tumor.

The radiation dose absorbed to the brain and 33 other organs and tissues was estimated for each participant using a dose reconstruction model that included historical information on CT machine settings, questionnaire data, and Digital Imaging and Communication in Medicine header metadata. “Mean brain dose per head or neck CT examination increased from 1984 until about 1991, following the introduction of multislice CT scanners at which point thereafter the mean dose decreased and then stabilized around 2010,” note the authors.

During a median follow-up of 5.6 years (starting 5 years after the first scan), 165 brain cancers occurred, including 121 (73%) gliomas, as well as a variety of other morphologic changes.

The mean cumulative brain dose, which lagged by 5 years, was 47.4 mGy overall and 76.0 mGy among people with brain cancer.

“We observed a significant positive association between the cumulative number of head or neck CT examinations and the risk of all brain cancers combined (P < .0001), and of gliomas separately (P = .0002),” the team reports, adding that, for a brain dose of 38 mGy, which was the average dose per head or neck CT in 2012-2014, the relative risk of developing brain cancer was 1.5, compared with not undergoing a CT scan, and the excess absolute risk per 100,000 person-years was 1.1.

These findings “can be used to give the patients and their parents important information on the risks of CT examination to balance against the known benefits,” noted Nobuyuki Hamada, PhD, from the Central Research Institute of Electric Power Industry, Tokyo, and Lydia B. Zablotska, MD, PhD, from the University of California, San Francisco, writing in a linked commentary.

“In recent years, rates of CT use have been steady or declined, and various efforts (for instance, in terms of diagnostic reference levels) have been made to justify and optimize CT examinations. Such continued efforts, along with extended epidemiological investigations, would be needed to minimize the risk of brain cancer after pediatric CT examination,” they add.
 

Keeping dose to a minimum

The study’s finding of a dose-response relationship underscores the importance of keeping doses to a minimum, Dr. Bindman-Smith commented. “I do not believe we are doing this nearly enough,” she added.

“In the UCSF International CT Dose Registry, where we have collected CT scans from 165 hospitals on many millions of patients, we found that the average brain dose for a head CT in a 1-year-old is 42 mGy but that this dose varies tremendously, where some children receive a dose of 100 mGy.

“So, a second message is that not only should CT scans be justified and used judiciously, but also they should be optimized, meaning using the lowest dose possible. I personally think there should be regulatory oversight to ensure that patients receive the absolutely lowest doses possible,” she added. “My team at UCSF has written quality measures endorsed by the National Quality Forum as a start for setting explicit standards for how CT should be performed in order to ensure the cancer risks are as low as possible.”

The study was funded through the Belgian Cancer Registry; La Ligue contre le Cancer, L’Institut National du Cancer, France; the Ministry of Health, Labour and Welfare of Japan; the German Federal Ministry of Education and Research; Worldwide Cancer Research; the Dutch Cancer Society; the Research Council of Norway; Consejo de Seguridad Nuclear, Generalitat deCatalunya, Spain; the U.S. National Cancer Institute; the U.K. National Institute for Health Research; and Public Health England. Dr. Hauptmann has disclosed no relevant financial relationships. Other investigators’ relevant financial relationships are listed in the original article. Dr. Hamada and Dr. Zablotska disclosed no relevant financial relationships.

A version of this article first appeared on Medscape.com.

Children and young adults who are exposed to a single CT scan of the head or neck before age 22 years are at significantly increased risk of developing a brain tumor, particularly glioma, after at least 5 years, according to results of the large EPI-CT study.

“Translation of our risk estimates to the clinical setting indicates that per 10,000 children who received one head CT examination, about one radiation-induced brain cancer is expected during the 5-15 years following the CT examination,” noted lead author Michael Hauptmann, PhD, from the Institute of Biostatistics and Registry Research, Brandenburg Medical School, Neuruppin, Germany, and coauthors.

“Next to the clinical benefit of most CT scans, there is a small risk of cancer from the radiation exposure,” Dr. Hauptmann told this news organization.

“So, CT examinations should only be used when necessary, and if they are used, the lowest achievable dose should be applied,” he said.

The study was published online in The Lancet Oncology.

“This is a thoughtful and well-conducted study by an outstanding multinational team of scientists that adds further weight to the growing body of evidence that has found exposure to CT scanning increases a child’s risk of developing brain cancer,” commented Rebecca Bindman-Smith, MD, from the University of California, San Francisco, who was not involved in the research.

“The results are real, and important,” she told this news organization, adding that “the authors were conservative in their assumptions, and performed a very large number of sensitivity analyses ... to check that the results were robust to a large range of assumptions – and the results changed relatively little.”

“I do not think there is enough awareness [about this risk],” Dr. Hauptmann said. “There is evidence that a nonnegligible number of CTs is unjustified according to guidelines, and there is evidence that doses vary substantially for the same CT between institutions in the same or different countries.”

Indeed, particularly in the United States, “we perform many CT scans in children and even more so in adults that are simply unnecessary,” agreed Dr. Bindman-Smith, who is professor of epidemiology and biostatistics at the University of California, San Francisco. “It is important for patients and providers to understand that nothing we do in medicine is risk free, including CT scanning. If a CT is necessary, the benefit almost certainly outweighs the risk. But if [not], then it should not be obtained. Both patients and providers must make thoroughly considered decisions before asking for or agreeing to a CT.”

She also pointed out that while this study evaluated the risk only for brain cancer, children who undergo head CTs are also at increased risk for leukemia.
 

Dose/response relationship

The study included 658,752 individuals from nine European countries and 276 hospitals. Each patient had received at least one CT scan between 1977 and 2014 before they turned 22 years of age. Eligibility requirements included their being alive at least 5 years after the first scan and that they had not previously been diagnosed with cancer or benign brain tumor.

The radiation dose absorbed to the brain and 33 other organs and tissues was estimated for each participant using a dose reconstruction model that included historical information on CT machine settings, questionnaire data, and Digital Imaging and Communication in Medicine header metadata. “Mean brain dose per head or neck CT examination increased from 1984 until about 1991, following the introduction of multislice CT scanners at which point thereafter the mean dose decreased and then stabilized around 2010,” note the authors.

During a median follow-up of 5.6 years (starting 5 years after the first scan), 165 brain cancers occurred, including 121 (73%) gliomas, as well as a variety of other morphologic changes.

The mean cumulative brain dose, which lagged by 5 years, was 47.4 mGy overall and 76.0 mGy among people with brain cancer.

“We observed a significant positive association between the cumulative number of head or neck CT examinations and the risk of all brain cancers combined (P < .0001), and of gliomas separately (P = .0002),” the team reports, adding that, for a brain dose of 38 mGy, which was the average dose per head or neck CT in 2012-2014, the relative risk of developing brain cancer was 1.5, compared with not undergoing a CT scan, and the excess absolute risk per 100,000 person-years was 1.1.

These findings “can be used to give the patients and their parents important information on the risks of CT examination to balance against the known benefits,” noted Nobuyuki Hamada, PhD, from the Central Research Institute of Electric Power Industry, Tokyo, and Lydia B. Zablotska, MD, PhD, from the University of California, San Francisco, writing in a linked commentary.

“In recent years, rates of CT use have been steady or declined, and various efforts (for instance, in terms of diagnostic reference levels) have been made to justify and optimize CT examinations. Such continued efforts, along with extended epidemiological investigations, would be needed to minimize the risk of brain cancer after pediatric CT examination,” they add.
 

Keeping dose to a minimum

The study’s finding of a dose-response relationship underscores the importance of keeping doses to a minimum, Dr. Bindman-Smith commented. “I do not believe we are doing this nearly enough,” she added.

“In the UCSF International CT Dose Registry, where we have collected CT scans from 165 hospitals on many millions of patients, we found that the average brain dose for a head CT in a 1-year-old is 42 mGy but that this dose varies tremendously, where some children receive a dose of 100 mGy.

“So, a second message is that not only should CT scans be justified and used judiciously, but also they should be optimized, meaning using the lowest dose possible. I personally think there should be regulatory oversight to ensure that patients receive the absolutely lowest doses possible,” she added. “My team at UCSF has written quality measures endorsed by the National Quality Forum as a start for setting explicit standards for how CT should be performed in order to ensure the cancer risks are as low as possible.”

The study was funded through the Belgian Cancer Registry; La Ligue contre le Cancer, L’Institut National du Cancer, France; the Ministry of Health, Labour and Welfare of Japan; the German Federal Ministry of Education and Research; Worldwide Cancer Research; the Dutch Cancer Society; the Research Council of Norway; Consejo de Seguridad Nuclear, Generalitat deCatalunya, Spain; the U.S. National Cancer Institute; the U.K. National Institute for Health Research; and Public Health England. Dr. Hauptmann has disclosed no relevant financial relationships. Other investigators’ relevant financial relationships are listed in the original article. Dr. Hamada and Dr. Zablotska disclosed no relevant financial relationships.

A version of this article first appeared on Medscape.com.

The offspring of mothers who sustain unintentional injuries during pregnancy appear to have a modest 33% increased risk of developing cerebral palsy (CP) – higher when injuries are more severe, multiple, or lead to delivery soon afterward, a Canadian birth cohort study found.

Such children may benefit from long-term monitoring for neurodevelpmental issues, wrote a group led by Asma Ahmed, MD, PhD, MPH, a pediatric epidemiologist at the Hospital for Sick Children Research Institute in Toronto in JAMA Pediatrics.

“We need to provide better support for babies whose mothers have been injured in pregnancy, especially after severe injuries,” Dr. Ahmed said in a press release. “As well, these findings suggest the need for early monitoring of babies’ development, regular check-ups, and longer-term neurodevelopmental assessments.” Future studies should directly measure injury severity and its possible link to CP.

Current guidelines, however, focus on monitoring fetal condition immediately after injury with little attention to its long-term effects.

In their findings from the population-based linkage study of 2,110,177 children born in Ontario’s public health system during 2002-2017 and followed to 2018 with a median follow-up of 8 years:

• A total of 81,281 fetuses were exposed in utero to unintentional maternal injury.
• Overall, 0.3% children were diagnosed with CP, and the mean CP incidence rates were 4.36 per 10,000 child-years for the exposed versus 2.93 for the unexposed.
• In those exposed, the hazard ratio was 1.33 (95% confidence interval, 1.18-1.50) after adjusting for maternal sociodemographic and clinical characteristics.
• Injuries resulting in hospitalization or delivery within 1 week were linked to higher adjusted hazard ratios of 2.18 (95% CI, 1.29-3.68) and 3.40 (95% CI, 1.93-6.00), respectively.
• Injuries most frequently resulted from transportation mishaps, falls, and being struck by a person or object. They were most commonly associated with age younger than 20 years, substance use disorder, residence in rural and under-resourced areas, and lower socioeconomic status.

The authors noted that complications after maternal injuries – which affect 6%-8% of pregnant women – include uterine rupture, preterm delivery, and placental abruption and are linked to fetal complications such as asphyxia. The association with an offspring’s neurodevelopment has been rarely investigated. One U.K. population study, however, suggested a link between vehicular crashes and higher CP risk in preterm infants.

A related editorial on the study noted that while CP affects about two to four children per 1,000 live births each year in high-income countries, the etiological causes of most cases remain unknown. “This large population-based cohort study ... should inspire more research into preventing and mitigating factors for maternal injuries and offspring CP development,” wrote Zeyan Liew, PhD, MPH, and Haoran Zhuo, MPH, of Yale University School of Public Health in New Haven, Conn.

This study was supported by Santé-Québec and ICES, a research institute funded by the Ontario Ministry of Health and the Ministry of Long-Term Care.

Dr. Ahmed and coauthor Seungmi Yang, PhD, reported research funding from Santé-Québec during the conduct of the study.

The offspring of mothers who sustain unintentional injuries during pregnancy appear to have a modest 33% increased risk of developing cerebral palsy (CP) – higher when injuries are more severe, multiple, or lead to delivery soon afterward, a Canadian birth cohort study found.

Such children may benefit from long-term monitoring for neurodevelpmental issues, wrote a group led by Asma Ahmed, MD, PhD, MPH, a pediatric epidemiologist at the Hospital for Sick Children Research Institute in Toronto in JAMA Pediatrics.

“We need to provide better support for babies whose mothers have been injured in pregnancy, especially after severe injuries,” Dr. Ahmed said in a press release. “As well, these findings suggest the need for early monitoring of babies’ development, regular check-ups, and longer-term neurodevelopmental assessments.” Future studies should directly measure injury severity and its possible link to CP.

Current guidelines, however, focus on monitoring fetal condition immediately after injury with little attention to its long-term effects.

In their findings from the population-based linkage study of 2,110,177 children born in Ontario’s public health system during 2002-2017 and followed to 2018 with a median follow-up of 8 years:

• A total of 81,281 fetuses were exposed in utero to unintentional maternal injury.
• Overall, 0.3% children were diagnosed with CP, and the mean CP incidence rates were 4.36 per 10,000 child-years for the exposed versus 2.93 for the unexposed.
• In those exposed, the hazard ratio was 1.33 (95% confidence interval, 1.18-1.50) after adjusting for maternal sociodemographic and clinical characteristics.
• Injuries resulting in hospitalization or delivery within 1 week were linked to higher adjusted hazard ratios of 2.18 (95% CI, 1.29-3.68) and 3.40 (95% CI, 1.93-6.00), respectively.
• Injuries most frequently resulted from transportation mishaps, falls, and being struck by a person or object. They were most commonly associated with age younger than 20 years, substance use disorder, residence in rural and under-resourced areas, and lower socioeconomic status.

The authors noted that complications after maternal injuries – which affect 6%-8% of pregnant women – include uterine rupture, preterm delivery, and placental abruption and are linked to fetal complications such as asphyxia. The association with an offspring’s neurodevelopment has been rarely investigated. One U.K. population study, however, suggested a link between vehicular crashes and higher CP risk in preterm infants.

A related editorial on the study noted that while CP affects about two to four children per 1,000 live births each year in high-income countries, the etiological causes of most cases remain unknown. “This large population-based cohort study ... should inspire more research into preventing and mitigating factors for maternal injuries and offspring CP development,” wrote Zeyan Liew, PhD, MPH, and Haoran Zhuo, MPH, of Yale University School of Public Health in New Haven, Conn.

This study was supported by Santé-Québec and ICES, a research institute funded by the Ontario Ministry of Health and the Ministry of Long-Term Care.

Dr. Ahmed and coauthor Seungmi Yang, PhD, reported research funding from Santé-Québec during the conduct of the study.

The offspring of mothers who sustain unintentional injuries during pregnancy appear to have a modest 33% increased risk of developing cerebral palsy (CP) – higher when injuries are more severe, multiple, or lead to delivery soon afterward, a Canadian birth cohort study found.

Such children may benefit from long-term monitoring for neurodevelpmental issues, wrote a group led by Asma Ahmed, MD, PhD, MPH, a pediatric epidemiologist at the Hospital for Sick Children Research Institute in Toronto in JAMA Pediatrics.

“We need to provide better support for babies whose mothers have been injured in pregnancy, especially after severe injuries,” Dr. Ahmed said in a press release. “As well, these findings suggest the need for early monitoring of babies’ development, regular check-ups, and longer-term neurodevelopmental assessments.” Future studies should directly measure injury severity and its possible link to CP.

Current guidelines, however, focus on monitoring fetal condition immediately after injury with little attention to its long-term effects.

In their findings from the population-based linkage study of 2,110,177 children born in Ontario’s public health system during 2002-2017 and followed to 2018 with a median follow-up of 8 years:

• A total of 81,281 fetuses were exposed in utero to unintentional maternal injury.
• Overall, 0.3% children were diagnosed with CP, and the mean CP incidence rates were 4.36 per 10,000 child-years for the exposed versus 2.93 for the unexposed.
• In those exposed, the hazard ratio was 1.33 (95% confidence interval, 1.18-1.50) after adjusting for maternal sociodemographic and clinical characteristics.
• Injuries resulting in hospitalization or delivery within 1 week were linked to higher adjusted hazard ratios of 2.18 (95% CI, 1.29-3.68) and 3.40 (95% CI, 1.93-6.00), respectively.
• Injuries most frequently resulted from transportation mishaps, falls, and being struck by a person or object. They were most commonly associated with age younger than 20 years, substance use disorder, residence in rural and under-resourced areas, and lower socioeconomic status.

The authors noted that complications after maternal injuries – which affect 6%-8% of pregnant women – include uterine rupture, preterm delivery, and placental abruption and are linked to fetal complications such as asphyxia. The association with an offspring’s neurodevelopment has been rarely investigated. One U.K. population study, however, suggested a link between vehicular crashes and higher CP risk in preterm infants.

A related editorial on the study noted that while CP affects about two to four children per 1,000 live births each year in high-income countries, the etiological causes of most cases remain unknown. “This large population-based cohort study ... should inspire more research into preventing and mitigating factors for maternal injuries and offspring CP development,” wrote Zeyan Liew, PhD, MPH, and Haoran Zhuo, MPH, of Yale University School of Public Health in New Haven, Conn.

This study was supported by Santé-Québec and ICES, a research institute funded by the Ontario Ministry of Health and the Ministry of Long-Term Care.

Dr. Ahmed and coauthor Seungmi Yang, PhD, reported research funding from Santé-Québec during the conduct of the study.