Head & Neck/Thyroid Cancers

Earlier this week, Medscape spoke with Nora Disis, MD, about vaccinating cancer patients. Disis is a medical oncologist and director of both the Institute of Translational Health Sciences and the Cancer Vaccine Institute, the University of Washington, Seattle, Washington. As editor-in-chief of JAMA Oncology, she has watched COVID-19 developments in the oncology community over the past year.

Here are a few themes that Disis said oncologists should be aware of as vaccines eventually begin reaching cancer patients.

We should expect cancer patients to respond to vaccines. Historically, some believed that cancer patients would be unable to mount an immune response to vaccines. Data on other viral vaccines have shown otherwise. For example, there has been a long history of studies of flu vaccination in cancer patients, and in general, those vaccines confer protection. Likewise for pneumococcal vaccine, which, generally speaking, cancer patients should receive.

Special cases may include hematologic malignancies in which the immune system has been destroyed and profound immunosuppression occurs. Data on immunization during this immunosuppressed period are scarce, but what data are available suggest that once cancer patients are through this immunosuppressed period, they can be vaccinated successfully.

The type of vaccine will probably be important for cancer patients. Currently, there are 61 coronavirus vaccines in human clinical trials, and 17 have reached the final stages of testing. At least 85 preclinical vaccines are under active investigation in animals.

Both the Pfizer-BioNTech and Moderna COVID vaccines are mRNA type. There are many other types, including protein-based vaccines, viral vector vaccines based on adenoviruses, and inactivated or attenuated coronavirus vaccines.

The latter vaccines, particularly attenuated live virus vaccines, may not be a good choice for cancer patients. Especially in those with rapidly progressing disease or on chemotherapy, attenuated live viruses may cause a low-grade infection.

Incidentally, the technology used in the genetic, or mRNA, vaccines developed by both Pfizer-BioNTech and Moderna was initially developed for fighting cancer, and studies have shown that patients can generate immune responses to cancer-associated proteins with this type of vaccine.

These genetic vaccines could turn out to be the most effective for cancer patients, especially those with solid tumors.

Our understanding is very limited right now. Neither the Pfizer-BioNTech nor the Moderna early data discuss cancer patients. Two of the most important questions for cancer patients are dosing and booster scheduling. Potential defects in lymphocyte function among cancer patients may require unique initial dosing and booster schedules. In terms of timing, it is unclear how active therapy might affect a patient’s immune response to vaccination and whether vaccines should be timed with therapy cycles.

Vaccine access may depend on whether cancer patients are viewed as a vulnerable population. Those at higher risk for severe COVID-19 clearly have a greater need for vaccination. While there are data suggesting that cancer patients are at higher risk, they are a bit murky, in part because cancer patients are a heterogeneous group. For example, there are data suggesting that lung and blood cancer patients fare worse. There is also a suggestion that, like in the general population, COVID risk in cancer patients remains driven by comorbidities.

It is likely, then, that personalized risk factors such as type of cancer therapy, site of disease, and comorbidities will shape individual choices about vaccination among cancer patients.

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

Earlier this week, Medscape spoke with Nora Disis, MD, about vaccinating cancer patients. Disis is a medical oncologist and director of both the Institute of Translational Health Sciences and the Cancer Vaccine Institute, the University of Washington, Seattle, Washington. As editor-in-chief of JAMA Oncology, she has watched COVID-19 developments in the oncology community over the past year.

Here are a few themes that Disis said oncologists should be aware of as vaccines eventually begin reaching cancer patients.

We should expect cancer patients to respond to vaccines. Historically, some believed that cancer patients would be unable to mount an immune response to vaccines. Data on other viral vaccines have shown otherwise. For example, there has been a long history of studies of flu vaccination in cancer patients, and in general, those vaccines confer protection. Likewise for pneumococcal vaccine, which, generally speaking, cancer patients should receive.

Special cases may include hematologic malignancies in which the immune system has been destroyed and profound immunosuppression occurs. Data on immunization during this immunosuppressed period are scarce, but what data are available suggest that once cancer patients are through this immunosuppressed period, they can be vaccinated successfully.

The type of vaccine will probably be important for cancer patients. Currently, there are 61 coronavirus vaccines in human clinical trials, and 17 have reached the final stages of testing. At least 85 preclinical vaccines are under active investigation in animals.

Both the Pfizer-BioNTech and Moderna COVID vaccines are mRNA type. There are many other types, including protein-based vaccines, viral vector vaccines based on adenoviruses, and inactivated or attenuated coronavirus vaccines.

The latter vaccines, particularly attenuated live virus vaccines, may not be a good choice for cancer patients. Especially in those with rapidly progressing disease or on chemotherapy, attenuated live viruses may cause a low-grade infection.

Incidentally, the technology used in the genetic, or mRNA, vaccines developed by both Pfizer-BioNTech and Moderna was initially developed for fighting cancer, and studies have shown that patients can generate immune responses to cancer-associated proteins with this type of vaccine.

These genetic vaccines could turn out to be the most effective for cancer patients, especially those with solid tumors.

Our understanding is very limited right now. Neither the Pfizer-BioNTech nor the Moderna early data discuss cancer patients. Two of the most important questions for cancer patients are dosing and booster scheduling. Potential defects in lymphocyte function among cancer patients may require unique initial dosing and booster schedules. In terms of timing, it is unclear how active therapy might affect a patient’s immune response to vaccination and whether vaccines should be timed with therapy cycles.

Vaccine access may depend on whether cancer patients are viewed as a vulnerable population. Those at higher risk for severe COVID-19 clearly have a greater need for vaccination. While there are data suggesting that cancer patients are at higher risk, they are a bit murky, in part because cancer patients are a heterogeneous group. For example, there are data suggesting that lung and blood cancer patients fare worse. There is also a suggestion that, like in the general population, COVID risk in cancer patients remains driven by comorbidities.

It is likely, then, that personalized risk factors such as type of cancer therapy, site of disease, and comorbidities will shape individual choices about vaccination among cancer patients.

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

Earlier this week, Medscape spoke with Nora Disis, MD, about vaccinating cancer patients. Disis is a medical oncologist and director of both the Institute of Translational Health Sciences and the Cancer Vaccine Institute, the University of Washington, Seattle, Washington. As editor-in-chief of JAMA Oncology, she has watched COVID-19 developments in the oncology community over the past year.

Here are a few themes that Disis said oncologists should be aware of as vaccines eventually begin reaching cancer patients.

We should expect cancer patients to respond to vaccines. Historically, some believed that cancer patients would be unable to mount an immune response to vaccines. Data on other viral vaccines have shown otherwise. For example, there has been a long history of studies of flu vaccination in cancer patients, and in general, those vaccines confer protection. Likewise for pneumococcal vaccine, which, generally speaking, cancer patients should receive.

Special cases may include hematologic malignancies in which the immune system has been destroyed and profound immunosuppression occurs. Data on immunization during this immunosuppressed period are scarce, but what data are available suggest that once cancer patients are through this immunosuppressed period, they can be vaccinated successfully.

The type of vaccine will probably be important for cancer patients. Currently, there are 61 coronavirus vaccines in human clinical trials, and 17 have reached the final stages of testing. At least 85 preclinical vaccines are under active investigation in animals.

Both the Pfizer-BioNTech and Moderna COVID vaccines are mRNA type. There are many other types, including protein-based vaccines, viral vector vaccines based on adenoviruses, and inactivated or attenuated coronavirus vaccines.

The latter vaccines, particularly attenuated live virus vaccines, may not be a good choice for cancer patients. Especially in those with rapidly progressing disease or on chemotherapy, attenuated live viruses may cause a low-grade infection.

Incidentally, the technology used in the genetic, or mRNA, vaccines developed by both Pfizer-BioNTech and Moderna was initially developed for fighting cancer, and studies have shown that patients can generate immune responses to cancer-associated proteins with this type of vaccine.

These genetic vaccines could turn out to be the most effective for cancer patients, especially those with solid tumors.

Our understanding is very limited right now. Neither the Pfizer-BioNTech nor the Moderna early data discuss cancer patients. Two of the most important questions for cancer patients are dosing and booster scheduling. Potential defects in lymphocyte function among cancer patients may require unique initial dosing and booster schedules. In terms of timing, it is unclear how active therapy might affect a patient’s immune response to vaccination and whether vaccines should be timed with therapy cycles.

Vaccine access may depend on whether cancer patients are viewed as a vulnerable population. Those at higher risk for severe COVID-19 clearly have a greater need for vaccination. While there are data suggesting that cancer patients are at higher risk, they are a bit murky, in part because cancer patients are a heterogeneous group. For example, there are data suggesting that lung and blood cancer patients fare worse. There is also a suggestion that, like in the general population, COVID risk in cancer patients remains driven by comorbidities.

It is likely, then, that personalized risk factors such as type of cancer therapy, site of disease, and comorbidities will shape individual choices about vaccination among cancer patients.

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

A simple blood test, claimed to detect more than 50 types of cancer, will be used in a pilot trial by National Health Service England in a bid to increase rates of early-stage diagnosis, in particular for cancers that are currently difficult to diagnose.

“Early detection, particularly for hard-to-treat conditions like ovarian and pancreatic cancer, has the potential to save many lives,” said NHS Chief Executive Sir Simon Stevens in a statement.

The pilot trial will use the Galleri blood test, developed by Grail. Sir Stevens described the blood test as “promising” and said it could “be a game changer in cancer care, helping thousands more people to get successful treatment.”

However, some clinicians have expressed concerns over the potential for false-positive results with the test.

Results of a study of the Galleri blood test, published earlier this year, showed that the test detected 50 types of cancer with a specificity of 99.3% and a false positive rate of 0.7%.

It also correctly identified the originating tissue in 90% of cases. However, the sensitivity was lower, at 67%, for the 12 most common cancers, as reported at the time.

The senior author of that study, Michael Seiden, MD, PhD, president of the U.S. Oncology Network, The Woodlands, Tex., noted that it was not a screening study: the test had been used in patients with cancer and in healthy volunteers. He said the test “is intended to be complementary to, and not replace, existing guideline-recommended screening tests and might provide new avenues of investigation for cancers that don’t currently have screening tests.”

The Galleri test uses next-generation sequencing to analyze the arrangement of methyl groups on circulating cell-free DNA in a blood sample.

Several other blood tests for cancer are under development, including the CancerSEEK test, which has been reported to be able to identify eight common cancers. It measures circulating tumor DNA from 16 genes and eight protein biomarkers and then uses machine learning to analyze the data.
 

Improving early detection rates

The pilot trial of the blood test is due to start in mid-2021 and will involve 165,000 people.

The trial will include 140,000 individuals aged 50-79 years who were identified through their health records and who have no cancer symptoms. They will undergo blood tests annually for 3 years and will be referred for investigation if a test result is positive.

A second group will include 25,000 people with potential cancer symptoms. These patients will be offered the blood test to speed up their diagnosis after referral to a hospital via the normal channels.

The results of the pilot are expected in 2023. If successful, the test will be rolled out to 1 million individuals from 2024 to 2025.

The pilot trial is part of the NHS Long Term Plan, which aims to increase early detection of cancer. At present, around half of cancers in England are diagnosed in stage I or II; the NHS aims to increase this to 75% by 2028.

“The NHS has set itself an ambitious target,” commented Peter Johnson, MD, PhD, national clinical director for cancer at NHS England and Improvement.

“Tests like this may help us get there far faster, and I am excited to see how this cutting-edge technology will work out as we test it in clinics across the NHS,” he added.

Lord David Prior, chair of NHS England, noted that almost 200,000 people die from cancer in the United Kingdom every year and that “many of these people are diagnosed too late for treatment to be effective.

“This collaboration between the NHS and Grail offers the chance for a wide range of cancers to be diagnosed much earlier and could fundamentally change the outlook for people with cancer,” he said.

However, some clinicians raised potential concerns.

Stephen Duffy, PhD, Center for Cancer Prevention, Queen Mary University of London, described the pilot as “very exciting,” but cautioned: “We will need to find out just how early the test detects cancers and whether it can it be used in a way which minimizes anxiety from false positives.”

Yong-Jie Lu, MD, PhD, also at Queen Mary University of London, said: “It is not clear how early it aims to catch cancer. For a cancer screen test, it needs very high specificity (>99%), otherwise it may end up in a similar situation as the PSA [prostate-specific antigen] test for prostate cancer, or even worse.”

Mangesh Thorat, MD, Cancer Prevention Trials Unit, King’s College London, warned: “It is likely that for every testing round ... there will be about 1,000 false-positive results, and the test may not be able to pinpoint the location of cancer in 3%-4% of those with a true positive result, necessitating a range of imaging and other investigations in these participants.”

No funding for the study has been declared. The investigators have disclosed no relevant financial relationships.

This article first appeared on Medscape.com.

A simple blood test, claimed to detect more than 50 types of cancer, will be used in a pilot trial by National Health Service England in a bid to increase rates of early-stage diagnosis, in particular for cancers that are currently difficult to diagnose.

“Early detection, particularly for hard-to-treat conditions like ovarian and pancreatic cancer, has the potential to save many lives,” said NHS Chief Executive Sir Simon Stevens in a statement.

The pilot trial will use the Galleri blood test, developed by Grail. Sir Stevens described the blood test as “promising” and said it could “be a game changer in cancer care, helping thousands more people to get successful treatment.”

However, some clinicians have expressed concerns over the potential for false-positive results with the test.

Results of a study of the Galleri blood test, published earlier this year, showed that the test detected 50 types of cancer with a specificity of 99.3% and a false positive rate of 0.7%.

It also correctly identified the originating tissue in 90% of cases. However, the sensitivity was lower, at 67%, for the 12 most common cancers, as reported at the time.

The senior author of that study, Michael Seiden, MD, PhD, president of the U.S. Oncology Network, The Woodlands, Tex., noted that it was not a screening study: the test had been used in patients with cancer and in healthy volunteers. He said the test “is intended to be complementary to, and not replace, existing guideline-recommended screening tests and might provide new avenues of investigation for cancers that don’t currently have screening tests.”

The Galleri test uses next-generation sequencing to analyze the arrangement of methyl groups on circulating cell-free DNA in a blood sample.

Several other blood tests for cancer are under development, including the CancerSEEK test, which has been reported to be able to identify eight common cancers. It measures circulating tumor DNA from 16 genes and eight protein biomarkers and then uses machine learning to analyze the data.
 

Improving early detection rates

The pilot trial of the blood test is due to start in mid-2021 and will involve 165,000 people.

The trial will include 140,000 individuals aged 50-79 years who were identified through their health records and who have no cancer symptoms. They will undergo blood tests annually for 3 years and will be referred for investigation if a test result is positive.

A second group will include 25,000 people with potential cancer symptoms. These patients will be offered the blood test to speed up their diagnosis after referral to a hospital via the normal channels.

The results of the pilot are expected in 2023. If successful, the test will be rolled out to 1 million individuals from 2024 to 2025.

The pilot trial is part of the NHS Long Term Plan, which aims to increase early detection of cancer. At present, around half of cancers in England are diagnosed in stage I or II; the NHS aims to increase this to 75% by 2028.

“The NHS has set itself an ambitious target,” commented Peter Johnson, MD, PhD, national clinical director for cancer at NHS England and Improvement.

“Tests like this may help us get there far faster, and I am excited to see how this cutting-edge technology will work out as we test it in clinics across the NHS,” he added.

Lord David Prior, chair of NHS England, noted that almost 200,000 people die from cancer in the United Kingdom every year and that “many of these people are diagnosed too late for treatment to be effective.

“This collaboration between the NHS and Grail offers the chance for a wide range of cancers to be diagnosed much earlier and could fundamentally change the outlook for people with cancer,” he said.

However, some clinicians raised potential concerns.

Stephen Duffy, PhD, Center for Cancer Prevention, Queen Mary University of London, described the pilot as “very exciting,” but cautioned: “We will need to find out just how early the test detects cancers and whether it can it be used in a way which minimizes anxiety from false positives.”

Yong-Jie Lu, MD, PhD, also at Queen Mary University of London, said: “It is not clear how early it aims to catch cancer. For a cancer screen test, it needs very high specificity (>99%), otherwise it may end up in a similar situation as the PSA [prostate-specific antigen] test for prostate cancer, or even worse.”

Mangesh Thorat, MD, Cancer Prevention Trials Unit, King’s College London, warned: “It is likely that for every testing round ... there will be about 1,000 false-positive results, and the test may not be able to pinpoint the location of cancer in 3%-4% of those with a true positive result, necessitating a range of imaging and other investigations in these participants.”

No funding for the study has been declared. The investigators have disclosed no relevant financial relationships.

This article first appeared on Medscape.com.

A simple blood test, claimed to detect more than 50 types of cancer, will be used in a pilot trial by National Health Service England in a bid to increase rates of early-stage diagnosis, in particular for cancers that are currently difficult to diagnose.

“Early detection, particularly for hard-to-treat conditions like ovarian and pancreatic cancer, has the potential to save many lives,” said NHS Chief Executive Sir Simon Stevens in a statement.

The pilot trial will use the Galleri blood test, developed by Grail. Sir Stevens described the blood test as “promising” and said it could “be a game changer in cancer care, helping thousands more people to get successful treatment.”

However, some clinicians have expressed concerns over the potential for false-positive results with the test.

Results of a study of the Galleri blood test, published earlier this year, showed that the test detected 50 types of cancer with a specificity of 99.3% and a false positive rate of 0.7%.

It also correctly identified the originating tissue in 90% of cases. However, the sensitivity was lower, at 67%, for the 12 most common cancers, as reported at the time.

The senior author of that study, Michael Seiden, MD, PhD, president of the U.S. Oncology Network, The Woodlands, Tex., noted that it was not a screening study: the test had been used in patients with cancer and in healthy volunteers. He said the test “is intended to be complementary to, and not replace, existing guideline-recommended screening tests and might provide new avenues of investigation for cancers that don’t currently have screening tests.”

The Galleri test uses next-generation sequencing to analyze the arrangement of methyl groups on circulating cell-free DNA in a blood sample.

Several other blood tests for cancer are under development, including the CancerSEEK test, which has been reported to be able to identify eight common cancers. It measures circulating tumor DNA from 16 genes and eight protein biomarkers and then uses machine learning to analyze the data.
 

Improving early detection rates

The pilot trial of the blood test is due to start in mid-2021 and will involve 165,000 people.

The trial will include 140,000 individuals aged 50-79 years who were identified through their health records and who have no cancer symptoms. They will undergo blood tests annually for 3 years and will be referred for investigation if a test result is positive.

A second group will include 25,000 people with potential cancer symptoms. These patients will be offered the blood test to speed up their diagnosis after referral to a hospital via the normal channels.

The results of the pilot are expected in 2023. If successful, the test will be rolled out to 1 million individuals from 2024 to 2025.

The pilot trial is part of the NHS Long Term Plan, which aims to increase early detection of cancer. At present, around half of cancers in England are diagnosed in stage I or II; the NHS aims to increase this to 75% by 2028.

“The NHS has set itself an ambitious target,” commented Peter Johnson, MD, PhD, national clinical director for cancer at NHS England and Improvement.

“Tests like this may help us get there far faster, and I am excited to see how this cutting-edge technology will work out as we test it in clinics across the NHS,” he added.

Lord David Prior, chair of NHS England, noted that almost 200,000 people die from cancer in the United Kingdom every year and that “many of these people are diagnosed too late for treatment to be effective.

“This collaboration between the NHS and Grail offers the chance for a wide range of cancers to be diagnosed much earlier and could fundamentally change the outlook for people with cancer,” he said.

However, some clinicians raised potential concerns.

Stephen Duffy, PhD, Center for Cancer Prevention, Queen Mary University of London, described the pilot as “very exciting,” but cautioned: “We will need to find out just how early the test detects cancers and whether it can it be used in a way which minimizes anxiety from false positives.”

Yong-Jie Lu, MD, PhD, also at Queen Mary University of London, said: “It is not clear how early it aims to catch cancer. For a cancer screen test, it needs very high specificity (>99%), otherwise it may end up in a similar situation as the PSA [prostate-specific antigen] test for prostate cancer, or even worse.”

Mangesh Thorat, MD, Cancer Prevention Trials Unit, King’s College London, warned: “It is likely that for every testing round ... there will be about 1,000 false-positive results, and the test may not be able to pinpoint the location of cancer in 3%-4% of those with a true positive result, necessitating a range of imaging and other investigations in these participants.”

No funding for the study has been declared. The investigators have disclosed no relevant financial relationships.

This article first appeared on Medscape.com.

Rates of cancer increased by 30% from 1973 to 2015 in adolescents and young adults (AYAs) aged 15–39 years in the United States, according to a review of almost a half million cases in the National Institutes of Health’s Surveillance, Epidemiology, and End Results database.

There was an annual increase of 0.537 new cases per 100,000 people, from 57.2 cases per 100,000 in 1973 to 74.2 in 2015.

Kidney carcinoma led with the highest rate increase. There were also marked increases in thyroid and colorectal carcinoma, germ cell and trophoblastic neoplasms, and melanoma, among others.

The report was published online December 1 in JAMA Network Open.

“Clinicians should be on the lookout for these cancers in their adolescent and young adult patients,” said senior investigator Nicholas Zaorsky, MD, an assistant professor of radiation oncology and public health sciences at the Penn State Cancer Institute, Hershey, Pennsylvania.

“Now that there is a better understanding of the types of cancer that are prevalent and rising in this age group, prevention, screening, diagnosis and treatment protocols specifically targeted to this population should be developed,” he said in a press release.

The reasons for the increases are unclear, but environmental and dietary factors, increasing obesity, and changing screening practices are likely in play, the authors comment. In addition, “cancer screening and overdiagnosis are thought to account for much of the increasing rates of thyroid and kidney carcinoma, among others,” they add.

The American Cancer Society (ACS) recently found similar increases in thyroid, kidney, and colorectal cancer among AYAs, as well as an increase in uterine cancer.

It’s important to note, however, that “this phenomenon is largely driven by trends for thyroid cancer, which is thought to be a result of overdiagnosis,” said ACS surveillance researcher Kimberly Miller, MPH, when asked to comment on the new study.

“As such, it is extremely important to also consider trends in cancer mortality rates among this age group, which are declining overall but are increasing for colorectal and uterine cancers. The fact that both incidence and mortality rates are increasing for these two cancers suggests a true increase in disease burden and certainly requires further attention and research,” she said.

Historically, management of cancer in AYAs has fallen somewhere between pediatric and adult oncology, neither of which capture the distinct biological, social, and economic needs of AYAs. Research has also focused on childhood and adult cancers, leaving cancer in AYAs inadequately studied.

The new findings are “valuable to guide more targeted research and interventions specifically to AYAs,” Zaorsky and colleagues say in their report.

Among female patients ― 59.1% of the study population ― incidence increased for 15 cancers, including kidney carcinoma (annual percent change [APC], 3.632), thyroid carcinoma (APC, 3.456), and myeloma, mast cell, and miscellaneous lymphoreticular neoplasms not otherwise specified (APC, 2.805). Rates of five cancers declined, led by astrocytoma not otherwise specified (APC, –3.369) and carcinoma of the gonads (APC, –1.743).

Among male patients, incidence increased for 14 cancers, including kidney carcinoma (APC, 3.572), unspecified soft tissue sarcoma (APC 2.543), and thyroid carcinoma (APC, 2.273). Incidence fell for seven, led by astrocytoma not otherwise specified (APC, –3.759) and carcinoma of the trachea, bronchus, and lung (APC, –2.635).

Increased testicular cancer rates (APC, 1.246) could be related to greater prenatal exposure to estrogen and progesterone or through dairy consumption; increasing survival of premature infants; and greater exposure to cannabis, among other possibilities, the investigators say.

Increases in colorectal cancer might be related to fewer vegetables and more fat and processed meat in the diet; lack of exercise; and increasing obesity. Human papillomavirus infection has also been implicated.

Higher rates of melanoma could be related to tanning bed use.

Declines in some cancers could be related to greater use of oral contraceptives; laws reducing exposure to benzene and other chemicals; and fewer people smoking.

Although kidney carcinoma has increased at the greatest rate, it’s uncommon. Colorectal and thyroid carcinoma, melanoma, non-Hodgkin lymphoma, and germ cell and trophoblastic neoplasms of the gonads contribute more to the overall increase in cancers among AYAs, the investigators note.

Almost 80% of the patients were White; 10.3% were Black.

The study was funded by the National Center for Advancing Translational Sciences. The investigators have disclosed no relevant financial relationships.

This article first appeared on Medscape.com.

Rates of cancer increased by 30% from 1973 to 2015 in adolescents and young adults (AYAs) aged 15–39 years in the United States, according to a review of almost a half million cases in the National Institutes of Health’s Surveillance, Epidemiology, and End Results database.

There was an annual increase of 0.537 new cases per 100,000 people, from 57.2 cases per 100,000 in 1973 to 74.2 in 2015.

Kidney carcinoma led with the highest rate increase. There were also marked increases in thyroid and colorectal carcinoma, germ cell and trophoblastic neoplasms, and melanoma, among others.

The report was published online December 1 in JAMA Network Open.

“Clinicians should be on the lookout for these cancers in their adolescent and young adult patients,” said senior investigator Nicholas Zaorsky, MD, an assistant professor of radiation oncology and public health sciences at the Penn State Cancer Institute, Hershey, Pennsylvania.

“Now that there is a better understanding of the types of cancer that are prevalent and rising in this age group, prevention, screening, diagnosis and treatment protocols specifically targeted to this population should be developed,” he said in a press release.

The reasons for the increases are unclear, but environmental and dietary factors, increasing obesity, and changing screening practices are likely in play, the authors comment. In addition, “cancer screening and overdiagnosis are thought to account for much of the increasing rates of thyroid and kidney carcinoma, among others,” they add.

The American Cancer Society (ACS) recently found similar increases in thyroid, kidney, and colorectal cancer among AYAs, as well as an increase in uterine cancer.

It’s important to note, however, that “this phenomenon is largely driven by trends for thyroid cancer, which is thought to be a result of overdiagnosis,” said ACS surveillance researcher Kimberly Miller, MPH, when asked to comment on the new study.

“As such, it is extremely important to also consider trends in cancer mortality rates among this age group, which are declining overall but are increasing for colorectal and uterine cancers. The fact that both incidence and mortality rates are increasing for these two cancers suggests a true increase in disease burden and certainly requires further attention and research,” she said.

Historically, management of cancer in AYAs has fallen somewhere between pediatric and adult oncology, neither of which capture the distinct biological, social, and economic needs of AYAs. Research has also focused on childhood and adult cancers, leaving cancer in AYAs inadequately studied.

The new findings are “valuable to guide more targeted research and interventions specifically to AYAs,” Zaorsky and colleagues say in their report.

Among female patients ― 59.1% of the study population ― incidence increased for 15 cancers, including kidney carcinoma (annual percent change [APC], 3.632), thyroid carcinoma (APC, 3.456), and myeloma, mast cell, and miscellaneous lymphoreticular neoplasms not otherwise specified (APC, 2.805). Rates of five cancers declined, led by astrocytoma not otherwise specified (APC, –3.369) and carcinoma of the gonads (APC, –1.743).

Among male patients, incidence increased for 14 cancers, including kidney carcinoma (APC, 3.572), unspecified soft tissue sarcoma (APC 2.543), and thyroid carcinoma (APC, 2.273). Incidence fell for seven, led by astrocytoma not otherwise specified (APC, –3.759) and carcinoma of the trachea, bronchus, and lung (APC, –2.635).

Increased testicular cancer rates (APC, 1.246) could be related to greater prenatal exposure to estrogen and progesterone or through dairy consumption; increasing survival of premature infants; and greater exposure to cannabis, among other possibilities, the investigators say.

Increases in colorectal cancer might be related to fewer vegetables and more fat and processed meat in the diet; lack of exercise; and increasing obesity. Human papillomavirus infection has also been implicated.

Higher rates of melanoma could be related to tanning bed use.

Declines in some cancers could be related to greater use of oral contraceptives; laws reducing exposure to benzene and other chemicals; and fewer people smoking.

Although kidney carcinoma has increased at the greatest rate, it’s uncommon. Colorectal and thyroid carcinoma, melanoma, non-Hodgkin lymphoma, and germ cell and trophoblastic neoplasms of the gonads contribute more to the overall increase in cancers among AYAs, the investigators note.

Almost 80% of the patients were White; 10.3% were Black.

The study was funded by the National Center for Advancing Translational Sciences. The investigators have disclosed no relevant financial relationships.

This article first appeared on Medscape.com.

Rates of cancer increased by 30% from 1973 to 2015 in adolescents and young adults (AYAs) aged 15–39 years in the United States, according to a review of almost a half million cases in the National Institutes of Health’s Surveillance, Epidemiology, and End Results database.

There was an annual increase of 0.537 new cases per 100,000 people, from 57.2 cases per 100,000 in 1973 to 74.2 in 2015.

Kidney carcinoma led with the highest rate increase. There were also marked increases in thyroid and colorectal carcinoma, germ cell and trophoblastic neoplasms, and melanoma, among others.

The report was published online December 1 in JAMA Network Open.

“Clinicians should be on the lookout for these cancers in their adolescent and young adult patients,” said senior investigator Nicholas Zaorsky, MD, an assistant professor of radiation oncology and public health sciences at the Penn State Cancer Institute, Hershey, Pennsylvania.

“Now that there is a better understanding of the types of cancer that are prevalent and rising in this age group, prevention, screening, diagnosis and treatment protocols specifically targeted to this population should be developed,” he said in a press release.

The reasons for the increases are unclear, but environmental and dietary factors, increasing obesity, and changing screening practices are likely in play, the authors comment. In addition, “cancer screening and overdiagnosis are thought to account for much of the increasing rates of thyroid and kidney carcinoma, among others,” they add.

The American Cancer Society (ACS) recently found similar increases in thyroid, kidney, and colorectal cancer among AYAs, as well as an increase in uterine cancer.

It’s important to note, however, that “this phenomenon is largely driven by trends for thyroid cancer, which is thought to be a result of overdiagnosis,” said ACS surveillance researcher Kimberly Miller, MPH, when asked to comment on the new study.

“As such, it is extremely important to also consider trends in cancer mortality rates among this age group, which are declining overall but are increasing for colorectal and uterine cancers. The fact that both incidence and mortality rates are increasing for these two cancers suggests a true increase in disease burden and certainly requires further attention and research,” she said.

Historically, management of cancer in AYAs has fallen somewhere between pediatric and adult oncology, neither of which capture the distinct biological, social, and economic needs of AYAs. Research has also focused on childhood and adult cancers, leaving cancer in AYAs inadequately studied.

The new findings are “valuable to guide more targeted research and interventions specifically to AYAs,” Zaorsky and colleagues say in their report.

Among female patients ― 59.1% of the study population ― incidence increased for 15 cancers, including kidney carcinoma (annual percent change [APC], 3.632), thyroid carcinoma (APC, 3.456), and myeloma, mast cell, and miscellaneous lymphoreticular neoplasms not otherwise specified (APC, 2.805). Rates of five cancers declined, led by astrocytoma not otherwise specified (APC, –3.369) and carcinoma of the gonads (APC, –1.743).

Among male patients, incidence increased for 14 cancers, including kidney carcinoma (APC, 3.572), unspecified soft tissue sarcoma (APC 2.543), and thyroid carcinoma (APC, 2.273). Incidence fell for seven, led by astrocytoma not otherwise specified (APC, –3.759) and carcinoma of the trachea, bronchus, and lung (APC, –2.635).

Increased testicular cancer rates (APC, 1.246) could be related to greater prenatal exposure to estrogen and progesterone or through dairy consumption; increasing survival of premature infants; and greater exposure to cannabis, among other possibilities, the investigators say.

Increases in colorectal cancer might be related to fewer vegetables and more fat and processed meat in the diet; lack of exercise; and increasing obesity. Human papillomavirus infection has also been implicated.

Higher rates of melanoma could be related to tanning bed use.

Declines in some cancers could be related to greater use of oral contraceptives; laws reducing exposure to benzene and other chemicals; and fewer people smoking.

Although kidney carcinoma has increased at the greatest rate, it’s uncommon. Colorectal and thyroid carcinoma, melanoma, non-Hodgkin lymphoma, and germ cell and trophoblastic neoplasms of the gonads contribute more to the overall increase in cancers among AYAs, the investigators note.

Almost 80% of the patients were White; 10.3% were Black.

The study was funded by the National Center for Advancing Translational Sciences. The investigators have disclosed no relevant financial relationships.

This article first appeared on Medscape.com.

Immunotherapy with pembrolizumab holds promise for improving the generally dismal outlook in patients with leptomeningeal metastases, a phase 2 trial suggests.

Results from the trial were reported at the Society for Immunotherapy of Cancer’s 35th Anniversary Annual Meeting.

“Unfortunately, when patients present with leptomeningeal disease, they usually have a poor prognosis. Their median survival is measured at 6-24 weeks,” commented lead study author Jarushka Naidoo, MBBCh, an adjunct assistant professor of oncology at the Sidney Kimmel Comprehensive Cancer Center at Johns Hopkins University, Baltimore, and a consultant medical oncologist at Beaumont Hospital in Dublin.

“While there may be some standard approaches for how we treat leptomeningeal disease, there are no universal standard therapies that are efficacious across solid tumor types,” Dr. Naidoo added.

With this in mind, Dr. Naidoo and colleagues tested systemic pembrolizumab in a trial of patients with leptomeningeal metastases from solid tumors.

The trial closed early because of poor accrual, after enrolling 13 patients: 5 with breast carcinoma, 3 with high-grade glioma, 3 with non–small cell lung cancer, 1 with squamous cell carcinoma of the skin, and 1 with head and neck squamous carcinoma. Nine patients (69%) had received at least two prior lines of systemic therapy.
 

Response, safety, and biomarkers

Overall, five patients (38%) had a central nervous system response, as ascertained from radiologic response on MRI, cytologic response in cerebrospinal fluid (CSF), and/or clinical response in neurologic symptoms, Dr. Naidoo reported.

Two patients had a complete CNS response: a patient with squamous cell carcinoma of the skin, who was still alive at 3 years, and a patient with non–small cell lung cancer, who survived 9 months but succumbed to metastases elsewhere.

For the entire cohort, median CNS progression-free survival was 2.9 months, and median overall survival was 4.9 months.

“This is consistent with published prospective studies of systemic agents for leptomeningeal disease,” Dr. Naidoo pointed out. “Notably, even though numbers are small, we do see the tail-on-the-curve phenomenon in both of these survival curves, which is consistent with immune checkpoint blockade prospective studies.”

The rate of grade 3 or higher treatment-related adverse events was 15.4%, and there were no grade 3 or higher immune-related adverse events.

The number of patients was too small for formal correlational testing, but both patients who achieved a complete response developed immune-related adverse events.

The trial’s biomarker analyses showed that an aneuploidy assay using CSF tumor-derived DNA performed well at detecting leptomeningeal metastases, with sensitivity of 84.6%, compared with just 53.8% for CSF cytopathology (the current preferred method).

A multiplex assay of CSF cytokines identified similar baseline profiles for patients who went on to have responses and showed similar changes in profile (notably a reduction in proinflammatory cytokines) for the two patients who had complete responses.

Given the trial’s 38% CNS response rate, pembrolizumab “needs to be studied in larger populations of patients to confirm this result, but it could be used as a potential treatment option for patients with leptomeningeal disease from solid tumors,” Dr. Naidoo concluded. “Reassuringly, pembrolizumab was well tolerated, and this is extremely important in a patient population that is traditionally quite frail and in which other standard therapies that are used, such as high-dose methotrexate or intrathecal chemotherapy, are associated with far higher rates of toxicity.”
 

An unmet need

“Leptomeningeal metastasis is a strong unmet need, although its occurrence is fortunately quite rare,” commented Kim Margolin, MD, a clinical professor and medical oncologist at City of Hope National Medical Center in Duarte, Calif., who was not involved in this study.

Courtesy of City of Hope

The trial is noteworthy for showing activity of programmed death–1 (PD-1) blockade given only systemically and not with additional intrathecal therapy (as has been done in a concurrent study at MD Anderson Cancer Center) and for providing insight into various biomarkers, Dr. Margolin said in an interview.

“I cannot take a stand on author conclusions other than to agree it warrants further evaluation in carefully selected patients, and it would be great to compare something like peripheral PD-1 blockade alone versus in combination with intrathecal therapy versus a combination such as CTLA4 blockade plus PD-1 blockade such as our group and others have shown to have increased activity in CNS metastases over PD-1 block alone,” Dr. Margolin said.

“The drugs in this class are already approved, so there is no reason not to try them,” she noted.

However, patients with leptomeningeal metastases of melanoma, for example, are likely to have already received anti-PD-1 immunotherapy.

“So the settings in which off-the-shelf PD-1 blockade would be useful are extremely limited,” she concluded.

The current trial was funded by Merck, the National Institutes of Health, the Lung Cancer Foundation of America, the International Association for the Study of Lung Cancer, and Johns Hopkins University Seed Grants. Dr. Naidoo disclosed relationships with AstraZeneca, Merck, Bristol Myers Squibb, and Roche/Genentech. Dr. Margolin disclosed no relevant conflicts of interest.

SOURCE: Naidoo J et al. SITC 2020, Abstract 788.

Immunotherapy with pembrolizumab holds promise for improving the generally dismal outlook in patients with leptomeningeal metastases, a phase 2 trial suggests.

Results from the trial were reported at the Society for Immunotherapy of Cancer’s 35th Anniversary Annual Meeting.

“Unfortunately, when patients present with leptomeningeal disease, they usually have a poor prognosis. Their median survival is measured at 6-24 weeks,” commented lead study author Jarushka Naidoo, MBBCh, an adjunct assistant professor of oncology at the Sidney Kimmel Comprehensive Cancer Center at Johns Hopkins University, Baltimore, and a consultant medical oncologist at Beaumont Hospital in Dublin.

“While there may be some standard approaches for how we treat leptomeningeal disease, there are no universal standard therapies that are efficacious across solid tumor types,” Dr. Naidoo added.

With this in mind, Dr. Naidoo and colleagues tested systemic pembrolizumab in a trial of patients with leptomeningeal metastases from solid tumors.

The trial closed early because of poor accrual, after enrolling 13 patients: 5 with breast carcinoma, 3 with high-grade glioma, 3 with non–small cell lung cancer, 1 with squamous cell carcinoma of the skin, and 1 with head and neck squamous carcinoma. Nine patients (69%) had received at least two prior lines of systemic therapy.
 

Response, safety, and biomarkers

Overall, five patients (38%) had a central nervous system response, as ascertained from radiologic response on MRI, cytologic response in cerebrospinal fluid (CSF), and/or clinical response in neurologic symptoms, Dr. Naidoo reported.

Two patients had a complete CNS response: a patient with squamous cell carcinoma of the skin, who was still alive at 3 years, and a patient with non–small cell lung cancer, who survived 9 months but succumbed to metastases elsewhere.

For the entire cohort, median CNS progression-free survival was 2.9 months, and median overall survival was 4.9 months.

“This is consistent with published prospective studies of systemic agents for leptomeningeal disease,” Dr. Naidoo pointed out. “Notably, even though numbers are small, we do see the tail-on-the-curve phenomenon in both of these survival curves, which is consistent with immune checkpoint blockade prospective studies.”

The rate of grade 3 or higher treatment-related adverse events was 15.4%, and there were no grade 3 or higher immune-related adverse events.

The number of patients was too small for formal correlational testing, but both patients who achieved a complete response developed immune-related adverse events.

The trial’s biomarker analyses showed that an aneuploidy assay using CSF tumor-derived DNA performed well at detecting leptomeningeal metastases, with sensitivity of 84.6%, compared with just 53.8% for CSF cytopathology (the current preferred method).

A multiplex assay of CSF cytokines identified similar baseline profiles for patients who went on to have responses and showed similar changes in profile (notably a reduction in proinflammatory cytokines) for the two patients who had complete responses.

Given the trial’s 38% CNS response rate, pembrolizumab “needs to be studied in larger populations of patients to confirm this result, but it could be used as a potential treatment option for patients with leptomeningeal disease from solid tumors,” Dr. Naidoo concluded. “Reassuringly, pembrolizumab was well tolerated, and this is extremely important in a patient population that is traditionally quite frail and in which other standard therapies that are used, such as high-dose methotrexate or intrathecal chemotherapy, are associated with far higher rates of toxicity.”
 

An unmet need

“Leptomeningeal metastasis is a strong unmet need, although its occurrence is fortunately quite rare,” commented Kim Margolin, MD, a clinical professor and medical oncologist at City of Hope National Medical Center in Duarte, Calif., who was not involved in this study.

Courtesy of City of Hope

The trial is noteworthy for showing activity of programmed death–1 (PD-1) blockade given only systemically and not with additional intrathecal therapy (as has been done in a concurrent study at MD Anderson Cancer Center) and for providing insight into various biomarkers, Dr. Margolin said in an interview.

“I cannot take a stand on author conclusions other than to agree it warrants further evaluation in carefully selected patients, and it would be great to compare something like peripheral PD-1 blockade alone versus in combination with intrathecal therapy versus a combination such as CTLA4 blockade plus PD-1 blockade such as our group and others have shown to have increased activity in CNS metastases over PD-1 block alone,” Dr. Margolin said.

“The drugs in this class are already approved, so there is no reason not to try them,” she noted.

However, patients with leptomeningeal metastases of melanoma, for example, are likely to have already received anti-PD-1 immunotherapy.

“So the settings in which off-the-shelf PD-1 blockade would be useful are extremely limited,” she concluded.

The current trial was funded by Merck, the National Institutes of Health, the Lung Cancer Foundation of America, the International Association for the Study of Lung Cancer, and Johns Hopkins University Seed Grants. Dr. Naidoo disclosed relationships with AstraZeneca, Merck, Bristol Myers Squibb, and Roche/Genentech. Dr. Margolin disclosed no relevant conflicts of interest.

SOURCE: Naidoo J et al. SITC 2020, Abstract 788.

Immunotherapy with pembrolizumab holds promise for improving the generally dismal outlook in patients with leptomeningeal metastases, a phase 2 trial suggests.

Results from the trial were reported at the Society for Immunotherapy of Cancer’s 35th Anniversary Annual Meeting.

“Unfortunately, when patients present with leptomeningeal disease, they usually have a poor prognosis. Their median survival is measured at 6-24 weeks,” commented lead study author Jarushka Naidoo, MBBCh, an adjunct assistant professor of oncology at the Sidney Kimmel Comprehensive Cancer Center at Johns Hopkins University, Baltimore, and a consultant medical oncologist at Beaumont Hospital in Dublin.

“While there may be some standard approaches for how we treat leptomeningeal disease, there are no universal standard therapies that are efficacious across solid tumor types,” Dr. Naidoo added.

With this in mind, Dr. Naidoo and colleagues tested systemic pembrolizumab in a trial of patients with leptomeningeal metastases from solid tumors.

The trial closed early because of poor accrual, after enrolling 13 patients: 5 with breast carcinoma, 3 with high-grade glioma, 3 with non–small cell lung cancer, 1 with squamous cell carcinoma of the skin, and 1 with head and neck squamous carcinoma. Nine patients (69%) had received at least two prior lines of systemic therapy.
 

Response, safety, and biomarkers

Overall, five patients (38%) had a central nervous system response, as ascertained from radiologic response on MRI, cytologic response in cerebrospinal fluid (CSF), and/or clinical response in neurologic symptoms, Dr. Naidoo reported.

Two patients had a complete CNS response: a patient with squamous cell carcinoma of the skin, who was still alive at 3 years, and a patient with non–small cell lung cancer, who survived 9 months but succumbed to metastases elsewhere.

For the entire cohort, median CNS progression-free survival was 2.9 months, and median overall survival was 4.9 months.

“This is consistent with published prospective studies of systemic agents for leptomeningeal disease,” Dr. Naidoo pointed out. “Notably, even though numbers are small, we do see the tail-on-the-curve phenomenon in both of these survival curves, which is consistent with immune checkpoint blockade prospective studies.”

The rate of grade 3 or higher treatment-related adverse events was 15.4%, and there were no grade 3 or higher immune-related adverse events.

The number of patients was too small for formal correlational testing, but both patients who achieved a complete response developed immune-related adverse events.

The trial’s biomarker analyses showed that an aneuploidy assay using CSF tumor-derived DNA performed well at detecting leptomeningeal metastases, with sensitivity of 84.6%, compared with just 53.8% for CSF cytopathology (the current preferred method).

A multiplex assay of CSF cytokines identified similar baseline profiles for patients who went on to have responses and showed similar changes in profile (notably a reduction in proinflammatory cytokines) for the two patients who had complete responses.

Given the trial’s 38% CNS response rate, pembrolizumab “needs to be studied in larger populations of patients to confirm this result, but it could be used as a potential treatment option for patients with leptomeningeal disease from solid tumors,” Dr. Naidoo concluded. “Reassuringly, pembrolizumab was well tolerated, and this is extremely important in a patient population that is traditionally quite frail and in which other standard therapies that are used, such as high-dose methotrexate or intrathecal chemotherapy, are associated with far higher rates of toxicity.”
 

An unmet need

“Leptomeningeal metastasis is a strong unmet need, although its occurrence is fortunately quite rare,” commented Kim Margolin, MD, a clinical professor and medical oncologist at City of Hope National Medical Center in Duarte, Calif., who was not involved in this study.

Courtesy of City of Hope

The trial is noteworthy for showing activity of programmed death–1 (PD-1) blockade given only systemically and not with additional intrathecal therapy (as has been done in a concurrent study at MD Anderson Cancer Center) and for providing insight into various biomarkers, Dr. Margolin said in an interview.

“I cannot take a stand on author conclusions other than to agree it warrants further evaluation in carefully selected patients, and it would be great to compare something like peripheral PD-1 blockade alone versus in combination with intrathecal therapy versus a combination such as CTLA4 blockade plus PD-1 blockade such as our group and others have shown to have increased activity in CNS metastases over PD-1 block alone,” Dr. Margolin said.

“The drugs in this class are already approved, so there is no reason not to try them,” she noted.

However, patients with leptomeningeal metastases of melanoma, for example, are likely to have already received anti-PD-1 immunotherapy.

“So the settings in which off-the-shelf PD-1 blockade would be useful are extremely limited,” she concluded.

The current trial was funded by Merck, the National Institutes of Health, the Lung Cancer Foundation of America, the International Association for the Study of Lung Cancer, and Johns Hopkins University Seed Grants. Dr. Naidoo disclosed relationships with AstraZeneca, Merck, Bristol Myers Squibb, and Roche/Genentech. Dr. Margolin disclosed no relevant conflicts of interest.

SOURCE: Naidoo J et al. SITC 2020, Abstract 788.

Traditional delivery of palliative care to outpatients with cancer is associated with many challenges.

Telehealth can eliminate some of these challenges but comes with issues of its own, according to results of the REACH PC trial.

Jennifer S. Temel, MD, of Massachusetts General Hospital in Boston, discussed the use of telemedicine in palliative care, including results from REACH PC, during an educational session at the ASCO Virtual Quality Care Symposium 2020.

Dr. Temel noted that, for cancer patients, an in-person visit with a palliative care specialist can cost time, induce fatigue, and increase financial burden from transportation and parking expenses.

For caregivers and family, an in-person visit may necessitate absence from family and/or work, require complex scheduling to coordinate with other office visits, and result in additional transportation and/or parking expenses.

For health care systems, to have a dedicated palliative care clinic requires precious space and financial expenditures for office personnel and other resources.

These issues make it attractive to consider whether telehealth could be used for palliative care services.
 

Scarcity of palliative care specialists

In the United States, there is roughly 1 palliative care physician for every 20,000 older adults with a life-limiting illness, according to research published in Annual Review of Public Health in 2014.

In its 2019 state-by-state report card, the Center to Advance Palliative Care noted that only 72% of U.S. hospitals with 50 or more beds have a palliative care team.

For patients with serious illnesses and those who are socioeconomically or geographically disadvantaged, palliative care is often inaccessible.

Inefficiencies in the current system are an additional impediment. Palliative care specialists frequently see patients during a portion of the patient’s routine visit to subspecialty or primary care clinics. This limits the palliative care specialist’s ability to perform comprehensive assessments and provide patient-centered care efficiently.
 

Special considerations regarding telehealth for palliative care

As a specialty, palliative care involves interactions that could make the use of telehealth problematic. For example, conveyance of interest, warmth, and touch are challenging or impossible in a video format.

Palliative care specialists engage with patients regarding relatively serious topics such as prognosis and end-of-life preferences. There is uncertainty about how those discussions would be received by patients and their caregivers via video.

Furthermore, there are logistical impediments such as prescribing opioids with video or across state lines.

Despite these concerns, the ENABLE study showed that supplementing usual oncology care with weekly (transitioning to monthly) telephone-based educational palliative care produced higher quality of life and mood than did usual oncology care alone. These results were published in JAMA in 2009.
 

REACH PC study demonstrates feasibility of telehealth model

Dr. Temel described the ongoing REACH PC trial in which palliative care is delivered via video visits and compared with in-person palliative care for patients with advanced non–small cell lung cancer.

The primary aim of REACH PC is to determine whether telehealth palliative care is equivalent to traditional palliative care in improving quality of life as a supplement to routine oncology care.

Currently, REACH PC has enrolled 581 patients at its 20 sites, spanning a geographically diverse area. Just over half of patients approached about REACH PC agreed to enroll in it. Ultimately, 1,250 enrollees are sought.

Among patients who declined to participate, 7.6% indicated “discomfort with technology” as the reason. Most refusals were due to lack of interest in research (35.1%) and/or palliative care (22.9%).

Older adults were prominent among enrollees. More than 60% were older than 60 years of age, and more than one-third were older than 70 years.

Among patients who began the trial, there were slightly more withdrawals in the telehealth participants, in comparison with in-person participants (13.6% versus 9.1%).

When palliative care clinicians were queried about video visits, 64.3% said there were no challenges. This is comparable to the 65.5% of clinicians who had no challenges with in-person visits.

When problems occurred with video visits, they were most frequently technical (19.1%). Only 1.4% of clinicians reported difficulty addressing topics that felt uncomfortable over video, and 1.5% reported difficulty establishing rapport.

The success rates of video and in-person visits were similar. About 80% of visits accomplished planned goals.
 

‘Webside’ manner

Strategies such as reflective listening and summarizing what patients say (to verify an accurate understanding of the patient’s perspective) are key to successful palliative care visits, regardless of the setting.

For telehealth visits, Dr. Temel described techniques she defined as “webside manner,” to compensate for the inability of the clinician to touch a patient. These techniques include leaning in toward the camera, nodding, and pausing to be certain the patient has finished speaking before the clinician speaks again.
 

Is telehealth the future of palliative care?

I include myself among those oncologists who have voiced concern about moving from face-to-face to remote visits for complicated consultations such as those required for palliative care. Nonetheless, from the preliminary results of the REACH PC trial, it appears that telehealth could be a valuable tool.

To minimize differences between in-person and remote delivery of palliative care, practical strategies for ensuring rapport and facilitating a trusting relationship should be defined further and disseminated.

In addition, we need to be vigilant for widening inequities of care from rapid movement to the use of technology (i.e., an equity gap). In their telehealth experience during the COVID-19 pandemic, investigators at Houston Methodist Cancer Center found that patients declining virtual visits tended to be older, lower-income, and less likely to have commercial insurance. These results were recently published in JCO Oncology Practice.

For the foregoing reasons, hybrid systems for palliative care services will probably always be needed.

Going forward, we should heed the advice of Alvin Toffler in his book Future Shock. Mr. Toffler said, “The illiterate of the 21st century will not be those who cannot read and write, but those who cannot learn, unlearn, and relearn.”

The traditional model for delivering palliative care will almost certainly need to be reimagined and relearned.

Dr. Temel disclosed institutional research funding from Pfizer.


Dr. Lyss was a community-based medical oncologist and clinical researcher for more than 35 years before his recent retirement. His clinical and research interests were focused on breast and lung cancers, as well as expanding clinical trial access to medically underserved populations. He is based in St. Louis. He has no conflicts of interest.

Traditional delivery of palliative care to outpatients with cancer is associated with many challenges.

Telehealth can eliminate some of these challenges but comes with issues of its own, according to results of the REACH PC trial.

Jennifer S. Temel, MD, of Massachusetts General Hospital in Boston, discussed the use of telemedicine in palliative care, including results from REACH PC, during an educational session at the ASCO Virtual Quality Care Symposium 2020.

Dr. Temel noted that, for cancer patients, an in-person visit with a palliative care specialist can cost time, induce fatigue, and increase financial burden from transportation and parking expenses.

For caregivers and family, an in-person visit may necessitate absence from family and/or work, require complex scheduling to coordinate with other office visits, and result in additional transportation and/or parking expenses.

For health care systems, to have a dedicated palliative care clinic requires precious space and financial expenditures for office personnel and other resources.

These issues make it attractive to consider whether telehealth could be used for palliative care services.
 

Scarcity of palliative care specialists

In the United States, there is roughly 1 palliative care physician for every 20,000 older adults with a life-limiting illness, according to research published in Annual Review of Public Health in 2014.

In its 2019 state-by-state report card, the Center to Advance Palliative Care noted that only 72% of U.S. hospitals with 50 or more beds have a palliative care team.

For patients with serious illnesses and those who are socioeconomically or geographically disadvantaged, palliative care is often inaccessible.

Inefficiencies in the current system are an additional impediment. Palliative care specialists frequently see patients during a portion of the patient’s routine visit to subspecialty or primary care clinics. This limits the palliative care specialist’s ability to perform comprehensive assessments and provide patient-centered care efficiently.
 

Special considerations regarding telehealth for palliative care

As a specialty, palliative care involves interactions that could make the use of telehealth problematic. For example, conveyance of interest, warmth, and touch are challenging or impossible in a video format.

Palliative care specialists engage with patients regarding relatively serious topics such as prognosis and end-of-life preferences. There is uncertainty about how those discussions would be received by patients and their caregivers via video.

Furthermore, there are logistical impediments such as prescribing opioids with video or across state lines.

Despite these concerns, the ENABLE study showed that supplementing usual oncology care with weekly (transitioning to monthly) telephone-based educational palliative care produced higher quality of life and mood than did usual oncology care alone. These results were published in JAMA in 2009.
 

REACH PC study demonstrates feasibility of telehealth model

Dr. Temel described the ongoing REACH PC trial in which palliative care is delivered via video visits and compared with in-person palliative care for patients with advanced non–small cell lung cancer.

The primary aim of REACH PC is to determine whether telehealth palliative care is equivalent to traditional palliative care in improving quality of life as a supplement to routine oncology care.

Currently, REACH PC has enrolled 581 patients at its 20 sites, spanning a geographically diverse area. Just over half of patients approached about REACH PC agreed to enroll in it. Ultimately, 1,250 enrollees are sought.

Among patients who declined to participate, 7.6% indicated “discomfort with technology” as the reason. Most refusals were due to lack of interest in research (35.1%) and/or palliative care (22.9%).

Older adults were prominent among enrollees. More than 60% were older than 60 years of age, and more than one-third were older than 70 years.

Among patients who began the trial, there were slightly more withdrawals in the telehealth participants, in comparison with in-person participants (13.6% versus 9.1%).

When palliative care clinicians were queried about video visits, 64.3% said there were no challenges. This is comparable to the 65.5% of clinicians who had no challenges with in-person visits.

When problems occurred with video visits, they were most frequently technical (19.1%). Only 1.4% of clinicians reported difficulty addressing topics that felt uncomfortable over video, and 1.5% reported difficulty establishing rapport.

The success rates of video and in-person visits were similar. About 80% of visits accomplished planned goals.
 

‘Webside’ manner

Strategies such as reflective listening and summarizing what patients say (to verify an accurate understanding of the patient’s perspective) are key to successful palliative care visits, regardless of the setting.

For telehealth visits, Dr. Temel described techniques she defined as “webside manner,” to compensate for the inability of the clinician to touch a patient. These techniques include leaning in toward the camera, nodding, and pausing to be certain the patient has finished speaking before the clinician speaks again.
 

Is telehealth the future of palliative care?

I include myself among those oncologists who have voiced concern about moving from face-to-face to remote visits for complicated consultations such as those required for palliative care. Nonetheless, from the preliminary results of the REACH PC trial, it appears that telehealth could be a valuable tool.

To minimize differences between in-person and remote delivery of palliative care, practical strategies for ensuring rapport and facilitating a trusting relationship should be defined further and disseminated.

In addition, we need to be vigilant for widening inequities of care from rapid movement to the use of technology (i.e., an equity gap). In their telehealth experience during the COVID-19 pandemic, investigators at Houston Methodist Cancer Center found that patients declining virtual visits tended to be older, lower-income, and less likely to have commercial insurance. These results were recently published in JCO Oncology Practice.

For the foregoing reasons, hybrid systems for palliative care services will probably always be needed.

Going forward, we should heed the advice of Alvin Toffler in his book Future Shock. Mr. Toffler said, “The illiterate of the 21st century will not be those who cannot read and write, but those who cannot learn, unlearn, and relearn.”

The traditional model for delivering palliative care will almost certainly need to be reimagined and relearned.

Dr. Temel disclosed institutional research funding from Pfizer.


Dr. Lyss was a community-based medical oncologist and clinical researcher for more than 35 years before his recent retirement. His clinical and research interests were focused on breast and lung cancers, as well as expanding clinical trial access to medically underserved populations. He is based in St. Louis. He has no conflicts of interest.

Traditional delivery of palliative care to outpatients with cancer is associated with many challenges.

Telehealth can eliminate some of these challenges but comes with issues of its own, according to results of the REACH PC trial.

Jennifer S. Temel, MD, of Massachusetts General Hospital in Boston, discussed the use of telemedicine in palliative care, including results from REACH PC, during an educational session at the ASCO Virtual Quality Care Symposium 2020.

Dr. Temel noted that, for cancer patients, an in-person visit with a palliative care specialist can cost time, induce fatigue, and increase financial burden from transportation and parking expenses.

For caregivers and family, an in-person visit may necessitate absence from family and/or work, require complex scheduling to coordinate with other office visits, and result in additional transportation and/or parking expenses.

For health care systems, to have a dedicated palliative care clinic requires precious space and financial expenditures for office personnel and other resources.

These issues make it attractive to consider whether telehealth could be used for palliative care services.
 

Scarcity of palliative care specialists

In the United States, there is roughly 1 palliative care physician for every 20,000 older adults with a life-limiting illness, according to research published in Annual Review of Public Health in 2014.

In its 2019 state-by-state report card, the Center to Advance Palliative Care noted that only 72% of U.S. hospitals with 50 or more beds have a palliative care team.

For patients with serious illnesses and those who are socioeconomically or geographically disadvantaged, palliative care is often inaccessible.

Inefficiencies in the current system are an additional impediment. Palliative care specialists frequently see patients during a portion of the patient’s routine visit to subspecialty or primary care clinics. This limits the palliative care specialist’s ability to perform comprehensive assessments and provide patient-centered care efficiently.
 

Special considerations regarding telehealth for palliative care

As a specialty, palliative care involves interactions that could make the use of telehealth problematic. For example, conveyance of interest, warmth, and touch are challenging or impossible in a video format.

Palliative care specialists engage with patients regarding relatively serious topics such as prognosis and end-of-life preferences. There is uncertainty about how those discussions would be received by patients and their caregivers via video.

Furthermore, there are logistical impediments such as prescribing opioids with video or across state lines.

Despite these concerns, the ENABLE study showed that supplementing usual oncology care with weekly (transitioning to monthly) telephone-based educational palliative care produced higher quality of life and mood than did usual oncology care alone. These results were published in JAMA in 2009.
 

REACH PC study demonstrates feasibility of telehealth model

Dr. Temel described the ongoing REACH PC trial in which palliative care is delivered via video visits and compared with in-person palliative care for patients with advanced non–small cell lung cancer.

The primary aim of REACH PC is to determine whether telehealth palliative care is equivalent to traditional palliative care in improving quality of life as a supplement to routine oncology care.

Currently, REACH PC has enrolled 581 patients at its 20 sites, spanning a geographically diverse area. Just over half of patients approached about REACH PC agreed to enroll in it. Ultimately, 1,250 enrollees are sought.

Among patients who declined to participate, 7.6% indicated “discomfort with technology” as the reason. Most refusals were due to lack of interest in research (35.1%) and/or palliative care (22.9%).

Older adults were prominent among enrollees. More than 60% were older than 60 years of age, and more than one-third were older than 70 years.

Among patients who began the trial, there were slightly more withdrawals in the telehealth participants, in comparison with in-person participants (13.6% versus 9.1%).

When palliative care clinicians were queried about video visits, 64.3% said there were no challenges. This is comparable to the 65.5% of clinicians who had no challenges with in-person visits.

When problems occurred with video visits, they were most frequently technical (19.1%). Only 1.4% of clinicians reported difficulty addressing topics that felt uncomfortable over video, and 1.5% reported difficulty establishing rapport.

The success rates of video and in-person visits were similar. About 80% of visits accomplished planned goals.
 

‘Webside’ manner

Strategies such as reflective listening and summarizing what patients say (to verify an accurate understanding of the patient’s perspective) are key to successful palliative care visits, regardless of the setting.

For telehealth visits, Dr. Temel described techniques she defined as “webside manner,” to compensate for the inability of the clinician to touch a patient. These techniques include leaning in toward the camera, nodding, and pausing to be certain the patient has finished speaking before the clinician speaks again.
 

Is telehealth the future of palliative care?

I include myself among those oncologists who have voiced concern about moving from face-to-face to remote visits for complicated consultations such as those required for palliative care. Nonetheless, from the preliminary results of the REACH PC trial, it appears that telehealth could be a valuable tool.

To minimize differences between in-person and remote delivery of palliative care, practical strategies for ensuring rapport and facilitating a trusting relationship should be defined further and disseminated.

In addition, we need to be vigilant for widening inequities of care from rapid movement to the use of technology (i.e., an equity gap). In their telehealth experience during the COVID-19 pandemic, investigators at Houston Methodist Cancer Center found that patients declining virtual visits tended to be older, lower-income, and less likely to have commercial insurance. These results were recently published in JCO Oncology Practice.

For the foregoing reasons, hybrid systems for palliative care services will probably always be needed.

Going forward, we should heed the advice of Alvin Toffler in his book Future Shock. Mr. Toffler said, “The illiterate of the 21st century will not be those who cannot read and write, but those who cannot learn, unlearn, and relearn.”

The traditional model for delivering palliative care will almost certainly need to be reimagined and relearned.

Dr. Temel disclosed institutional research funding from Pfizer.


Dr. Lyss was a community-based medical oncologist and clinical researcher for more than 35 years before his recent retirement. His clinical and research interests were focused on breast and lung cancers, as well as expanding clinical trial access to medically underserved populations. He is based in St. Louis. He has no conflicts of interest.

Cancer drug approvals between 2000 and 2016 were associated with a significant reduction in deaths from the most common cancers in the United States, according to a new study.

Reductions in mortality were most notable for tumor types with relatively more approvals, including lung and breast cancer, melanoma, lymphoma, and leukemia.

A report from the American Cancer Society (ACS) estimated that, from 1991 to 2017, there were 2,902,200 total cancer deaths avoided from improvements in mortality from all potential sources.

The new findings, reported in the Journal of Medical Economics, suggest that drugs approved between 2000 and 2016 to treat the 15 most common cancer types helped to reduce mortality by 24% per 100,000 people.

“This study provides evidence that a significant share of that reduction from 2000 to 2016 was associated with the introduction of new therapies. The ACS report and other studies demonstrate that the improvements in lung cancer specifically are likely due to new treatments,” said lead study author Joanna P. MacEwan, MD, of PRECISIONheor in Los Angeles.

The findings contribute to a better understanding of whether increased spending on cancer drugs are worth the investment, according to the study authors.

“We provide evidence that the gains in survival measured in clinical trials are translating into health benefits for patients in the real world and confirm previous research that has also shown that new pharmaceutical treatments are associated with improved real-world survival outcomes for patients,” Dr. MacEwan said.
 

Full effect not yet observed

The researchers used a series of national data sets from sources including the Centers for Disease Control and Prevention; the U.S. Mortality Files by the National Center of Health Statistics; Survival, Epidemiology and End Results program; and United States Cancer Statistics.

The team calculated age-adjusted cancer mortality rates per year for the 15 most common tumor types and also looked at incident cases of cancer by tumor type, represented as per 100,000 people, for all ages, races, and genders.

The researchers then translated the change in cancer mortality in the U.S. from 2000 to 2016 associated with treatment stocks in each year into deaths averted per year.

Across the 16 years, mortality was down by 1,291,769 deaths. The following cancers had significant reductions in mortality: breast (n = 127,874), colorectal (n = 46,705), lung (n = 375,256), prostate (n = 476,210), gastric (n = 758), and renal (n = 739) cancers, as well as non-Hodgkin lymphoma (n = 48,836) and leukemia (n = 4,011).

Estimated mortality increased by 825 deaths in patients with thyroid cancer and 7,768 deaths for those with bladder cancer. These rises are likely due to the result of sparse drug approvals during this period – five for thyroid cancer and three for bladder cancer – Dr. MacEwan said. There were no approvals in liver or uterine cancer and few approvals in pancreatic and oral cancer.

The full effect of new drug introductions may not have been observed yet, Dr. MacEwan noted.

“There are fewer patients using the treatments for drugs approved in the later years of our study and less follow-up time to measure outcomes,” she said. “Over time, utilization of the newer therapies will likely increase and the full effect on mortality will be observed.”
 

Other factors at play

Multiple factors have led to the declines in mortality, said William G. Cance, MD, chief medical and scientific officer for the ACS, who was not involved in this study. “We are slowly sorting out the explanations in greater granularity.”  

Dr. MacEwan said improved cancer screening may partially explain the decline in mortality in some tumor types.

“If screening in a particular tumor type improved during the study period and tumors were diagnosed earlier, then mortality for that tumor type may decline,” she said. “However, we did not find strong evidence to suggest that there were significant changes in screening during our study period. Breast cancer screening rates, for example, were stable over our study period.”  

Cancer screening is not as strong an influence as it should be, Dr. Cance said.

“The lung cancer screening rate is low. In breast and colorectal cancers, we need to double down on earlier screening,” he said, noting that less than one-quarter of adults between ages 45 and 50 years are currently screened for colorectal cancer. The ACS recommends that people at average risk of colorectal cancer start regular screening at age 45.

More research is necessary to evaluate the relationship between drug approvals and cancer mortality, Dr. MacEwan said.

“Research directly linking utilization of new therapies to improved survival or reduced mortality in the real-world setting would more definitively demonstrate the impact of new treatments,” she said. “New therapies have improved outcomes for many patients and should continue to be considered as key elements of cancer treatment.”

“We need to continue to reduce tobacco smoking and improve on modifiable behaviors at the same time as we work on getting new drugs to cancer patients,” Dr. Cance said. “We are coming into an era of multiple new therapeutics, including targeted therapies, immunotherapies, and cellular therapies. Clinicians need to look closely at the trial data of new drugs and pay close attention to those that have the most mortality impact.”

“We also need equitable distribution of newer drugs,” Dr. Cance added. “They should be distributed to everybody who deserves them. Mortality is often impacted by social determinants of health.”

Funding for this research was provided by Pfizer. Study authors disclosed relationships, including employment, with Pfizer. Dr. Cance had no disclosures.

SOURCE: MacEwan JP et al. J Med Econ. 2020 Nov 9;1-12.

Cancer drug approvals between 2000 and 2016 were associated with a significant reduction in deaths from the most common cancers in the United States, according to a new study.

Reductions in mortality were most notable for tumor types with relatively more approvals, including lung and breast cancer, melanoma, lymphoma, and leukemia.

A report from the American Cancer Society (ACS) estimated that, from 1991 to 2017, there were 2,902,200 total cancer deaths avoided from improvements in mortality from all potential sources.

The new findings, reported in the Journal of Medical Economics, suggest that drugs approved between 2000 and 2016 to treat the 15 most common cancer types helped to reduce mortality by 24% per 100,000 people.

“This study provides evidence that a significant share of that reduction from 2000 to 2016 was associated with the introduction of new therapies. The ACS report and other studies demonstrate that the improvements in lung cancer specifically are likely due to new treatments,” said lead study author Joanna P. MacEwan, MD, of PRECISIONheor in Los Angeles.

The findings contribute to a better understanding of whether increased spending on cancer drugs are worth the investment, according to the study authors.

“We provide evidence that the gains in survival measured in clinical trials are translating into health benefits for patients in the real world and confirm previous research that has also shown that new pharmaceutical treatments are associated with improved real-world survival outcomes for patients,” Dr. MacEwan said.
 

Full effect not yet observed

The researchers used a series of national data sets from sources including the Centers for Disease Control and Prevention; the U.S. Mortality Files by the National Center of Health Statistics; Survival, Epidemiology and End Results program; and United States Cancer Statistics.

The team calculated age-adjusted cancer mortality rates per year for the 15 most common tumor types and also looked at incident cases of cancer by tumor type, represented as per 100,000 people, for all ages, races, and genders.

The researchers then translated the change in cancer mortality in the U.S. from 2000 to 2016 associated with treatment stocks in each year into deaths averted per year.

Across the 16 years, mortality was down by 1,291,769 deaths. The following cancers had significant reductions in mortality: breast (n = 127,874), colorectal (n = 46,705), lung (n = 375,256), prostate (n = 476,210), gastric (n = 758), and renal (n = 739) cancers, as well as non-Hodgkin lymphoma (n = 48,836) and leukemia (n = 4,011).

Estimated mortality increased by 825 deaths in patients with thyroid cancer and 7,768 deaths for those with bladder cancer. These rises are likely due to the result of sparse drug approvals during this period – five for thyroid cancer and three for bladder cancer – Dr. MacEwan said. There were no approvals in liver or uterine cancer and few approvals in pancreatic and oral cancer.

The full effect of new drug introductions may not have been observed yet, Dr. MacEwan noted.

“There are fewer patients using the treatments for drugs approved in the later years of our study and less follow-up time to measure outcomes,” she said. “Over time, utilization of the newer therapies will likely increase and the full effect on mortality will be observed.”
 

Other factors at play

Multiple factors have led to the declines in mortality, said William G. Cance, MD, chief medical and scientific officer for the ACS, who was not involved in this study. “We are slowly sorting out the explanations in greater granularity.”  

Dr. MacEwan said improved cancer screening may partially explain the decline in mortality in some tumor types.

“If screening in a particular tumor type improved during the study period and tumors were diagnosed earlier, then mortality for that tumor type may decline,” she said. “However, we did not find strong evidence to suggest that there were significant changes in screening during our study period. Breast cancer screening rates, for example, were stable over our study period.”  

Cancer screening is not as strong an influence as it should be, Dr. Cance said.

“The lung cancer screening rate is low. In breast and colorectal cancers, we need to double down on earlier screening,” he said, noting that less than one-quarter of adults between ages 45 and 50 years are currently screened for colorectal cancer. The ACS recommends that people at average risk of colorectal cancer start regular screening at age 45.

More research is necessary to evaluate the relationship between drug approvals and cancer mortality, Dr. MacEwan said.

“Research directly linking utilization of new therapies to improved survival or reduced mortality in the real-world setting would more definitively demonstrate the impact of new treatments,” she said. “New therapies have improved outcomes for many patients and should continue to be considered as key elements of cancer treatment.”

“We need to continue to reduce tobacco smoking and improve on modifiable behaviors at the same time as we work on getting new drugs to cancer patients,” Dr. Cance said. “We are coming into an era of multiple new therapeutics, including targeted therapies, immunotherapies, and cellular therapies. Clinicians need to look closely at the trial data of new drugs and pay close attention to those that have the most mortality impact.”

“We also need equitable distribution of newer drugs,” Dr. Cance added. “They should be distributed to everybody who deserves them. Mortality is often impacted by social determinants of health.”

Funding for this research was provided by Pfizer. Study authors disclosed relationships, including employment, with Pfizer. Dr. Cance had no disclosures.

SOURCE: MacEwan JP et al. J Med Econ. 2020 Nov 9;1-12.

Cancer drug approvals between 2000 and 2016 were associated with a significant reduction in deaths from the most common cancers in the United States, according to a new study.

Reductions in mortality were most notable for tumor types with relatively more approvals, including lung and breast cancer, melanoma, lymphoma, and leukemia.

A report from the American Cancer Society (ACS) estimated that, from 1991 to 2017, there were 2,902,200 total cancer deaths avoided from improvements in mortality from all potential sources.

The new findings, reported in the Journal of Medical Economics, suggest that drugs approved between 2000 and 2016 to treat the 15 most common cancer types helped to reduce mortality by 24% per 100,000 people.

“This study provides evidence that a significant share of that reduction from 2000 to 2016 was associated with the introduction of new therapies. The ACS report and other studies demonstrate that the improvements in lung cancer specifically are likely due to new treatments,” said lead study author Joanna P. MacEwan, MD, of PRECISIONheor in Los Angeles.

The findings contribute to a better understanding of whether increased spending on cancer drugs are worth the investment, according to the study authors.

“We provide evidence that the gains in survival measured in clinical trials are translating into health benefits for patients in the real world and confirm previous research that has also shown that new pharmaceutical treatments are associated with improved real-world survival outcomes for patients,” Dr. MacEwan said.
 

Full effect not yet observed

The researchers used a series of national data sets from sources including the Centers for Disease Control and Prevention; the U.S. Mortality Files by the National Center of Health Statistics; Survival, Epidemiology and End Results program; and United States Cancer Statistics.

The team calculated age-adjusted cancer mortality rates per year for the 15 most common tumor types and also looked at incident cases of cancer by tumor type, represented as per 100,000 people, for all ages, races, and genders.

The researchers then translated the change in cancer mortality in the U.S. from 2000 to 2016 associated with treatment stocks in each year into deaths averted per year.

Across the 16 years, mortality was down by 1,291,769 deaths. The following cancers had significant reductions in mortality: breast (n = 127,874), colorectal (n = 46,705), lung (n = 375,256), prostate (n = 476,210), gastric (n = 758), and renal (n = 739) cancers, as well as non-Hodgkin lymphoma (n = 48,836) and leukemia (n = 4,011).

Estimated mortality increased by 825 deaths in patients with thyroid cancer and 7,768 deaths for those with bladder cancer. These rises are likely due to the result of sparse drug approvals during this period – five for thyroid cancer and three for bladder cancer – Dr. MacEwan said. There were no approvals in liver or uterine cancer and few approvals in pancreatic and oral cancer.

The full effect of new drug introductions may not have been observed yet, Dr. MacEwan noted.

“There are fewer patients using the treatments for drugs approved in the later years of our study and less follow-up time to measure outcomes,” she said. “Over time, utilization of the newer therapies will likely increase and the full effect on mortality will be observed.”
 

Other factors at play

Multiple factors have led to the declines in mortality, said William G. Cance, MD, chief medical and scientific officer for the ACS, who was not involved in this study. “We are slowly sorting out the explanations in greater granularity.”  

Dr. MacEwan said improved cancer screening may partially explain the decline in mortality in some tumor types.

“If screening in a particular tumor type improved during the study period and tumors were diagnosed earlier, then mortality for that tumor type may decline,” she said. “However, we did not find strong evidence to suggest that there were significant changes in screening during our study period. Breast cancer screening rates, for example, were stable over our study period.”  

Cancer screening is not as strong an influence as it should be, Dr. Cance said.

“The lung cancer screening rate is low. In breast and colorectal cancers, we need to double down on earlier screening,” he said, noting that less than one-quarter of adults between ages 45 and 50 years are currently screened for colorectal cancer. The ACS recommends that people at average risk of colorectal cancer start regular screening at age 45.

More research is necessary to evaluate the relationship between drug approvals and cancer mortality, Dr. MacEwan said.

“Research directly linking utilization of new therapies to improved survival or reduced mortality in the real-world setting would more definitively demonstrate the impact of new treatments,” she said. “New therapies have improved outcomes for many patients and should continue to be considered as key elements of cancer treatment.”

“We need to continue to reduce tobacco smoking and improve on modifiable behaviors at the same time as we work on getting new drugs to cancer patients,” Dr. Cance said. “We are coming into an era of multiple new therapeutics, including targeted therapies, immunotherapies, and cellular therapies. Clinicians need to look closely at the trial data of new drugs and pay close attention to those that have the most mortality impact.”

“We also need equitable distribution of newer drugs,” Dr. Cance added. “They should be distributed to everybody who deserves them. Mortality is often impacted by social determinants of health.”

Funding for this research was provided by Pfizer. Study authors disclosed relationships, including employment, with Pfizer. Dr. Cance had no disclosures.

SOURCE: MacEwan JP et al. J Med Econ. 2020 Nov 9;1-12.

People whose treatment for cancer is delayed by even 1 month have a 6%-13% higher risk of dying, suggests research published online in the BMJ.

In light of the treatment delays resulting from the pandemic, Canadian and U.K. researchers carried out a review and analysis of relevant studies published between January 2000 and April 2020.

Included studies examined data on surgical interventions, systemic therapy, or radiotherapy for seven forms of cancer – bladder, breast, colon, rectum, lung, cervix, and head and neck. Delays were measured from diagnosis to the first treatment or from the completion of one treatment to the start of the next.

The search identified 34 suitable studies for 17 indications, with data from more than 1.2 million patients. The analysis identified a significant association between delay and increased mortality for 13 of the 17 indications (P < .05).

For surgery, there was a 6%-8% increase in the risk of death for every 4-week treatment delay. Estimates for systemic treatment varied (hazard ratio range, 1.01-1.28). Four-week delays in radiotherapy were for radical radiotherapy for head and neck cancer (HR, 1.09; 95% confidence interval, 1.05-1.14), adjuvant radiotherapy after breast-conserving surgery (HR, 0.98; 95% CI, 0.88-1.09), and cervical cancer adjuvant radiotherapy (HR, 1.23; 95% CI, 1.00-1.50).

Delays of up to 8 and 12 weeks further increased mortality. An 8-week delay in breast cancer surgery was linked to a 17% increased mortality, and a 12-week delay would increase mortality by 26%.

A surgical delay of 12 weeks for patients with breast cancer continuing for 1 year – which is likely to be the case as the pandemic continues – would lead to 1,400 excess deaths in the United Kingdom.

The authors said the results of this study could be used to guide policy making on the organization of cancer services, particularly as the pandemic continues and further delays are expected.

This article originally appeared on Univadis, part of the Medscape Professional Network.

People whose treatment for cancer is delayed by even 1 month have a 6%-13% higher risk of dying, suggests research published online in the BMJ.

In light of the treatment delays resulting from the pandemic, Canadian and U.K. researchers carried out a review and analysis of relevant studies published between January 2000 and April 2020.

Included studies examined data on surgical interventions, systemic therapy, or radiotherapy for seven forms of cancer – bladder, breast, colon, rectum, lung, cervix, and head and neck. Delays were measured from diagnosis to the first treatment or from the completion of one treatment to the start of the next.

The search identified 34 suitable studies for 17 indications, with data from more than 1.2 million patients. The analysis identified a significant association between delay and increased mortality for 13 of the 17 indications (P < .05).

For surgery, there was a 6%-8% increase in the risk of death for every 4-week treatment delay. Estimates for systemic treatment varied (hazard ratio range, 1.01-1.28). Four-week delays in radiotherapy were for radical radiotherapy for head and neck cancer (HR, 1.09; 95% confidence interval, 1.05-1.14), adjuvant radiotherapy after breast-conserving surgery (HR, 0.98; 95% CI, 0.88-1.09), and cervical cancer adjuvant radiotherapy (HR, 1.23; 95% CI, 1.00-1.50).

Delays of up to 8 and 12 weeks further increased mortality. An 8-week delay in breast cancer surgery was linked to a 17% increased mortality, and a 12-week delay would increase mortality by 26%.

A surgical delay of 12 weeks for patients with breast cancer continuing for 1 year – which is likely to be the case as the pandemic continues – would lead to 1,400 excess deaths in the United Kingdom.

The authors said the results of this study could be used to guide policy making on the organization of cancer services, particularly as the pandemic continues and further delays are expected.

This article originally appeared on Univadis, part of the Medscape Professional Network.

People whose treatment for cancer is delayed by even 1 month have a 6%-13% higher risk of dying, suggests research published online in the BMJ.

In light of the treatment delays resulting from the pandemic, Canadian and U.K. researchers carried out a review and analysis of relevant studies published between January 2000 and April 2020.

Included studies examined data on surgical interventions, systemic therapy, or radiotherapy for seven forms of cancer – bladder, breast, colon, rectum, lung, cervix, and head and neck. Delays were measured from diagnosis to the first treatment or from the completion of one treatment to the start of the next.

The search identified 34 suitable studies for 17 indications, with data from more than 1.2 million patients. The analysis identified a significant association between delay and increased mortality for 13 of the 17 indications (P < .05).

For surgery, there was a 6%-8% increase in the risk of death for every 4-week treatment delay. Estimates for systemic treatment varied (hazard ratio range, 1.01-1.28). Four-week delays in radiotherapy were for radical radiotherapy for head and neck cancer (HR, 1.09; 95% confidence interval, 1.05-1.14), adjuvant radiotherapy after breast-conserving surgery (HR, 0.98; 95% CI, 0.88-1.09), and cervical cancer adjuvant radiotherapy (HR, 1.23; 95% CI, 1.00-1.50).

Delays of up to 8 and 12 weeks further increased mortality. An 8-week delay in breast cancer surgery was linked to a 17% increased mortality, and a 12-week delay would increase mortality by 26%.

A surgical delay of 12 weeks for patients with breast cancer continuing for 1 year – which is likely to be the case as the pandemic continues – would lead to 1,400 excess deaths in the United Kingdom.

The authors said the results of this study could be used to guide policy making on the organization of cancer services, particularly as the pandemic continues and further delays are expected.

This article originally appeared on Univadis, part of the Medscape Professional Network.

Real-world survival outcomes for cancer patients on immune checkpoint inhibitors (ICIs) are inferior to outcomes reported in patients on clinical trials of ICIs, according to research published in JCO Clinical Cancer Informatics.

However, the research also suggests that real-world patients who receive ICIs achieve longer survival than patients on standard-of-care medications.

“Patients receiving ICIs in real-world practice may differ from those enrolled in trials in a variety of ways, including age, race, performance status, and comorbidity burden,” said study author Jerry S.H. Lee, PhD, of the University of Southern California, Los Angeles.

Dr. Lee noted that only 3%-4% of cancer patients participate in clinical trials. In fact, more than half of patients with melanoma and nearly three-quarters of those with non–small cell lung cancer (NSCLC) do not meet criteria for eligibility in clinical trials, he said.

To examine the discrepancies between real-world practice and clinical trials and to better understand which patients receive ICIs in clinical practice, Dr. Lee and colleagues conducted a retrospective analysis using electronic health record data from Veterans Administration (VA) facilities nationwide.

The researchers identified 11,888 cancer patients who were treated with ICIs. The cohort included patients who are underrepresented in pivotal clinical trials, including older, non-White, and/or higher disease-burdened patients.

The majority of patients were treated for NSCLC (51.1%), followed by melanoma (14.4%), renal cell carcinoma (RCC; 8.1%), squamous cell carcinoma of the head and neck (6.8%), urothelial cancer (6.4%), hepatocellular carcinoma (4.5%), and other less common cancer types (8.8%).
 

Overall survival by indication

In general, median overall survival (OS) in the VA cohort was inferior to median OS reported in clinical trials. However, patients treated with first-line nivolumab for melanoma and second-line pembrolizumab or nivolumab for NSCLC had similar OS in the real-world and trial data.

The researchers did not report exact OS numbers from clinical trials. However, they did report the exact numbers from the VA cohort and show OS differences between the VA cohort and clinical trials graphically.

Among patients in the VA cohort, the median OS was:

• 25.5 months in melanoma patients on first-line nivolumab
• 16.3 months in RCC patients receiving nivolumab in the second line or higher
• 14 months in RCC patients on first-line ipilimumab and nivolumab
• 10.6 months in NSCLC patients on first-line pembrolizumab
• 9.9 months in NSCLC patients receiving pembrolizumab or nivolumab in the second line or higher
• 9.1 months in NSCLC patients on first-line pembrolizumab and platinum-based chemotherapy
• 6.7 months in urothelial cancer patients receiving ICIs in the second line or higher.

A number of factors may have contributed to the shorter OS observed in the VA cohort, according to the researchers. The VA cohort is predominantly male, is older, and has a higher degree of comorbidity, compared with patients in clinical trials.

In addition, no data are available to determine the cause for discontinuation of therapy, and VA patients may have received ICIs after failing multiple lines of previous therapy, while clinical trials may limit patients to only one or two previous lines of therapy.

After stratifying VA patients by frailty status, the OS among non-frail patients was more similar to the OS reported in clinical trials.

“Real-world outcomes from the VA were more similar when adjusted for frailty, which shows the importance of patient diversity in clinical trials,” Dr. Lee said. He added that the definition of frailty among VA patients included potential injury during combat and therefore differs from a generic frailty definition.
 

ICIs vs. standard care

The researchers also found that VA patients treated with ICIs had longer OS, compared with a cohort of VA patients receiving standard-of-care therapies.

The median OS was as follows:

• In melanoma patients on first-line treatment – 39.29 months with nivolumab and 5.75 months with chemotherapy (P < .001).
• In RCC patients on first-line treatment – 14.01 months with ipilimumab plus nivolumab and 8.63 months with targeted therapy (P = .051).
• In RCC patients on second-line or greater treatment – 12.43 months with nivolumab and 8.09 months with everolimus (P < .001).
• In NSCLC patients on first-line therapy – 8.88 months with pembrolizumab and 6.38 months with a platinum doublet (P < .001).
• In NSCLC patients on first-line combination therapy – 10.59 months with pembrolizumab plus platinum chemotherapy and 6.38 months with a platinum doublet (P < .001).
• In NSCLC patients on second-line or greater therapy – 10.06 months with pembrolizumab or nivolumab and 6.41 months with docetaxel (P < .001).
• In urothelial cancer patients on second-line or greater therapy – 7.66 months with an ICI and 6.31 months with chemotherapy (P = .043).
   

Help for treatment decisions

“The real-world survival outcomes not only indicate the breadth of indications but also represent patients who tend not to be eligible for immunotherapy trials, based on their health status,” Dr. Lee said. “We hope this dataset of national-level experience provides practicing oncologists evidence to help patients and family members in the process of decision-making about therapy.”

Real-world data can also inform oncologists who face decisions on whether to prescribe or withhold ICIs and patients who face the financial burden of paying for ICIs, he said.

This dataset will be continually updated. The researchers have already added another 10,000 VA patients who have received immunotherapies in the year since the trial began.

“In a longitudinal way, we plan to examine what causes differences in outcomes and continue to find ways to extend care to veterans with a balance of high quality of life,” Dr. Lee said.

“Patients who participate in clinical trials are, on average, younger and healthier than the general population,” said Bora Youn, PhD, a senior biostatistician at Biogen in Cambridge, Mass., who was not involved in this study.

“In the case of immunotherapies, those with poor performance status and autoimmune conditions are often excluded from trials,” Dr. Youn added. “In the real world, these patients can also receive treatments, and clinicians often need to extrapolate the results from clinical trials. It is therefore important to collect real-world data to understand the effectiveness and safety of these therapies in patients with limited evidence.”

Dr. Youn led a real-world study, published in Cancer, of 1,256 Medicare recipients who were diagnosed with NSCLC and received ICI therapy.

“We found that factors associated with poor prognosis in general, such as squamous histology and failure of aggressive prior treatment, are also predictive of decreased survival among those who initiated immunotherapies. Yet, OS of older patients was relatively comparable to those observed in clinical trials,” Dr. Youn said.

“Understanding the real-world effectiveness of these treatments will help improve the evidence base, especially for those underrepresented in clinical trials. These studies can also help identify patients who are most likely to benefit from immunotherapies,” Dr. Youn added.

This study was supported by the VA Office of Research and Development Cooperative Studies Program. Dr. Lee and Dr. Youn disclosed no conflicts of interest.

SOURCE: Jennifer La et al. JCO Clinical Cancer Informatics. 2020:4:918-28.

Real-world survival outcomes for cancer patients on immune checkpoint inhibitors (ICIs) are inferior to outcomes reported in patients on clinical trials of ICIs, according to research published in JCO Clinical Cancer Informatics.

However, the research also suggests that real-world patients who receive ICIs achieve longer survival than patients on standard-of-care medications.

“Patients receiving ICIs in real-world practice may differ from those enrolled in trials in a variety of ways, including age, race, performance status, and comorbidity burden,” said study author Jerry S.H. Lee, PhD, of the University of Southern California, Los Angeles.

Dr. Lee noted that only 3%-4% of cancer patients participate in clinical trials. In fact, more than half of patients with melanoma and nearly three-quarters of those with non–small cell lung cancer (NSCLC) do not meet criteria for eligibility in clinical trials, he said.

To examine the discrepancies between real-world practice and clinical trials and to better understand which patients receive ICIs in clinical practice, Dr. Lee and colleagues conducted a retrospective analysis using electronic health record data from Veterans Administration (VA) facilities nationwide.

The researchers identified 11,888 cancer patients who were treated with ICIs. The cohort included patients who are underrepresented in pivotal clinical trials, including older, non-White, and/or higher disease-burdened patients.

The majority of patients were treated for NSCLC (51.1%), followed by melanoma (14.4%), renal cell carcinoma (RCC; 8.1%), squamous cell carcinoma of the head and neck (6.8%), urothelial cancer (6.4%), hepatocellular carcinoma (4.5%), and other less common cancer types (8.8%).
 

Overall survival by indication

In general, median overall survival (OS) in the VA cohort was inferior to median OS reported in clinical trials. However, patients treated with first-line nivolumab for melanoma and second-line pembrolizumab or nivolumab for NSCLC had similar OS in the real-world and trial data.

The researchers did not report exact OS numbers from clinical trials. However, they did report the exact numbers from the VA cohort and show OS differences between the VA cohort and clinical trials graphically.

Among patients in the VA cohort, the median OS was:

• 25.5 months in melanoma patients on first-line nivolumab
• 16.3 months in RCC patients receiving nivolumab in the second line or higher
• 14 months in RCC patients on first-line ipilimumab and nivolumab
• 10.6 months in NSCLC patients on first-line pembrolizumab
• 9.9 months in NSCLC patients receiving pembrolizumab or nivolumab in the second line or higher
• 9.1 months in NSCLC patients on first-line pembrolizumab and platinum-based chemotherapy
• 6.7 months in urothelial cancer patients receiving ICIs in the second line or higher.

A number of factors may have contributed to the shorter OS observed in the VA cohort, according to the researchers. The VA cohort is predominantly male, is older, and has a higher degree of comorbidity, compared with patients in clinical trials.

In addition, no data are available to determine the cause for discontinuation of therapy, and VA patients may have received ICIs after failing multiple lines of previous therapy, while clinical trials may limit patients to only one or two previous lines of therapy.

After stratifying VA patients by frailty status, the OS among non-frail patients was more similar to the OS reported in clinical trials.

“Real-world outcomes from the VA were more similar when adjusted for frailty, which shows the importance of patient diversity in clinical trials,” Dr. Lee said. He added that the definition of frailty among VA patients included potential injury during combat and therefore differs from a generic frailty definition.
 

ICIs vs. standard care

The researchers also found that VA patients treated with ICIs had longer OS, compared with a cohort of VA patients receiving standard-of-care therapies.

The median OS was as follows:

• In melanoma patients on first-line treatment – 39.29 months with nivolumab and 5.75 months with chemotherapy (P < .001).
• In RCC patients on first-line treatment – 14.01 months with ipilimumab plus nivolumab and 8.63 months with targeted therapy (P = .051).
• In RCC patients on second-line or greater treatment – 12.43 months with nivolumab and 8.09 months with everolimus (P < .001).
• In NSCLC patients on first-line therapy – 8.88 months with pembrolizumab and 6.38 months with a platinum doublet (P < .001).
• In NSCLC patients on first-line combination therapy – 10.59 months with pembrolizumab plus platinum chemotherapy and 6.38 months with a platinum doublet (P < .001).
• In NSCLC patients on second-line or greater therapy – 10.06 months with pembrolizumab or nivolumab and 6.41 months with docetaxel (P < .001).
• In urothelial cancer patients on second-line or greater therapy – 7.66 months with an ICI and 6.31 months with chemotherapy (P = .043).
   

Help for treatment decisions

“The real-world survival outcomes not only indicate the breadth of indications but also represent patients who tend not to be eligible for immunotherapy trials, based on their health status,” Dr. Lee said. “We hope this dataset of national-level experience provides practicing oncologists evidence to help patients and family members in the process of decision-making about therapy.”

Real-world data can also inform oncologists who face decisions on whether to prescribe or withhold ICIs and patients who face the financial burden of paying for ICIs, he said.

This dataset will be continually updated. The researchers have already added another 10,000 VA patients who have received immunotherapies in the year since the trial began.

“In a longitudinal way, we plan to examine what causes differences in outcomes and continue to find ways to extend care to veterans with a balance of high quality of life,” Dr. Lee said.

“Patients who participate in clinical trials are, on average, younger and healthier than the general population,” said Bora Youn, PhD, a senior biostatistician at Biogen in Cambridge, Mass., who was not involved in this study.

“In the case of immunotherapies, those with poor performance status and autoimmune conditions are often excluded from trials,” Dr. Youn added. “In the real world, these patients can also receive treatments, and clinicians often need to extrapolate the results from clinical trials. It is therefore important to collect real-world data to understand the effectiveness and safety of these therapies in patients with limited evidence.”

Dr. Youn led a real-world study, published in Cancer, of 1,256 Medicare recipients who were diagnosed with NSCLC and received ICI therapy.

“We found that factors associated with poor prognosis in general, such as squamous histology and failure of aggressive prior treatment, are also predictive of decreased survival among those who initiated immunotherapies. Yet, OS of older patients was relatively comparable to those observed in clinical trials,” Dr. Youn said.

“Understanding the real-world effectiveness of these treatments will help improve the evidence base, especially for those underrepresented in clinical trials. These studies can also help identify patients who are most likely to benefit from immunotherapies,” Dr. Youn added.

This study was supported by the VA Office of Research and Development Cooperative Studies Program. Dr. Lee and Dr. Youn disclosed no conflicts of interest.

SOURCE: Jennifer La et al. JCO Clinical Cancer Informatics. 2020:4:918-28.

Real-world survival outcomes for cancer patients on immune checkpoint inhibitors (ICIs) are inferior to outcomes reported in patients on clinical trials of ICIs, according to research published in JCO Clinical Cancer Informatics.

However, the research also suggests that real-world patients who receive ICIs achieve longer survival than patients on standard-of-care medications.

“Patients receiving ICIs in real-world practice may differ from those enrolled in trials in a variety of ways, including age, race, performance status, and comorbidity burden,” said study author Jerry S.H. Lee, PhD, of the University of Southern California, Los Angeles.

Dr. Lee noted that only 3%-4% of cancer patients participate in clinical trials. In fact, more than half of patients with melanoma and nearly three-quarters of those with non–small cell lung cancer (NSCLC) do not meet criteria for eligibility in clinical trials, he said.

To examine the discrepancies between real-world practice and clinical trials and to better understand which patients receive ICIs in clinical practice, Dr. Lee and colleagues conducted a retrospective analysis using electronic health record data from Veterans Administration (VA) facilities nationwide.

The researchers identified 11,888 cancer patients who were treated with ICIs. The cohort included patients who are underrepresented in pivotal clinical trials, including older, non-White, and/or higher disease-burdened patients.

The majority of patients were treated for NSCLC (51.1%), followed by melanoma (14.4%), renal cell carcinoma (RCC; 8.1%), squamous cell carcinoma of the head and neck (6.8%), urothelial cancer (6.4%), hepatocellular carcinoma (4.5%), and other less common cancer types (8.8%).
 

Overall survival by indication

In general, median overall survival (OS) in the VA cohort was inferior to median OS reported in clinical trials. However, patients treated with first-line nivolumab for melanoma and second-line pembrolizumab or nivolumab for NSCLC had similar OS in the real-world and trial data.

The researchers did not report exact OS numbers from clinical trials. However, they did report the exact numbers from the VA cohort and show OS differences between the VA cohort and clinical trials graphically.

Among patients in the VA cohort, the median OS was:

• 25.5 months in melanoma patients on first-line nivolumab
• 16.3 months in RCC patients receiving nivolumab in the second line or higher
• 14 months in RCC patients on first-line ipilimumab and nivolumab
• 10.6 months in NSCLC patients on first-line pembrolizumab
• 9.9 months in NSCLC patients receiving pembrolizumab or nivolumab in the second line or higher
• 9.1 months in NSCLC patients on first-line pembrolizumab and platinum-based chemotherapy
• 6.7 months in urothelial cancer patients receiving ICIs in the second line or higher.

A number of factors may have contributed to the shorter OS observed in the VA cohort, according to the researchers. The VA cohort is predominantly male, is older, and has a higher degree of comorbidity, compared with patients in clinical trials.

In addition, no data are available to determine the cause for discontinuation of therapy, and VA patients may have received ICIs after failing multiple lines of previous therapy, while clinical trials may limit patients to only one or two previous lines of therapy.

After stratifying VA patients by frailty status, the OS among non-frail patients was more similar to the OS reported in clinical trials.

“Real-world outcomes from the VA were more similar when adjusted for frailty, which shows the importance of patient diversity in clinical trials,” Dr. Lee said. He added that the definition of frailty among VA patients included potential injury during combat and therefore differs from a generic frailty definition.
 

ICIs vs. standard care

The researchers also found that VA patients treated with ICIs had longer OS, compared with a cohort of VA patients receiving standard-of-care therapies.

The median OS was as follows:

• In melanoma patients on first-line treatment – 39.29 months with nivolumab and 5.75 months with chemotherapy (P < .001).
• In RCC patients on first-line treatment – 14.01 months with ipilimumab plus nivolumab and 8.63 months with targeted therapy (P = .051).
• In RCC patients on second-line or greater treatment – 12.43 months with nivolumab and 8.09 months with everolimus (P < .001).
• In NSCLC patients on first-line therapy – 8.88 months with pembrolizumab and 6.38 months with a platinum doublet (P < .001).
• In NSCLC patients on first-line combination therapy – 10.59 months with pembrolizumab plus platinum chemotherapy and 6.38 months with a platinum doublet (P < .001).
• In NSCLC patients on second-line or greater therapy – 10.06 months with pembrolizumab or nivolumab and 6.41 months with docetaxel (P < .001).
• In urothelial cancer patients on second-line or greater therapy – 7.66 months with an ICI and 6.31 months with chemotherapy (P = .043).
   

Help for treatment decisions

“The real-world survival outcomes not only indicate the breadth of indications but also represent patients who tend not to be eligible for immunotherapy trials, based on their health status,” Dr. Lee said. “We hope this dataset of national-level experience provides practicing oncologists evidence to help patients and family members in the process of decision-making about therapy.”

Real-world data can also inform oncologists who face decisions on whether to prescribe or withhold ICIs and patients who face the financial burden of paying for ICIs, he said.

This dataset will be continually updated. The researchers have already added another 10,000 VA patients who have received immunotherapies in the year since the trial began.

“In a longitudinal way, we plan to examine what causes differences in outcomes and continue to find ways to extend care to veterans with a balance of high quality of life,” Dr. Lee said.

“Patients who participate in clinical trials are, on average, younger and healthier than the general population,” said Bora Youn, PhD, a senior biostatistician at Biogen in Cambridge, Mass., who was not involved in this study.

“In the case of immunotherapies, those with poor performance status and autoimmune conditions are often excluded from trials,” Dr. Youn added. “In the real world, these patients can also receive treatments, and clinicians often need to extrapolate the results from clinical trials. It is therefore important to collect real-world data to understand the effectiveness and safety of these therapies in patients with limited evidence.”

Dr. Youn led a real-world study, published in Cancer, of 1,256 Medicare recipients who were diagnosed with NSCLC and received ICI therapy.

“We found that factors associated with poor prognosis in general, such as squamous histology and failure of aggressive prior treatment, are also predictive of decreased survival among those who initiated immunotherapies. Yet, OS of older patients was relatively comparable to those observed in clinical trials,” Dr. Youn said.

“Understanding the real-world effectiveness of these treatments will help improve the evidence base, especially for those underrepresented in clinical trials. These studies can also help identify patients who are most likely to benefit from immunotherapies,” Dr. Youn added.

This study was supported by the VA Office of Research and Development Cooperative Studies Program. Dr. Lee and Dr. Youn disclosed no conflicts of interest.

SOURCE: Jennifer La et al. JCO Clinical Cancer Informatics. 2020:4:918-28.

Stereotactic radiosurgery (SRS) should replace whole-brain radiotherapy (WBRT) as the new standard of care for patients with four or more brain metastases, say researchers who report results from a randomized trial conducted in patients with four to 15 brain metastases

“SRS was associated with reduced risk of neurocognitive deterioration compared to WBRT, as demonstrated by a constellation of neurocognitive tests, individually or by composite scores,” said lead author Jing Li, MD, PhD, associate professor of radiation oncology and codirector of the Brain Metastasis Clinic at the University of Texas MD Anderson Cancer Center, Houston.

She was speaking at the American Society for Radiation Oncology (ASTRO) 2020 Annual Meeting, which was held online this year because of the COVID pandemic.

“The results from this phase 3 randomized trial strongly support the use of SRS in patients with four to 15 brain metastases to better preserve cognitive function and to minimize interruption of systemic therapy, without compromising overall survival,” said Li.

SRS is already the standard of care for patients with one to three brain metastases. Two previous phase 3 randomized trials showed that SRS was better at preserving cognitive function without compromising overall survival in comparison to WBRT.

However, there has been some controversy over the use of SRS for patients with multiple brain metastases, commented study discussant Sue S. Yom, MD, PhD, a professor in the Departments of Radiation Oncology and Otolaryngology–Head and Neck Surgery, University of California, San Francisco.

This study has shown, “in a practice-changing manner, that giving SRS can improve the quality of life of patients with metastatic disease,” she said.

Up to 30% of cancer patients develop brain metastases. Historically, these have been associated with poor overall survival, in the range of 1 to 4 months.
 

Reduces cognitive decline

The new trial involved 72 patients with four to 15 untreated, nonmelanoma brain metastases (up to 20 lesions were allowed at the time of treatment); the median number of brain metastases was eight. Most (83%) of the trial participants were White, nearly half were aged 60 years or older, and 58% were women.

Patients were randomly assigned to receive either SRS (15–24 Gy per Radiation Therapy Oncology Group protocol 9005) or WBRT (30 Gy in 10 fractions). On the basis of previous research, 62% of patients in the WBRT arm were also given memantine, a dementia drug that can help preserve cognitive function.

All participants completed neurocognitive testing, including testing of learning, memory, attention span, executive function, verbal fluency, processing speed, and motor dexterity, at enrollment and longitudinally.

The primary endpoints were Hopkins Verbal Learning Test – Revised Total Recall (HVLT-R TR) score and local control at 4 months. Secondary endpoints included overall survival, distant brain failure, toxicity, and time to initiation of systemic therapy.

In the primary endpoint analysis, at 4 months, the HVLT-R TR standardized z-score increased by +0.21 (standard error [SE], 0.27) for patients who received SRS, but it declined by –0.74 (SE, 0.36) for WBRT-treated patients (P = .041). On the basis of Clinical Trial Battery Composite score, neurocognitive function of patients in the SRS arm improved on average +0.23 (SE, 0.14) but declined an average –0.73 (SE, 0.35) in the WBRT arm (P = .008).

Li pointed out that there was also a “clinically meaningful and statistically significant benefit” with SRS at 1 month (P = .033) and 6 months (P = .012).

A total of 69 patients (35 for SRS and 34 for WBRT) were evaluable for overall survival, which was similar between the groups (SRS median, 7.8 months; WBRT median, 8.9 months; P = .59). Treatment with SRS resulted in better local control rates (95% at 4 months with SRS and 86.7% with WBRT; P = .09), but the median time to distant brain failure was shorter (10.5 months for WBRT and 6.3 months for SRS; P = .37).

In her discussion of the study, Yom noted that overall survival time was similar in the two arms and that, numerically, it may have even been a little longer in the SRS group. “While it is true that they had more relapses in untreated portions of the brain, they lived as long or longer than those who received WBRT and had better cognitive function,” she noted

Yom also noted that of particular importance was the finding that SRS was associated with shorter interruptions of systemic therapy (time to systemic therapy: SRS, 1.7 weeks; WBRT, 4.1 weeks; P = .001). Patients with metastatic disease usually have cancer in locations other than the brain. They may be receiving some type of systemic therapy, which is interrupted with WBRT, Li commented.

Toxicities of grade 3 or higher were observed in four patients in the WBRT arm and two in the SRS arm. Radiographic evidence of radiation necrosis, a side effect associated with SRS, was observed in 17% patients in the SRS arm of the trial (4% of all treated lesions).

The trial was halted early owing to the publication of another phase 3 trial (NRG Oncology CC 001), which provided level 1 evidence for replacing standard WBRT with hippocampal-avoidance WBRT. Despite the early trial termination, Li concluded that these results “strongly support the use of SRS in patients with four to 15 brain metastases to better preserve cognitive function and to minimize interruption of systemic therapy, without compromising overall survival.”

Li has received research funding from BMS and Medtronic and honorarium from Novocure and Monteris.

This article first appeared on Medscape.com.

Stereotactic radiosurgery (SRS) should replace whole-brain radiotherapy (WBRT) as the new standard of care for patients with four or more brain metastases, say researchers who report results from a randomized trial conducted in patients with four to 15 brain metastases

“SRS was associated with reduced risk of neurocognitive deterioration compared to WBRT, as demonstrated by a constellation of neurocognitive tests, individually or by composite scores,” said lead author Jing Li, MD, PhD, associate professor of radiation oncology and codirector of the Brain Metastasis Clinic at the University of Texas MD Anderson Cancer Center, Houston.

She was speaking at the American Society for Radiation Oncology (ASTRO) 2020 Annual Meeting, which was held online this year because of the COVID pandemic.

“The results from this phase 3 randomized trial strongly support the use of SRS in patients with four to 15 brain metastases to better preserve cognitive function and to minimize interruption of systemic therapy, without compromising overall survival,” said Li.

SRS is already the standard of care for patients with one to three brain metastases. Two previous phase 3 randomized trials showed that SRS was better at preserving cognitive function without compromising overall survival in comparison to WBRT.

However, there has been some controversy over the use of SRS for patients with multiple brain metastases, commented study discussant Sue S. Yom, MD, PhD, a professor in the Departments of Radiation Oncology and Otolaryngology–Head and Neck Surgery, University of California, San Francisco.

This study has shown, “in a practice-changing manner, that giving SRS can improve the quality of life of patients with metastatic disease,” she said.

Up to 30% of cancer patients develop brain metastases. Historically, these have been associated with poor overall survival, in the range of 1 to 4 months.
 

Reduces cognitive decline

The new trial involved 72 patients with four to 15 untreated, nonmelanoma brain metastases (up to 20 lesions were allowed at the time of treatment); the median number of brain metastases was eight. Most (83%) of the trial participants were White, nearly half were aged 60 years or older, and 58% were women.

Patients were randomly assigned to receive either SRS (15–24 Gy per Radiation Therapy Oncology Group protocol 9005) or WBRT (30 Gy in 10 fractions). On the basis of previous research, 62% of patients in the WBRT arm were also given memantine, a dementia drug that can help preserve cognitive function.

All participants completed neurocognitive testing, including testing of learning, memory, attention span, executive function, verbal fluency, processing speed, and motor dexterity, at enrollment and longitudinally.

The primary endpoints were Hopkins Verbal Learning Test – Revised Total Recall (HVLT-R TR) score and local control at 4 months. Secondary endpoints included overall survival, distant brain failure, toxicity, and time to initiation of systemic therapy.

In the primary endpoint analysis, at 4 months, the HVLT-R TR standardized z-score increased by +0.21 (standard error [SE], 0.27) for patients who received SRS, but it declined by –0.74 (SE, 0.36) for WBRT-treated patients (P = .041). On the basis of Clinical Trial Battery Composite score, neurocognitive function of patients in the SRS arm improved on average +0.23 (SE, 0.14) but declined an average –0.73 (SE, 0.35) in the WBRT arm (P = .008).

Li pointed out that there was also a “clinically meaningful and statistically significant benefit” with SRS at 1 month (P = .033) and 6 months (P = .012).

A total of 69 patients (35 for SRS and 34 for WBRT) were evaluable for overall survival, which was similar between the groups (SRS median, 7.8 months; WBRT median, 8.9 months; P = .59). Treatment with SRS resulted in better local control rates (95% at 4 months with SRS and 86.7% with WBRT; P = .09), but the median time to distant brain failure was shorter (10.5 months for WBRT and 6.3 months for SRS; P = .37).

In her discussion of the study, Yom noted that overall survival time was similar in the two arms and that, numerically, it may have even been a little longer in the SRS group. “While it is true that they had more relapses in untreated portions of the brain, they lived as long or longer than those who received WBRT and had better cognitive function,” she noted

Yom also noted that of particular importance was the finding that SRS was associated with shorter interruptions of systemic therapy (time to systemic therapy: SRS, 1.7 weeks; WBRT, 4.1 weeks; P = .001). Patients with metastatic disease usually have cancer in locations other than the brain. They may be receiving some type of systemic therapy, which is interrupted with WBRT, Li commented.

Toxicities of grade 3 or higher were observed in four patients in the WBRT arm and two in the SRS arm. Radiographic evidence of radiation necrosis, a side effect associated with SRS, was observed in 17% patients in the SRS arm of the trial (4% of all treated lesions).

The trial was halted early owing to the publication of another phase 3 trial (NRG Oncology CC 001), which provided level 1 evidence for replacing standard WBRT with hippocampal-avoidance WBRT. Despite the early trial termination, Li concluded that these results “strongly support the use of SRS in patients with four to 15 brain metastases to better preserve cognitive function and to minimize interruption of systemic therapy, without compromising overall survival.”

Li has received research funding from BMS and Medtronic and honorarium from Novocure and Monteris.

This article first appeared on Medscape.com.

Stereotactic radiosurgery (SRS) should replace whole-brain radiotherapy (WBRT) as the new standard of care for patients with four or more brain metastases, say researchers who report results from a randomized trial conducted in patients with four to 15 brain metastases

“SRS was associated with reduced risk of neurocognitive deterioration compared to WBRT, as demonstrated by a constellation of neurocognitive tests, individually or by composite scores,” said lead author Jing Li, MD, PhD, associate professor of radiation oncology and codirector of the Brain Metastasis Clinic at the University of Texas MD Anderson Cancer Center, Houston.

She was speaking at the American Society for Radiation Oncology (ASTRO) 2020 Annual Meeting, which was held online this year because of the COVID pandemic.

“The results from this phase 3 randomized trial strongly support the use of SRS in patients with four to 15 brain metastases to better preserve cognitive function and to minimize interruption of systemic therapy, without compromising overall survival,” said Li.

SRS is already the standard of care for patients with one to three brain metastases. Two previous phase 3 randomized trials showed that SRS was better at preserving cognitive function without compromising overall survival in comparison to WBRT.

However, there has been some controversy over the use of SRS for patients with multiple brain metastases, commented study discussant Sue S. Yom, MD, PhD, a professor in the Departments of Radiation Oncology and Otolaryngology–Head and Neck Surgery, University of California, San Francisco.

This study has shown, “in a practice-changing manner, that giving SRS can improve the quality of life of patients with metastatic disease,” she said.

Up to 30% of cancer patients develop brain metastases. Historically, these have been associated with poor overall survival, in the range of 1 to 4 months.
 

Reduces cognitive decline

The new trial involved 72 patients with four to 15 untreated, nonmelanoma brain metastases (up to 20 lesions were allowed at the time of treatment); the median number of brain metastases was eight. Most (83%) of the trial participants were White, nearly half were aged 60 years or older, and 58% were women.

Patients were randomly assigned to receive either SRS (15–24 Gy per Radiation Therapy Oncology Group protocol 9005) or WBRT (30 Gy in 10 fractions). On the basis of previous research, 62% of patients in the WBRT arm were also given memantine, a dementia drug that can help preserve cognitive function.

All participants completed neurocognitive testing, including testing of learning, memory, attention span, executive function, verbal fluency, processing speed, and motor dexterity, at enrollment and longitudinally.

The primary endpoints were Hopkins Verbal Learning Test – Revised Total Recall (HVLT-R TR) score and local control at 4 months. Secondary endpoints included overall survival, distant brain failure, toxicity, and time to initiation of systemic therapy.

In the primary endpoint analysis, at 4 months, the HVLT-R TR standardized z-score increased by +0.21 (standard error [SE], 0.27) for patients who received SRS, but it declined by –0.74 (SE, 0.36) for WBRT-treated patients (P = .041). On the basis of Clinical Trial Battery Composite score, neurocognitive function of patients in the SRS arm improved on average +0.23 (SE, 0.14) but declined an average –0.73 (SE, 0.35) in the WBRT arm (P = .008).

Li pointed out that there was also a “clinically meaningful and statistically significant benefit” with SRS at 1 month (P = .033) and 6 months (P = .012).

A total of 69 patients (35 for SRS and 34 for WBRT) were evaluable for overall survival, which was similar between the groups (SRS median, 7.8 months; WBRT median, 8.9 months; P = .59). Treatment with SRS resulted in better local control rates (95% at 4 months with SRS and 86.7% with WBRT; P = .09), but the median time to distant brain failure was shorter (10.5 months for WBRT and 6.3 months for SRS; P = .37).

In her discussion of the study, Yom noted that overall survival time was similar in the two arms and that, numerically, it may have even been a little longer in the SRS group. “While it is true that they had more relapses in untreated portions of the brain, they lived as long or longer than those who received WBRT and had better cognitive function,” she noted

Yom also noted that of particular importance was the finding that SRS was associated with shorter interruptions of systemic therapy (time to systemic therapy: SRS, 1.7 weeks; WBRT, 4.1 weeks; P = .001). Patients with metastatic disease usually have cancer in locations other than the brain. They may be receiving some type of systemic therapy, which is interrupted with WBRT, Li commented.

Toxicities of grade 3 or higher were observed in four patients in the WBRT arm and two in the SRS arm. Radiographic evidence of radiation necrosis, a side effect associated with SRS, was observed in 17% patients in the SRS arm of the trial (4% of all treated lesions).

The trial was halted early owing to the publication of another phase 3 trial (NRG Oncology CC 001), which provided level 1 evidence for replacing standard WBRT with hippocampal-avoidance WBRT. Despite the early trial termination, Li concluded that these results “strongly support the use of SRS in patients with four to 15 brain metastases to better preserve cognitive function and to minimize interruption of systemic therapy, without compromising overall survival.”

Li has received research funding from BMS and Medtronic and honorarium from Novocure and Monteris.

This article first appeared on Medscape.com.

It’s not ready for the clinic, but new research suggests that angiotensin receptor II blockers (ARBs) widely used to treat hypertension may improve responses to cancer immunotherapy agents targeted against the programmed death-1/ligand-1 (PD-1/PD-L1) pathway.

That conclusion comes from an observational study of 597 patients with more than 3 dozen different cancer types treated in clinical trials at the US National Institutes of Health. Investigators found that both objective response rates and 3-year overall survival (OS) rates were significantly higher for patients treated with a PD-1/PD-L1 inhibitor who were on ARBs, compared with patients who weren’t taking the antihypertensive agents.

An association was also seen between higher ORR and OS rates for patients taking ACE inhibitors, but it was not statistically significant, reported Julius Strauss, MD, from the Center for Cancer Research at the National Cancer Institute in Bethesda, Md.

All study patients received PD-1/PD-L1 inhibitors, and the ORR for patients treated with ARBs was 33.8%, compared with 19.5% for those treated with ACE inhibitors, and 17% for those who took neither drug. The respective complete response (CR) rates were 11.3%, 3.7%, and 3.1%.

Strauss discussed the data during an online briefing prior to his presentation of the findings during the 32nd EORTC-NCI-AACR Symposium on Molecular Targets and Cancer Therapeutics, which is taking place virtually.

Several early studies have suggested that angiotensin II, in addition to its effect on blood pressure, can also affect cancer growth by leading to downstream production of two proteins: vascular endothelial growth factor (VEGF) and transforming growth factor–beta (TGF-beta), he explained.

“Both of these [proteins] have been linked to cancer growth and cancer resistance to immune system attack,” Strauss observed.

He also discussed the mechanics of possible effects. Angiotensin II increases VEGF and TGF-beta through binding to the AT1 receptor, but has the opposite effect when it binds to the AT2 receptor, resulting in a decrease in both of the growth factors, he added.

ACE inhibitors prevent the conversion of angiotensin I to angiotensin II, with the result being that the drugs indirectly block both the AT1 and AT2 receptors.

In contrast, ARBs block only the AT1 receptor and leave the AT2 counter-regulatory receptor alone, said Strauss.
 

More data, including on overall survival

Strauss and colleagues examined whether ACE inhibitors and/or ARBs could have an effect on the response to PD-1/PD-L1 immune checkpoint inhibitors delivered with or without other immunotherapies, such as anti-cytotoxic T-lymphocyte-associated protein 4 (CTLA-4) checkpoint inhibitors, or targeted agents such as tyrosine kinase inhibitors (TKIs).

They pooled data on 597 patients receiving PD-1/PD-L1 inhibitors in clinical trials for various cancers, including 71 receiving concomitant ARBs, 82 receiving an ACE inhibitor, and 444 who were not receiving either class of antihypertensives.

The above-mentioned improvement in ORR with ARBs compared with patients not receiving the drug was statistically significant (P = .001), as was the improvement in CR rates (P = .002). In contrast, neither ORR nor CR were significantly better with patients on ACE inhibitors compared with patients not taking these drugs.

In multiple regression analysis controlling for age, gender, body mass index (BMI), tumor type, and additional therapies given, the superior ORR and CR rates with ARBs remained (P = .039 and .002, respectively), while there continued to be no significant additional benefit with ACE inhibitors.

The median overall survival was 35.2 months for patients on ARBs, 26.2 months for those on ACE inhibitors, and 18.8 months for patients on neither drug. The respective 3-year OS rates were 48.1%, 37.2%, and 31.5%, with the difference between the ARB and no-drug groups being significant (P = .0078).

In regression analysis controlling for the factors mentioned before, the OS advantage with ARBs but not ACE inhibitors remained significant (P = .006 for ARBs, and .078 for ACE inhibitors).

Strauss emphasized that further study is needed to determine if AT1 blockade can improve outcomes when combined anti-PD-1/PD-L1-based therapy.

It might be reasonable for patients who are taking ACE inhibitors to control blood pressure and are also receiving immunotherapy with a PD-1/PD-L1 inhibitor to be switched to an ARB if it is deemed safe and if further research bears it out, said Strauss in response to a question from Medscape Medical News.
 

Hypothesis-generating study

Meeting cochair Emiliano Calvo, MD, PhD, from Hospital de Madrid Norte Sanchinarro in Madrid, who attended the media briefing but was not involved in the study, commented that hypothesis-generating research using drugs already on the market for other indications adds important value to cancer therapy.

James Gulley, MD, PhD, from the Center for Cancer Research at the NCI, also a meeting cochair, agreed with Calvo.

“Thinking about utilizing the data that already exists to really get hypothesis-generating questions, it also opens up the possibility for real-world data, real-world evidence from these big datasets from [electronic medical records] that we could really interrogate and understand what we might see and get these hypothesis-generating findings that we could then prospectively evaluate,” Gulley said.

The research was funded by the National Cancer Institute. Strauss and Gulley are National Cancer Institute employees. Calvo disclosed no relevant financial relationships.

This article first appeared on Medscape.com.

It’s not ready for the clinic, but new research suggests that angiotensin receptor II blockers (ARBs) widely used to treat hypertension may improve responses to cancer immunotherapy agents targeted against the programmed death-1/ligand-1 (PD-1/PD-L1) pathway.

That conclusion comes from an observational study of 597 patients with more than 3 dozen different cancer types treated in clinical trials at the US National Institutes of Health. Investigators found that both objective response rates and 3-year overall survival (OS) rates were significantly higher for patients treated with a PD-1/PD-L1 inhibitor who were on ARBs, compared with patients who weren’t taking the antihypertensive agents.

An association was also seen between higher ORR and OS rates for patients taking ACE inhibitors, but it was not statistically significant, reported Julius Strauss, MD, from the Center for Cancer Research at the National Cancer Institute in Bethesda, Md.

All study patients received PD-1/PD-L1 inhibitors, and the ORR for patients treated with ARBs was 33.8%, compared with 19.5% for those treated with ACE inhibitors, and 17% for those who took neither drug. The respective complete response (CR) rates were 11.3%, 3.7%, and 3.1%.

Strauss discussed the data during an online briefing prior to his presentation of the findings during the 32nd EORTC-NCI-AACR Symposium on Molecular Targets and Cancer Therapeutics, which is taking place virtually.

Several early studies have suggested that angiotensin II, in addition to its effect on blood pressure, can also affect cancer growth by leading to downstream production of two proteins: vascular endothelial growth factor (VEGF) and transforming growth factor–beta (TGF-beta), he explained.

“Both of these [proteins] have been linked to cancer growth and cancer resistance to immune system attack,” Strauss observed.

He also discussed the mechanics of possible effects. Angiotensin II increases VEGF and TGF-beta through binding to the AT1 receptor, but has the opposite effect when it binds to the AT2 receptor, resulting in a decrease in both of the growth factors, he added.

ACE inhibitors prevent the conversion of angiotensin I to angiotensin II, with the result being that the drugs indirectly block both the AT1 and AT2 receptors.

In contrast, ARBs block only the AT1 receptor and leave the AT2 counter-regulatory receptor alone, said Strauss.
 

More data, including on overall survival

Strauss and colleagues examined whether ACE inhibitors and/or ARBs could have an effect on the response to PD-1/PD-L1 immune checkpoint inhibitors delivered with or without other immunotherapies, such as anti-cytotoxic T-lymphocyte-associated protein 4 (CTLA-4) checkpoint inhibitors, or targeted agents such as tyrosine kinase inhibitors (TKIs).

They pooled data on 597 patients receiving PD-1/PD-L1 inhibitors in clinical trials for various cancers, including 71 receiving concomitant ARBs, 82 receiving an ACE inhibitor, and 444 who were not receiving either class of antihypertensives.

The above-mentioned improvement in ORR with ARBs compared with patients not receiving the drug was statistically significant (P = .001), as was the improvement in CR rates (P = .002). In contrast, neither ORR nor CR were significantly better with patients on ACE inhibitors compared with patients not taking these drugs.

In multiple regression analysis controlling for age, gender, body mass index (BMI), tumor type, and additional therapies given, the superior ORR and CR rates with ARBs remained (P = .039 and .002, respectively), while there continued to be no significant additional benefit with ACE inhibitors.

The median overall survival was 35.2 months for patients on ARBs, 26.2 months for those on ACE inhibitors, and 18.8 months for patients on neither drug. The respective 3-year OS rates were 48.1%, 37.2%, and 31.5%, with the difference between the ARB and no-drug groups being significant (P = .0078).

In regression analysis controlling for the factors mentioned before, the OS advantage with ARBs but not ACE inhibitors remained significant (P = .006 for ARBs, and .078 for ACE inhibitors).

Strauss emphasized that further study is needed to determine if AT1 blockade can improve outcomes when combined anti-PD-1/PD-L1-based therapy.

It might be reasonable for patients who are taking ACE inhibitors to control blood pressure and are also receiving immunotherapy with a PD-1/PD-L1 inhibitor to be switched to an ARB if it is deemed safe and if further research bears it out, said Strauss in response to a question from Medscape Medical News.
 

Hypothesis-generating study

Meeting cochair Emiliano Calvo, MD, PhD, from Hospital de Madrid Norte Sanchinarro in Madrid, who attended the media briefing but was not involved in the study, commented that hypothesis-generating research using drugs already on the market for other indications adds important value to cancer therapy.

James Gulley, MD, PhD, from the Center for Cancer Research at the NCI, also a meeting cochair, agreed with Calvo.

“Thinking about utilizing the data that already exists to really get hypothesis-generating questions, it also opens up the possibility for real-world data, real-world evidence from these big datasets from [electronic medical records] that we could really interrogate and understand what we might see and get these hypothesis-generating findings that we could then prospectively evaluate,” Gulley said.

The research was funded by the National Cancer Institute. Strauss and Gulley are National Cancer Institute employees. Calvo disclosed no relevant financial relationships.

This article first appeared on Medscape.com.

It’s not ready for the clinic, but new research suggests that angiotensin receptor II blockers (ARBs) widely used to treat hypertension may improve responses to cancer immunotherapy agents targeted against the programmed death-1/ligand-1 (PD-1/PD-L1) pathway.

That conclusion comes from an observational study of 597 patients with more than 3 dozen different cancer types treated in clinical trials at the US National Institutes of Health. Investigators found that both objective response rates and 3-year overall survival (OS) rates were significantly higher for patients treated with a PD-1/PD-L1 inhibitor who were on ARBs, compared with patients who weren’t taking the antihypertensive agents.

An association was also seen between higher ORR and OS rates for patients taking ACE inhibitors, but it was not statistically significant, reported Julius Strauss, MD, from the Center for Cancer Research at the National Cancer Institute in Bethesda, Md.

All study patients received PD-1/PD-L1 inhibitors, and the ORR for patients treated with ARBs was 33.8%, compared with 19.5% for those treated with ACE inhibitors, and 17% for those who took neither drug. The respective complete response (CR) rates were 11.3%, 3.7%, and 3.1%.

Strauss discussed the data during an online briefing prior to his presentation of the findings during the 32nd EORTC-NCI-AACR Symposium on Molecular Targets and Cancer Therapeutics, which is taking place virtually.

Several early studies have suggested that angiotensin II, in addition to its effect on blood pressure, can also affect cancer growth by leading to downstream production of two proteins: vascular endothelial growth factor (VEGF) and transforming growth factor–beta (TGF-beta), he explained.

“Both of these [proteins] have been linked to cancer growth and cancer resistance to immune system attack,” Strauss observed.

He also discussed the mechanics of possible effects. Angiotensin II increases VEGF and TGF-beta through binding to the AT1 receptor, but has the opposite effect when it binds to the AT2 receptor, resulting in a decrease in both of the growth factors, he added.

ACE inhibitors prevent the conversion of angiotensin I to angiotensin II, with the result being that the drugs indirectly block both the AT1 and AT2 receptors.

In contrast, ARBs block only the AT1 receptor and leave the AT2 counter-regulatory receptor alone, said Strauss.
 

More data, including on overall survival

Strauss and colleagues examined whether ACE inhibitors and/or ARBs could have an effect on the response to PD-1/PD-L1 immune checkpoint inhibitors delivered with or without other immunotherapies, such as anti-cytotoxic T-lymphocyte-associated protein 4 (CTLA-4) checkpoint inhibitors, or targeted agents such as tyrosine kinase inhibitors (TKIs).

They pooled data on 597 patients receiving PD-1/PD-L1 inhibitors in clinical trials for various cancers, including 71 receiving concomitant ARBs, 82 receiving an ACE inhibitor, and 444 who were not receiving either class of antihypertensives.

The above-mentioned improvement in ORR with ARBs compared with patients not receiving the drug was statistically significant (P = .001), as was the improvement in CR rates (P = .002). In contrast, neither ORR nor CR were significantly better with patients on ACE inhibitors compared with patients not taking these drugs.

In multiple regression analysis controlling for age, gender, body mass index (BMI), tumor type, and additional therapies given, the superior ORR and CR rates with ARBs remained (P = .039 and .002, respectively), while there continued to be no significant additional benefit with ACE inhibitors.

The median overall survival was 35.2 months for patients on ARBs, 26.2 months for those on ACE inhibitors, and 18.8 months for patients on neither drug. The respective 3-year OS rates were 48.1%, 37.2%, and 31.5%, with the difference between the ARB and no-drug groups being significant (P = .0078).

In regression analysis controlling for the factors mentioned before, the OS advantage with ARBs but not ACE inhibitors remained significant (P = .006 for ARBs, and .078 for ACE inhibitors).

Strauss emphasized that further study is needed to determine if AT1 blockade can improve outcomes when combined anti-PD-1/PD-L1-based therapy.

It might be reasonable for patients who are taking ACE inhibitors to control blood pressure and are also receiving immunotherapy with a PD-1/PD-L1 inhibitor to be switched to an ARB if it is deemed safe and if further research bears it out, said Strauss in response to a question from Medscape Medical News.
 

Hypothesis-generating study

Meeting cochair Emiliano Calvo, MD, PhD, from Hospital de Madrid Norte Sanchinarro in Madrid, who attended the media briefing but was not involved in the study, commented that hypothesis-generating research using drugs already on the market for other indications adds important value to cancer therapy.

James Gulley, MD, PhD, from the Center for Cancer Research at the NCI, also a meeting cochair, agreed with Calvo.

“Thinking about utilizing the data that already exists to really get hypothesis-generating questions, it also opens up the possibility for real-world data, real-world evidence from these big datasets from [electronic medical records] that we could really interrogate and understand what we might see and get these hypothesis-generating findings that we could then prospectively evaluate,” Gulley said.

The research was funded by the National Cancer Institute. Strauss and Gulley are National Cancer Institute employees. Calvo disclosed no relevant financial relationships.

This article first appeared on Medscape.com.