Happy New Year, everyone! In early December, I attended the 2022 AGA Women’s Leadership Collaboration Conference to discuss strategies to promote gender equity in our profession. It was an inspiring weekend and reminded me how many talented individuals we have in the field of gastroenterology, all with fascinating personal and professional stories and much to contribute. I think I speak for all attendees in saying that it was a privilege to have the opportunity to interact with this amazing group of women leaders, reflect on our shared experiences and visions for the future of GI, and expand our networks.

This month we are excited to launch a new recurring feature in the newspaper and online – the Member Spotlight column. AGA has more than16,000 members from varied backgrounds. Yet the reality is that each of our individual networks is much smaller, and we would all benefit from learning more about one other and building a greater sense of community. To that end, starting with this issue, we will feature a different AGA member each month in our Member Spotlight column. The goal of this new feature is to recognize AGA members’ accomplishments across all career stages and practice settings, to highlight the diversity of our membership, and to help AGA members feel more connected by learning more about each other. Our inaugural Member Spotlight column highlights Patricia Jones, MD, associate professor at the University of Miami and an accomplished hepatologist. We thank Dr. Jones for sharing her story with us.

This will be a recurring monthly feature, so please consider nominating your colleagues (including trainees, practicing GIs in academics and community practice, those with non-traditional careers or unique pursuits outside of medicine, and others) to be featured in future Member Spotlight columns! It’s a great way for the nominee’s accomplishments to be recognized and to build a sense of community among the broader AGA membership. To submit a nomination, please send the nominee’s name, email, and a brief description of why you are nominating them to: [email protected]. We look forward to reviewing your submissions and hope you will use these Member Spotlights as an opportunity to strike up a conversation with someone new and expand your networks.

Megan A. Adams, MD, JD, MSc
Editor-in-Chief

Happy New Year, everyone! In early December, I attended the 2022 AGA Women’s Leadership Collaboration Conference to discuss strategies to promote gender equity in our profession. It was an inspiring weekend and reminded me how many talented individuals we have in the field of gastroenterology, all with fascinating personal and professional stories and much to contribute. I think I speak for all attendees in saying that it was a privilege to have the opportunity to interact with this amazing group of women leaders, reflect on our shared experiences and visions for the future of GI, and expand our networks.

This month we are excited to launch a new recurring feature in the newspaper and online – the Member Spotlight column. AGA has more than16,000 members from varied backgrounds. Yet the reality is that each of our individual networks is much smaller, and we would all benefit from learning more about one other and building a greater sense of community. To that end, starting with this issue, we will feature a different AGA member each month in our Member Spotlight column. The goal of this new feature is to recognize AGA members’ accomplishments across all career stages and practice settings, to highlight the diversity of our membership, and to help AGA members feel more connected by learning more about each other. Our inaugural Member Spotlight column highlights Patricia Jones, MD, associate professor at the University of Miami and an accomplished hepatologist. We thank Dr. Jones for sharing her story with us.

This will be a recurring monthly feature, so please consider nominating your colleagues (including trainees, practicing GIs in academics and community practice, those with non-traditional careers or unique pursuits outside of medicine, and others) to be featured in future Member Spotlight columns! It’s a great way for the nominee’s accomplishments to be recognized and to build a sense of community among the broader AGA membership. To submit a nomination, please send the nominee’s name, email, and a brief description of why you are nominating them to: [email protected]. We look forward to reviewing your submissions and hope you will use these Member Spotlights as an opportunity to strike up a conversation with someone new and expand your networks.

Megan A. Adams, MD, JD, MSc
Editor-in-Chief

Happy New Year, everyone! In early December, I attended the 2022 AGA Women’s Leadership Collaboration Conference to discuss strategies to promote gender equity in our profession. It was an inspiring weekend and reminded me how many talented individuals we have in the field of gastroenterology, all with fascinating personal and professional stories and much to contribute. I think I speak for all attendees in saying that it was a privilege to have the opportunity to interact with this amazing group of women leaders, reflect on our shared experiences and visions for the future of GI, and expand our networks.

This month we are excited to launch a new recurring feature in the newspaper and online – the Member Spotlight column. AGA has more than16,000 members from varied backgrounds. Yet the reality is that each of our individual networks is much smaller, and we would all benefit from learning more about one other and building a greater sense of community. To that end, starting with this issue, we will feature a different AGA member each month in our Member Spotlight column. The goal of this new feature is to recognize AGA members’ accomplishments across all career stages and practice settings, to highlight the diversity of our membership, and to help AGA members feel more connected by learning more about each other. Our inaugural Member Spotlight column highlights Patricia Jones, MD, associate professor at the University of Miami and an accomplished hepatologist. We thank Dr. Jones for sharing her story with us.

This will be a recurring monthly feature, so please consider nominating your colleagues (including trainees, practicing GIs in academics and community practice, those with non-traditional careers or unique pursuits outside of medicine, and others) to be featured in future Member Spotlight columns! It’s a great way for the nominee’s accomplishments to be recognized and to build a sense of community among the broader AGA membership. To submit a nomination, please send the nominee’s name, email, and a brief description of why you are nominating them to: [email protected]. We look forward to reviewing your submissions and hope you will use these Member Spotlights as an opportunity to strike up a conversation with someone new and expand your networks.

Megan A. Adams, MD, JD, MSc
Editor-in-Chief

Hepatologist Patricia Denise Jones, MD, recollects the balancing act of going through medical training while caring for her four children.

“I had them at every stage: my first one as a medical student; twins when I was a resident, and my last one at the end of fellowship. It was challenging, trying to put their needs first while trying to be a great doctor, learning how to do research,” said Dr. Jones, an associate professor at the University of Miami Health system.

She has no regrets. “I think I’m a better doctor and colleague because I have children. Showing my kids how important it is to help and serve others is one of the best legacies I can leave them.”

University of Miami Miller School of Medicine Sylvester Comprehensive Cancer Center

Q: Describe your current practice. What gives you the most joy in your day-to-day practice?

Dr. Jones: Being able to make a difference in the lives of patients. A lot of the patients that I take care of have difficulty navigating the health system. That’s the population I feel most inclined to serve. It’s always rewarding to help someone make a connection that they couldn’t make on their own or help them understand something that wasn’t clear. Knowing that you’re helping someone to live a healthier life is deeply gratifying.



Q: Tell me about your patient population.

Dr. Jones: My focus is patients with liver cancer, hepatocellular carcinoma specifically, and cirrhosis patients. They tend to be sick relative to most Americans. I also take care of people who have other forms of liver disease like fatty liver and viral hepatitis. I live in Miami, so most of the patients that I take care of are going to be Hispanic. A good percentage are immigrants with limited health literacy.

Q: What is your biggest practice-related challenge? What are you doing to address it?

Dr. Jones: Lack of insurance and underinsurance. One patient of mine with Medicare and Humana has a carve out: She can see me and some of my colleagues but not the oncologist or a radiation oncologist. For her to be seen in our center, she would have to get a referral from a doctor in a different county. This makes no sense. It’s a hard problem to solve. To me, that’s the most challenging thing – not being able to help when something is beyond my control, beyond what I understand, and translating it into action. 

Q: What general principles guide you in your professional and personal life?

Dr. Jones: I try to think of the Golden Rule in every encounter with a person, either in clinic or in real life, as if they were my mother or sister. If I’m frustrated or having a bad day, what would I want that person’s experience to be with their doctor? I also try to assume the best possible intent with people.

Latosha Y. Flowers, MD

Q: What teacher, mentor, or other influences had the greatest impact on you?

Dr. Jones: My father. He started out as a salesman, worked in legislation, and then retired early to focus on and build up our community, making sure that we were better off than we were before. In terms of my professional life, Robert Sandler, MD is one of my greatest mentors. He is at the University of North Carolina and was the division chief of gastroenterology. He saw potential in me and supports me to this day. If you need something, he’s there. If you need him to comment on your draft, he’s very reliable and gives you great, critical feedback.
 

Q: In 10 years, what do you hope you are doing or what do you hope you have accomplished?

Dr. Jones: In 10 years, I hope that my efforts will have revolutionized our approach to delivering care to vulnerable populations. Much of the work that has been done thus far in the field of disparities and liver disease has focused on describing the inequities. However, I have just started working in health equity. This will require partnering with patients and caregivers to get a better understanding of their needs and collaborating with legislators to increase funding directed towards building the infrastructure necessary to deliver health care to those who have been forgotten.

Lightning round questions

Favorite movie, show, or book
Forrest Gump, Blackish, anything by Toni Morrison

Favorite music genre
Hip Hop

Favorite food
Seafood

Favorite travel destination
Tanzania

Your ideal type of pet
Dog

Optimist or pessimist?
Optimist!

Dr. Jones is on Twitter @DrLiverPatty.

Hepatologist Patricia Denise Jones, MD, recollects the balancing act of going through medical training while caring for her four children.

“I had them at every stage: my first one as a medical student; twins when I was a resident, and my last one at the end of fellowship. It was challenging, trying to put their needs first while trying to be a great doctor, learning how to do research,” said Dr. Jones, an associate professor at the University of Miami Health system.

She has no regrets. “I think I’m a better doctor and colleague because I have children. Showing my kids how important it is to help and serve others is one of the best legacies I can leave them.”

University of Miami Miller School of Medicine Sylvester Comprehensive Cancer Center

Q: Describe your current practice. What gives you the most joy in your day-to-day practice?

Dr. Jones: Being able to make a difference in the lives of patients. A lot of the patients that I take care of have difficulty navigating the health system. That’s the population I feel most inclined to serve. It’s always rewarding to help someone make a connection that they couldn’t make on their own or help them understand something that wasn’t clear. Knowing that you’re helping someone to live a healthier life is deeply gratifying.



Q: Tell me about your patient population.

Dr. Jones: My focus is patients with liver cancer, hepatocellular carcinoma specifically, and cirrhosis patients. They tend to be sick relative to most Americans. I also take care of people who have other forms of liver disease like fatty liver and viral hepatitis. I live in Miami, so most of the patients that I take care of are going to be Hispanic. A good percentage are immigrants with limited health literacy.

Q: What is your biggest practice-related challenge? What are you doing to address it?

Dr. Jones: Lack of insurance and underinsurance. One patient of mine with Medicare and Humana has a carve out: She can see me and some of my colleagues but not the oncologist or a radiation oncologist. For her to be seen in our center, she would have to get a referral from a doctor in a different county. This makes no sense. It’s a hard problem to solve. To me, that’s the most challenging thing – not being able to help when something is beyond my control, beyond what I understand, and translating it into action. 

Q: What general principles guide you in your professional and personal life?

Dr. Jones: I try to think of the Golden Rule in every encounter with a person, either in clinic or in real life, as if they were my mother or sister. If I’m frustrated or having a bad day, what would I want that person’s experience to be with their doctor? I also try to assume the best possible intent with people.

Latosha Y. Flowers, MD

Q: What teacher, mentor, or other influences had the greatest impact on you?

Dr. Jones: My father. He started out as a salesman, worked in legislation, and then retired early to focus on and build up our community, making sure that we were better off than we were before. In terms of my professional life, Robert Sandler, MD is one of my greatest mentors. He is at the University of North Carolina and was the division chief of gastroenterology. He saw potential in me and supports me to this day. If you need something, he’s there. If you need him to comment on your draft, he’s very reliable and gives you great, critical feedback.
 

Q: In 10 years, what do you hope you are doing or what do you hope you have accomplished?

Dr. Jones: In 10 years, I hope that my efforts will have revolutionized our approach to delivering care to vulnerable populations. Much of the work that has been done thus far in the field of disparities and liver disease has focused on describing the inequities. However, I have just started working in health equity. This will require partnering with patients and caregivers to get a better understanding of their needs and collaborating with legislators to increase funding directed towards building the infrastructure necessary to deliver health care to those who have been forgotten.

Lightning round questions

Favorite movie, show, or book
Forrest Gump, Blackish, anything by Toni Morrison

Favorite music genre
Hip Hop

Favorite food
Seafood

Favorite travel destination
Tanzania

Your ideal type of pet
Dog

Optimist or pessimist?
Optimist!

Dr. Jones is on Twitter @DrLiverPatty.

Hepatologist Patricia Denise Jones, MD, recollects the balancing act of going through medical training while caring for her four children.

“I had them at every stage: my first one as a medical student; twins when I was a resident, and my last one at the end of fellowship. It was challenging, trying to put their needs first while trying to be a great doctor, learning how to do research,” said Dr. Jones, an associate professor at the University of Miami Health system.

She has no regrets. “I think I’m a better doctor and colleague because I have children. Showing my kids how important it is to help and serve others is one of the best legacies I can leave them.”

University of Miami Miller School of Medicine Sylvester Comprehensive Cancer Center

Q: Describe your current practice. What gives you the most joy in your day-to-day practice?

Dr. Jones: Being able to make a difference in the lives of patients. A lot of the patients that I take care of have difficulty navigating the health system. That’s the population I feel most inclined to serve. It’s always rewarding to help someone make a connection that they couldn’t make on their own or help them understand something that wasn’t clear. Knowing that you’re helping someone to live a healthier life is deeply gratifying.



Q: Tell me about your patient population.

Dr. Jones: My focus is patients with liver cancer, hepatocellular carcinoma specifically, and cirrhosis patients. They tend to be sick relative to most Americans. I also take care of people who have other forms of liver disease like fatty liver and viral hepatitis. I live in Miami, so most of the patients that I take care of are going to be Hispanic. A good percentage are immigrants with limited health literacy.

Q: What is your biggest practice-related challenge? What are you doing to address it?

Dr. Jones: Lack of insurance and underinsurance. One patient of mine with Medicare and Humana has a carve out: She can see me and some of my colleagues but not the oncologist or a radiation oncologist. For her to be seen in our center, she would have to get a referral from a doctor in a different county. This makes no sense. It’s a hard problem to solve. To me, that’s the most challenging thing – not being able to help when something is beyond my control, beyond what I understand, and translating it into action. 

Q: What general principles guide you in your professional and personal life?

Dr. Jones: I try to think of the Golden Rule in every encounter with a person, either in clinic or in real life, as if they were my mother or sister. If I’m frustrated or having a bad day, what would I want that person’s experience to be with their doctor? I also try to assume the best possible intent with people.

Latosha Y. Flowers, MD

Q: What teacher, mentor, or other influences had the greatest impact on you?

Dr. Jones: My father. He started out as a salesman, worked in legislation, and then retired early to focus on and build up our community, making sure that we were better off than we were before. In terms of my professional life, Robert Sandler, MD is one of my greatest mentors. He is at the University of North Carolina and was the division chief of gastroenterology. He saw potential in me and supports me to this day. If you need something, he’s there. If you need him to comment on your draft, he’s very reliable and gives you great, critical feedback.
 

Q: In 10 years, what do you hope you are doing or what do you hope you have accomplished?

Dr. Jones: In 10 years, I hope that my efforts will have revolutionized our approach to delivering care to vulnerable populations. Much of the work that has been done thus far in the field of disparities and liver disease has focused on describing the inequities. However, I have just started working in health equity. This will require partnering with patients and caregivers to get a better understanding of their needs and collaborating with legislators to increase funding directed towards building the infrastructure necessary to deliver health care to those who have been forgotten.

Lightning round questions

Favorite movie, show, or book
Forrest Gump, Blackish, anything by Toni Morrison

Favorite music genre
Hip Hop

Favorite food
Seafood

Favorite travel destination
Tanzania

Your ideal type of pet
Dog

Optimist or pessimist?
Optimist!

Dr. Jones is on Twitter @DrLiverPatty.

This patient's clinical presentation is consistent with a diagnosis of metastatic invasive lobular carcinoma, with nodal involvement. 

Breast cancer is one of the most frequently diagnosed cancers worldwide. In Western countries, 1 in 8 women will be diagnosed with breast cancer at some point in their lives. Various histologic subtypes with specific clinical characteristics exist. Invasive lobular carcinoma (ILC) is the second most common subtype, accounting for an estimated 10%-15% of breast cancers. Over the past two decades, a significant increase has been observed in the incidence of ILC, particularly among postmenopausal women. Improved diagnostic techniques and the use of hormone replacement therapy may account for this increased incidence. White women have the highest incidence of ILC; however, compared with White women and women of other races, Black women experience the worst 5-year overall survival from ILC.

ILC arises in the mammary ducts (lobules) of the breast. Women with ILC are typically slightly older than women with invasive breast cancer of no special type at diagnosis (mean age 63.4 vs 59.5 years, respectively). Risk factors for ILC may include early menarche, use of progesterone-based hormone replacement therapy, late age at first live birth, and alcohol consumption. 

In most cases, ILC does not form a discrete palpable mass until it has reached an advanced stage, making it more difficult to detect through physical examination or imaging. Patients often present with a large tumor and with nodal involvement. A slight thickening of the nipple, an exudative scab on the skin, or other changes in the skin, such as flushing or swelling, may be seen in patients presenting with advanced disease. Additionally, ILC tumors are often bilateral and multifocal. 

ILC is predominantly a histopathologic diagnosis based on standard hematoxylin and eosin staining. Histologically, ILC is characterized by a proliferation of small cells that lack cohesion. These cells are often dispersed individually through a fibrous connective tissue; alternatively, they may be organized in single-file linear cords invading the stroma. A concentric pattern around normal ducts is often seen in the infiltrating cords. There is usually little host reaction of the background architecture. Round or notched ovoid nuclei are seen in the neoplastic cells, along with a thin rim of cytoplasm. Occasionally, an intracytoplasmic lumen is present and may harbor a central mucoid inclusion. Very few or no mitoses are seen.

Several variants of ILC exist, all of which lack cell-to-cell cohesion. These include:

•    Solid type
•    Pleomorphic lobular carcinoma
•    Tubulo-lobular variant
•    Alveolar variant
•    Mixed type

Complete loss of E-cadherin expression occurs in most ILCs, which can help to differentiate it from invasive ductal cancers or ductal carcinomas in situ. Diffuse cortical thickening without hilar mass effect is often seen in nodal metastases associated with ILC. 

Most classic ILCs are estrogen receptor– and progesterone receptor–positive. Conversely, HER2 overexpression and amplification rarely occurs in ILC. 

Late relapses more than 10 years after remission may occur. In addition to frequent bone and liver metastasis, ILC is associated with metastatic spread to unusual sites, including the peritoneum, gastrointestinal tract, urinary tract, leptomeninges, skin, orbit, and ovaries. 

Mastectomy is often indicated in ILC. In the neoadjuvant setting, ILC is associated with low pathologic complete response rates. Endocrine therapy in the neoadjuvant setting is an emerging approach for some patients with ILC. According to 2022 National Comprehensive Cancer Network guidelines, adjuvant chemotherapy followed by endocrine therapy or endocrine therapy alone should be considered for pre- and postmenopausal patients with ILC.

Avan J. Armaghani, MD, Assistant Member, Department of Breast Oncology, Moffitt Cancer Center, University of South Florida, Tampa, FL.
 
Avan J. Armaghani, MD, has disclosed no relevant financial relationships.

Image Quizzes are fictional or fictionalized clinical scenarios intended to provide evidence-based educational takeaways.

This patient's clinical presentation is consistent with a diagnosis of metastatic invasive lobular carcinoma, with nodal involvement. 

Breast cancer is one of the most frequently diagnosed cancers worldwide. In Western countries, 1 in 8 women will be diagnosed with breast cancer at some point in their lives. Various histologic subtypes with specific clinical characteristics exist. Invasive lobular carcinoma (ILC) is the second most common subtype, accounting for an estimated 10%-15% of breast cancers. Over the past two decades, a significant increase has been observed in the incidence of ILC, particularly among postmenopausal women. Improved diagnostic techniques and the use of hormone replacement therapy may account for this increased incidence. White women have the highest incidence of ILC; however, compared with White women and women of other races, Black women experience the worst 5-year overall survival from ILC.

ILC arises in the mammary ducts (lobules) of the breast. Women with ILC are typically slightly older than women with invasive breast cancer of no special type at diagnosis (mean age 63.4 vs 59.5 years, respectively). Risk factors for ILC may include early menarche, use of progesterone-based hormone replacement therapy, late age at first live birth, and alcohol consumption. 

In most cases, ILC does not form a discrete palpable mass until it has reached an advanced stage, making it more difficult to detect through physical examination or imaging. Patients often present with a large tumor and with nodal involvement. A slight thickening of the nipple, an exudative scab on the skin, or other changes in the skin, such as flushing or swelling, may be seen in patients presenting with advanced disease. Additionally, ILC tumors are often bilateral and multifocal. 

ILC is predominantly a histopathologic diagnosis based on standard hematoxylin and eosin staining. Histologically, ILC is characterized by a proliferation of small cells that lack cohesion. These cells are often dispersed individually through a fibrous connective tissue; alternatively, they may be organized in single-file linear cords invading the stroma. A concentric pattern around normal ducts is often seen in the infiltrating cords. There is usually little host reaction of the background architecture. Round or notched ovoid nuclei are seen in the neoplastic cells, along with a thin rim of cytoplasm. Occasionally, an intracytoplasmic lumen is present and may harbor a central mucoid inclusion. Very few or no mitoses are seen.

Several variants of ILC exist, all of which lack cell-to-cell cohesion. These include:

•    Solid type
•    Pleomorphic lobular carcinoma
•    Tubulo-lobular variant
•    Alveolar variant
•    Mixed type

Complete loss of E-cadherin expression occurs in most ILCs, which can help to differentiate it from invasive ductal cancers or ductal carcinomas in situ. Diffuse cortical thickening without hilar mass effect is often seen in nodal metastases associated with ILC. 

Most classic ILCs are estrogen receptor– and progesterone receptor–positive. Conversely, HER2 overexpression and amplification rarely occurs in ILC. 

Late relapses more than 10 years after remission may occur. In addition to frequent bone and liver metastasis, ILC is associated with metastatic spread to unusual sites, including the peritoneum, gastrointestinal tract, urinary tract, leptomeninges, skin, orbit, and ovaries. 

Mastectomy is often indicated in ILC. In the neoadjuvant setting, ILC is associated with low pathologic complete response rates. Endocrine therapy in the neoadjuvant setting is an emerging approach for some patients with ILC. According to 2022 National Comprehensive Cancer Network guidelines, adjuvant chemotherapy followed by endocrine therapy or endocrine therapy alone should be considered for pre- and postmenopausal patients with ILC.

Avan J. Armaghani, MD, Assistant Member, Department of Breast Oncology, Moffitt Cancer Center, University of South Florida, Tampa, FL.
 
Avan J. Armaghani, MD, has disclosed no relevant financial relationships.

Image Quizzes are fictional or fictionalized clinical scenarios intended to provide evidence-based educational takeaways.

This patient's clinical presentation is consistent with a diagnosis of metastatic invasive lobular carcinoma, with nodal involvement. 

Breast cancer is one of the most frequently diagnosed cancers worldwide. In Western countries, 1 in 8 women will be diagnosed with breast cancer at some point in their lives. Various histologic subtypes with specific clinical characteristics exist. Invasive lobular carcinoma (ILC) is the second most common subtype, accounting for an estimated 10%-15% of breast cancers. Over the past two decades, a significant increase has been observed in the incidence of ILC, particularly among postmenopausal women. Improved diagnostic techniques and the use of hormone replacement therapy may account for this increased incidence. White women have the highest incidence of ILC; however, compared with White women and women of other races, Black women experience the worst 5-year overall survival from ILC.

ILC arises in the mammary ducts (lobules) of the breast. Women with ILC are typically slightly older than women with invasive breast cancer of no special type at diagnosis (mean age 63.4 vs 59.5 years, respectively). Risk factors for ILC may include early menarche, use of progesterone-based hormone replacement therapy, late age at first live birth, and alcohol consumption. 

In most cases, ILC does not form a discrete palpable mass until it has reached an advanced stage, making it more difficult to detect through physical examination or imaging. Patients often present with a large tumor and with nodal involvement. A slight thickening of the nipple, an exudative scab on the skin, or other changes in the skin, such as flushing or swelling, may be seen in patients presenting with advanced disease. Additionally, ILC tumors are often bilateral and multifocal. 

ILC is predominantly a histopathologic diagnosis based on standard hematoxylin and eosin staining. Histologically, ILC is characterized by a proliferation of small cells that lack cohesion. These cells are often dispersed individually through a fibrous connective tissue; alternatively, they may be organized in single-file linear cords invading the stroma. A concentric pattern around normal ducts is often seen in the infiltrating cords. There is usually little host reaction of the background architecture. Round or notched ovoid nuclei are seen in the neoplastic cells, along with a thin rim of cytoplasm. Occasionally, an intracytoplasmic lumen is present and may harbor a central mucoid inclusion. Very few or no mitoses are seen.

Several variants of ILC exist, all of which lack cell-to-cell cohesion. These include:

•    Solid type
•    Pleomorphic lobular carcinoma
•    Tubulo-lobular variant
•    Alveolar variant
•    Mixed type

Complete loss of E-cadherin expression occurs in most ILCs, which can help to differentiate it from invasive ductal cancers or ductal carcinomas in situ. Diffuse cortical thickening without hilar mass effect is often seen in nodal metastases associated with ILC. 

Most classic ILCs are estrogen receptor– and progesterone receptor–positive. Conversely, HER2 overexpression and amplification rarely occurs in ILC. 

Late relapses more than 10 years after remission may occur. In addition to frequent bone and liver metastasis, ILC is associated with metastatic spread to unusual sites, including the peritoneum, gastrointestinal tract, urinary tract, leptomeninges, skin, orbit, and ovaries. 

Mastectomy is often indicated in ILC. In the neoadjuvant setting, ILC is associated with low pathologic complete response rates. Endocrine therapy in the neoadjuvant setting is an emerging approach for some patients with ILC. According to 2022 National Comprehensive Cancer Network guidelines, adjuvant chemotherapy followed by endocrine therapy or endocrine therapy alone should be considered for pre- and postmenopausal patients with ILC.

Avan J. Armaghani, MD, Assistant Member, Department of Breast Oncology, Moffitt Cancer Center, University of South Florida, Tampa, FL.
 
Avan J. Armaghani, MD, has disclosed no relevant financial relationships.

Image Quizzes are fictional or fictionalized clinical scenarios intended to provide evidence-based educational takeaways.

Contact dermatitis is a common problem in the floral bulb industry and is considered an occupational disease. Daffodils (Narcissus species)(Figure) are thought to be the most common cause of irritant contact dermatitis among florists.¹

Clinical Importance

Picking daffodils can start as early as October, when the flowers are still closed. The picker’s hand slides down the stem to snap the stalk at the base. This potentially traumatic maneuver to the web of the fingers leads to abrasions, which are irritated by the sap and cause granulomatous sores and paronychia. An experienced picker can pick 20,000 flowers a day, leading to extensive contact with sap.²

Eczematous or granulomatous rash on the arms also is seen as the sap irritates the wrist and forearm. The pickers often hold the flowers until a bunch of 10 has been collected. The 10 flowers are held together by a rubber band and stacked along the arm, the chin, and the axilla, causing the rash to extend to those areas. Sap also can be transferred by the hand to other parts of the body, such as the face. In men, sap can be transferred to the genitalia as the men urinate in the field.

Narcissus also can cause poisoning if ingested by humans or animals. Researchers who analyzed calls made to the New Zealand Natural Poisons Centre between 2003 and 2010 determined that daffodil was the 11th most common call for plant-related poisoning.³

Although the severity of plant poisoning often is low due to the small amount of plant material usually consumed, more severe poisoning can occur when the plant is eaten for medicinal purposes or mistaken for an edible plant.³ Vomiting, respiratory symptoms, abdominal pain, diarrhea, trembling, and convulsions can occur when daffodils are ingested. Death has been reported due to ingestion of the bulbs.⁴

In February 2010, 10 children aged 10 and 11 years and their 22-year-old guide presented to an emergency department in Israel after ingesting Narcissus bulbs, which were mistakenly believed to be the bulbs of onions.⁴ Eight children and the guide vomited. One child and the guide reported abdominal pain. All were discharged in stable condition after 4 hours of observation.⁴

Clinical Manifestations

Daffodil rash or lily rash was first described in 1910.⁵ The typical rash presents as dryness, fissures, scaling, and erythema of the fingertips, hands, and forearms, often with subungual hyperkeratosis. Vesicles and pustules may be seen. The rash may extend to other areas of the body, including the face.⁶

 

 

Prevention and Treatment

Use of protective gloves and clothing to avoid contact with the plant is recommended.² Treatment includes stopping contact with the irritant, eye irrigation, and supportive measures (airway, breathing, and circulation). Activated charcoal can be helpful if used within 1 hour after ingestion but is contraindicated in vomiting patients.⁴

Identifying Features

The genus Narcissus is in the family Amaryllidaceae and contains ornamental plants, including daffodil (trumpet Narcissus, Narcissus pseudonarcissus), jonquil (Narcissus jonquilla), and poet’s narcissus (Narcissus poeticus). Most species are perennial; the plant emerges from a bulb in spring. Leaves originate from the base of the plant and range from 5-cm to 1.2-meters long, depending on the species. The flowers span a range of shapes and colors—from a trumpet (the daffodil) to a ringlike cup (poet’s Narcissus) and in yellow, white, and pink.⁷

Distribution and Plant Facts

Distribution—There are approximately 80 to 100 wild Narcissus species, which are found in southwestern Europe, North Africa, the Balkan Peninsula, Italy, and France. There are more than 27,000 Narcissus cultivars registered in the International Daffodil Register.⁸

Plant Facts—The daffodil is the national flower of Wales. It also is often used to depict hope and joy and is the symbol of cancer charities in many countries.⁹

The name Narcissus is believed to have originated from Greek mythology. A handsome youth, Narcissus, fell in love with his own reflection, for which the gods punished him by turning him into a flower.¹⁰

Another theory states that Narcissus is derived from the Greek word narkao (to benumb) due to its narcotic properties. When an open wound is subjected to an extract of the bulb, numbness of the entire nervous system is said to occur as well as paralysis of the heart. This narcotic effect led Socrates to refer to the Narcissus plant as the “chaplet of the infernal gods.”¹¹

Narcissus is an important flower in various ethnic rituals. The Greeks often planted daffodils near tombs. In Muslim culture, white is believed to be the symbol of good and purity; Narcissus was one of the most common white-flowered plants found in Muslim graveyards.¹²

Medicinal Qualities and Uses—Narcissus species have been used as medicinal plants for a variety of ailments. For example, Narcissus tazetta contains flavonoids, alkaloids, saponins, tannins, cardiac glycosides, oil, steroids, terpenoids, and anthraquinones that contribute to its antibacterial, antifungal, antiviral, antimalarial, anticancer, antioxidant, dermatologic, cardiovascular, immunomodulatory, and acetylcholinesterase inhibitory effects.¹³ In a study, chloroform extracts from N tazetta bulbs were found to be more active than doxorubicin against hepatocellular and colon cancer cell lines.¹⁴

More than 500 alkaloids have been isolated from the Narcissus genus.¹⁵ In 2001, the US Food and Drug Administration approved one of the alkaloids, galantamine, for the treatment of mild to moderate stages of Alzheimer disease.¹⁶ Galantamine selectively and reversibly inhibits acetylcholinesterase, the enzyme believed responsible for neurodegeneration seen in Alzheimer disease. Plants are the main source of galantamine, despite the ability of pharmaceutical companies to synthesize the compound. Galantamine hydrobromide is sold by prescription (Razadyne [Janssen Pharmaceuticals, Inc]); generic formulations approved by the US Food and Drug Administration have been produced by more than 15 pharmaceutical companies.^17,18

Irritant and Allergen

Sap found in the bulbs and hollow stems of Narcissus contains calcium oxalate crystals, or raphides. The minute, needle-shaped calcium oxalate crystals are believed to be a waste product of cellular metabolism.¹⁹ When the plant structure is compromised by pickers snapping the stalk, the sharp crystals penetrate the skin to cause an irritant contact dermatitis.

Relevant Research—A study used electron microscopy to characterize the structure of raphides from various plants,² though not from Narcissus species; the structure of each raphide was then compared to the degree of irritation it produced. The researchers concluded that more elongated crystals (those containing barbs) produce a greater degree of irritation. Narcissus species are known to cause varying degrees of skin irritation: For example, N tazetta rarely causes skin irritation, whereas N pseudonarcissi (daffodil) tends to cause remarkably more skin irritation.²

Allergic reactions to and strong toxicity from Narcissus species are not well understood. In a study, only 2 alkaloids—homolycorine and masonin—produced a weakly positive reaction in patch tests on sensitized guinea pigs, which correlates with the finding of a different study, in which only 2 of 12 patients whose findings were examined over 14 years had a positive patch test for Narcissus.^20,21

However, IgE-mediated allergies indicative of an allergic response to Narcissus have been reported. A study isolated an allergenic protein, narcin, from bulbs of N tazetta. Narcin is a 13-kDa protein with potent allergenic effects capable of inducing production of proinflammatory cytokines and increasing IgE levels in mononuclear cells in peripheral blood.²²

More research is required to find and understand the compounds responsible for causing an allergic reaction to Narcissus.

Contact dermatitis is a common problem in the floral bulb industry and is considered an occupational disease. Daffodils (Narcissus species)(Figure) are thought to be the most common cause of irritant contact dermatitis among florists.¹

Clinical Importance

Picking daffodils can start as early as October, when the flowers are still closed. The picker’s hand slides down the stem to snap the stalk at the base. This potentially traumatic maneuver to the web of the fingers leads to abrasions, which are irritated by the sap and cause granulomatous sores and paronychia. An experienced picker can pick 20,000 flowers a day, leading to extensive contact with sap.²

Eczematous or granulomatous rash on the arms also is seen as the sap irritates the wrist and forearm. The pickers often hold the flowers until a bunch of 10 has been collected. The 10 flowers are held together by a rubber band and stacked along the arm, the chin, and the axilla, causing the rash to extend to those areas. Sap also can be transferred by the hand to other parts of the body, such as the face. In men, sap can be transferred to the genitalia as the men urinate in the field.

Narcissus also can cause poisoning if ingested by humans or animals. Researchers who analyzed calls made to the New Zealand Natural Poisons Centre between 2003 and 2010 determined that daffodil was the 11th most common call for plant-related poisoning.³

Although the severity of plant poisoning often is low due to the small amount of plant material usually consumed, more severe poisoning can occur when the plant is eaten for medicinal purposes or mistaken for an edible plant.³ Vomiting, respiratory symptoms, abdominal pain, diarrhea, trembling, and convulsions can occur when daffodils are ingested. Death has been reported due to ingestion of the bulbs.⁴

In February 2010, 10 children aged 10 and 11 years and their 22-year-old guide presented to an emergency department in Israel after ingesting Narcissus bulbs, which were mistakenly believed to be the bulbs of onions.⁴ Eight children and the guide vomited. One child and the guide reported abdominal pain. All were discharged in stable condition after 4 hours of observation.⁴

Clinical Manifestations

Daffodil rash or lily rash was first described in 1910.⁵ The typical rash presents as dryness, fissures, scaling, and erythema of the fingertips, hands, and forearms, often with subungual hyperkeratosis. Vesicles and pustules may be seen. The rash may extend to other areas of the body, including the face.⁶

 

 

Prevention and Treatment

Use of protective gloves and clothing to avoid contact with the plant is recommended.² Treatment includes stopping contact with the irritant, eye irrigation, and supportive measures (airway, breathing, and circulation). Activated charcoal can be helpful if used within 1 hour after ingestion but is contraindicated in vomiting patients.⁴

Identifying Features

The genus Narcissus is in the family Amaryllidaceae and contains ornamental plants, including daffodil (trumpet Narcissus, Narcissus pseudonarcissus), jonquil (Narcissus jonquilla), and poet’s narcissus (Narcissus poeticus). Most species are perennial; the plant emerges from a bulb in spring. Leaves originate from the base of the plant and range from 5-cm to 1.2-meters long, depending on the species. The flowers span a range of shapes and colors—from a trumpet (the daffodil) to a ringlike cup (poet’s Narcissus) and in yellow, white, and pink.⁷

Distribution and Plant Facts

Distribution—There are approximately 80 to 100 wild Narcissus species, which are found in southwestern Europe, North Africa, the Balkan Peninsula, Italy, and France. There are more than 27,000 Narcissus cultivars registered in the International Daffodil Register.⁸

Plant Facts—The daffodil is the national flower of Wales. It also is often used to depict hope and joy and is the symbol of cancer charities in many countries.⁹

The name Narcissus is believed to have originated from Greek mythology. A handsome youth, Narcissus, fell in love with his own reflection, for which the gods punished him by turning him into a flower.¹⁰

Another theory states that Narcissus is derived from the Greek word narkao (to benumb) due to its narcotic properties. When an open wound is subjected to an extract of the bulb, numbness of the entire nervous system is said to occur as well as paralysis of the heart. This narcotic effect led Socrates to refer to the Narcissus plant as the “chaplet of the infernal gods.”¹¹

Narcissus is an important flower in various ethnic rituals. The Greeks often planted daffodils near tombs. In Muslim culture, white is believed to be the symbol of good and purity; Narcissus was one of the most common white-flowered plants found in Muslim graveyards.¹²

Medicinal Qualities and Uses—Narcissus species have been used as medicinal plants for a variety of ailments. For example, Narcissus tazetta contains flavonoids, alkaloids, saponins, tannins, cardiac glycosides, oil, steroids, terpenoids, and anthraquinones that contribute to its antibacterial, antifungal, antiviral, antimalarial, anticancer, antioxidant, dermatologic, cardiovascular, immunomodulatory, and acetylcholinesterase inhibitory effects.¹³ In a study, chloroform extracts from N tazetta bulbs were found to be more active than doxorubicin against hepatocellular and colon cancer cell lines.¹⁴

More than 500 alkaloids have been isolated from the Narcissus genus.¹⁵ In 2001, the US Food and Drug Administration approved one of the alkaloids, galantamine, for the treatment of mild to moderate stages of Alzheimer disease.¹⁶ Galantamine selectively and reversibly inhibits acetylcholinesterase, the enzyme believed responsible for neurodegeneration seen in Alzheimer disease. Plants are the main source of galantamine, despite the ability of pharmaceutical companies to synthesize the compound. Galantamine hydrobromide is sold by prescription (Razadyne [Janssen Pharmaceuticals, Inc]); generic formulations approved by the US Food and Drug Administration have been produced by more than 15 pharmaceutical companies.^17,18

Irritant and Allergen

Sap found in the bulbs and hollow stems of Narcissus contains calcium oxalate crystals, or raphides. The minute, needle-shaped calcium oxalate crystals are believed to be a waste product of cellular metabolism.¹⁹ When the plant structure is compromised by pickers snapping the stalk, the sharp crystals penetrate the skin to cause an irritant contact dermatitis.

Relevant Research—A study used electron microscopy to characterize the structure of raphides from various plants,² though not from Narcissus species; the structure of each raphide was then compared to the degree of irritation it produced. The researchers concluded that more elongated crystals (those containing barbs) produce a greater degree of irritation. Narcissus species are known to cause varying degrees of skin irritation: For example, N tazetta rarely causes skin irritation, whereas N pseudonarcissi (daffodil) tends to cause remarkably more skin irritation.²

Allergic reactions to and strong toxicity from Narcissus species are not well understood. In a study, only 2 alkaloids—homolycorine and masonin—produced a weakly positive reaction in patch tests on sensitized guinea pigs, which correlates with the finding of a different study, in which only 2 of 12 patients whose findings were examined over 14 years had a positive patch test for Narcissus.^20,21

However, IgE-mediated allergies indicative of an allergic response to Narcissus have been reported. A study isolated an allergenic protein, narcin, from bulbs of N tazetta. Narcin is a 13-kDa protein with potent allergenic effects capable of inducing production of proinflammatory cytokines and increasing IgE levels in mononuclear cells in peripheral blood.²²

More research is required to find and understand the compounds responsible for causing an allergic reaction to Narcissus.

Contact dermatitis is a common problem in the floral bulb industry and is considered an occupational disease. Daffodils (Narcissus species)(Figure) are thought to be the most common cause of irritant contact dermatitis among florists.¹

Clinical Importance

Picking daffodils can start as early as October, when the flowers are still closed. The picker’s hand slides down the stem to snap the stalk at the base. This potentially traumatic maneuver to the web of the fingers leads to abrasions, which are irritated by the sap and cause granulomatous sores and paronychia. An experienced picker can pick 20,000 flowers a day, leading to extensive contact with sap.²

Eczematous or granulomatous rash on the arms also is seen as the sap irritates the wrist and forearm. The pickers often hold the flowers until a bunch of 10 has been collected. The 10 flowers are held together by a rubber band and stacked along the arm, the chin, and the axilla, causing the rash to extend to those areas. Sap also can be transferred by the hand to other parts of the body, such as the face. In men, sap can be transferred to the genitalia as the men urinate in the field.

Narcissus also can cause poisoning if ingested by humans or animals. Researchers who analyzed calls made to the New Zealand Natural Poisons Centre between 2003 and 2010 determined that daffodil was the 11th most common call for plant-related poisoning.³

Although the severity of plant poisoning often is low due to the small amount of plant material usually consumed, more severe poisoning can occur when the plant is eaten for medicinal purposes or mistaken for an edible plant.³ Vomiting, respiratory symptoms, abdominal pain, diarrhea, trembling, and convulsions can occur when daffodils are ingested. Death has been reported due to ingestion of the bulbs.⁴

In February 2010, 10 children aged 10 and 11 years and their 22-year-old guide presented to an emergency department in Israel after ingesting Narcissus bulbs, which were mistakenly believed to be the bulbs of onions.⁴ Eight children and the guide vomited. One child and the guide reported abdominal pain. All were discharged in stable condition after 4 hours of observation.⁴

Clinical Manifestations

Daffodil rash or lily rash was first described in 1910.⁵ The typical rash presents as dryness, fissures, scaling, and erythema of the fingertips, hands, and forearms, often with subungual hyperkeratosis. Vesicles and pustules may be seen. The rash may extend to other areas of the body, including the face.⁶

 

 

Prevention and Treatment

Use of protective gloves and clothing to avoid contact with the plant is recommended.² Treatment includes stopping contact with the irritant, eye irrigation, and supportive measures (airway, breathing, and circulation). Activated charcoal can be helpful if used within 1 hour after ingestion but is contraindicated in vomiting patients.⁴

Identifying Features

The genus Narcissus is in the family Amaryllidaceae and contains ornamental plants, including daffodil (trumpet Narcissus, Narcissus pseudonarcissus), jonquil (Narcissus jonquilla), and poet’s narcissus (Narcissus poeticus). Most species are perennial; the plant emerges from a bulb in spring. Leaves originate from the base of the plant and range from 5-cm to 1.2-meters long, depending on the species. The flowers span a range of shapes and colors—from a trumpet (the daffodil) to a ringlike cup (poet’s Narcissus) and in yellow, white, and pink.⁷

Distribution and Plant Facts

Distribution—There are approximately 80 to 100 wild Narcissus species, which are found in southwestern Europe, North Africa, the Balkan Peninsula, Italy, and France. There are more than 27,000 Narcissus cultivars registered in the International Daffodil Register.⁸

Plant Facts—The daffodil is the national flower of Wales. It also is often used to depict hope and joy and is the symbol of cancer charities in many countries.⁹

The name Narcissus is believed to have originated from Greek mythology. A handsome youth, Narcissus, fell in love with his own reflection, for which the gods punished him by turning him into a flower.¹⁰

Another theory states that Narcissus is derived from the Greek word narkao (to benumb) due to its narcotic properties. When an open wound is subjected to an extract of the bulb, numbness of the entire nervous system is said to occur as well as paralysis of the heart. This narcotic effect led Socrates to refer to the Narcissus plant as the “chaplet of the infernal gods.”¹¹

Narcissus is an important flower in various ethnic rituals. The Greeks often planted daffodils near tombs. In Muslim culture, white is believed to be the symbol of good and purity; Narcissus was one of the most common white-flowered plants found in Muslim graveyards.¹²

Medicinal Qualities and Uses—Narcissus species have been used as medicinal plants for a variety of ailments. For example, Narcissus tazetta contains flavonoids, alkaloids, saponins, tannins, cardiac glycosides, oil, steroids, terpenoids, and anthraquinones that contribute to its antibacterial, antifungal, antiviral, antimalarial, anticancer, antioxidant, dermatologic, cardiovascular, immunomodulatory, and acetylcholinesterase inhibitory effects.¹³ In a study, chloroform extracts from N tazetta bulbs were found to be more active than doxorubicin against hepatocellular and colon cancer cell lines.¹⁴

More than 500 alkaloids have been isolated from the Narcissus genus.¹⁵ In 2001, the US Food and Drug Administration approved one of the alkaloids, galantamine, for the treatment of mild to moderate stages of Alzheimer disease.¹⁶ Galantamine selectively and reversibly inhibits acetylcholinesterase, the enzyme believed responsible for neurodegeneration seen in Alzheimer disease. Plants are the main source of galantamine, despite the ability of pharmaceutical companies to synthesize the compound. Galantamine hydrobromide is sold by prescription (Razadyne [Janssen Pharmaceuticals, Inc]); generic formulations approved by the US Food and Drug Administration have been produced by more than 15 pharmaceutical companies.^17,18

Irritant and Allergen

Sap found in the bulbs and hollow stems of Narcissus contains calcium oxalate crystals, or raphides. The minute, needle-shaped calcium oxalate crystals are believed to be a waste product of cellular metabolism.¹⁹ When the plant structure is compromised by pickers snapping the stalk, the sharp crystals penetrate the skin to cause an irritant contact dermatitis.

Relevant Research—A study used electron microscopy to characterize the structure of raphides from various plants,² though not from Narcissus species; the structure of each raphide was then compared to the degree of irritation it produced. The researchers concluded that more elongated crystals (those containing barbs) produce a greater degree of irritation. Narcissus species are known to cause varying degrees of skin irritation: For example, N tazetta rarely causes skin irritation, whereas N pseudonarcissi (daffodil) tends to cause remarkably more skin irritation.²

Allergic reactions to and strong toxicity from Narcissus species are not well understood. In a study, only 2 alkaloids—homolycorine and masonin—produced a weakly positive reaction in patch tests on sensitized guinea pigs, which correlates with the finding of a different study, in which only 2 of 12 patients whose findings were examined over 14 years had a positive patch test for Narcissus.^20,21

However, IgE-mediated allergies indicative of an allergic response to Narcissus have been reported. A study isolated an allergenic protein, narcin, from bulbs of N tazetta. Narcin is a 13-kDa protein with potent allergenic effects capable of inducing production of proinflammatory cytokines and increasing IgE levels in mononuclear cells in peripheral blood.²²

More research is required to find and understand the compounds responsible for causing an allergic reaction to Narcissus.

Nonmelanoma skin cancer (NMSC) is the most common cancer in the United States, and cutaneous melanoma is projected to be the fifth most common form of cancer in 2022, with increasing incidence and high potential for mortality.^1-3 Estimates indicate that 35% to 45% of all cancers in White patients are cutaneous, with 4% to 5% occurring in Hispanic patients, 2% to 4% in Asian patients, and 1% to 2% in Black patients.⁴ Of the keratinocyte carcinomas, basal cell carcinoma (BCC) is the most prevalent, projected to affect approximately 33% to 39% of White males and 23% to 28% of White females in the United States during their lifetimes. Squamous cell carcinoma (SCC) is the second most common skin malignancy, with a lifetime risk of 9% to 14% for White males and 4% to 9% for White females in the United States.⁵ The incidence of melanoma continues to increase, with approximately 99,780 new cases expected in the United States in 2022.¹

UV-induced DNA damage plays a key role in the pathogenesis and development of various skin malignancies.⁶ UV radiation from sunlight or tanning devices causes photocarcinogenesis due to molecular and cellular effects, including the generation of reactive oxygen species, DNA damage due to the formation of cyclobutane pyrimidine dimers and pyrimidine-pyrimidone, melanogenesis, apoptosis, and the increased expression of harmful genes and proteins.⁶ The summation of this damage can result in skin malignancies, including NMSC and melanoma.^6,7 Dietary antioxidants theoretically help prevent oxidative reactions from occurring within the body, and it has been suggested that intake of dietary antioxidants may decrease DNA damage and prevent tumorigenesis secondary to UV radiation.⁸ Antioxidants exist naturally in the body but can be acquired exogenously. Investigators have studied dietary antioxidants in preventing skin cancer formation with promising results in the laboratory setting.^8-11 Recently, more robust human studies have been initiated to further delineate this relationship. We present clinical evidence of several frequently utilized antioxidant vitamins and their effects on melanoma and NMSC.

Antioxidants

Vitamin A—Vitamin A is a fat-soluble vitamin found in animal sources, including fish, liver, and eggs. Carotenoids, such as beta carotene, are provitamin A plant derivatives found in fruits and vegetables that are converted into biologically active retinol and retinoic acid.¹² Retinols play a key role in cellular growth and differentiation and are thought to be protective against skin cancer via the inactivation of free radicals and immunologic enhancement due to their antiproliferative, antioxidative, and antiapoptotic effects.^13-16 Animal studies have demonstrated this protective effect and the ability of retinoids to suppress carcinogenesis; however, human studies reveal conflicting results.^17,18

Greenberg et al¹⁹ investigated the use of beta carotene in preventing the formation of NMSC. Patients (N=1805) were randomized to receive 50 mg of beta carotene daily or placebo. Over a 5-year period, there was no significant reduction in the occurrence of NMSC (relative risk [RR], 1.05; 95% CI, 0.91-1.22).¹⁹ Frieling et al²⁰ conducted a similar randomized, double-blind, placebo-controlled trial investigating beta carotene for primary prevention of NMSC in 22,071 healthy male physicians. The study group received 50 mg of beta carotene every other day for 12 years’ duration, and there was no significant effect on the incidence of first NMSC development (RR, 0.98; 95% CI, 0.92-1.05).²⁰

A case-control study by Naldi et al²¹ found an inverse association between vitamin A intake and development of melanoma. Study participants were stratified into quartiles based on level of dietary intake and found an odds ratio (OR) of 0.71 for beta carotene (95% CI, 0.50-1.02), 0.57 for retinol (95% CI, 0.39-0.83), and 0.51 for total vitamin A (95% CI, 0.35-0.75) when comparing the upper quartile of vitamin A intake to the lower quartile. Upper-quartile cutoff values of vitamin A intake were 214 µg/d for beta carotene, 149 µg/d for retinol, and 359 µg/d for total vitamin A.²¹ More recently, a meta-analysis by Zhang et al²² pooled data from 8 case-control studies and 2 prospective studies. Intake of retinol but not total vitamin A or beta carotene was associated with a reduced risk for development of melanoma (retinol: OR, 0.80; 95% CI, 0.69-0.92; total vitamin A: OR, 0.86; 95% CI, 0.59-1.25; beta carotene: OR, 0.87; 95% CI, 0.62-1.20).²² Feskanich et al²³ demonstrated similar findings with use of food-frequency questionnaires in White women, suggesting that retinol intake from food combined with supplements may be protective for women who were otherwise at a low risk for melanoma based on nondietary factors. These factors included painful or blistering sunburns during childhood, history of more than 6 sunburns, more than 3 moles on the left arm, having red or blonde hair, and having a parent or sibling with melanoma (P=.01). However, this relationship did not hold true when looking at women at an intermediate or high risk for melanoma (P=.16 and P=.46).²³

When looking at high-risk patients, such as transplant patients, oral retinoids have been beneficial in preventing NMSC.^24-27 Bavinck et al²⁴ investigated 44 renal transplant patients with a history of more than 10 NMSCs treated with 30 mg of acitretin daily vs placebo. Patients receiving oral retinoid supplementation developed fewer NMSCs over a 6-month treatment period (P=.01).²⁴ Similarly, George et al²⁵ investigated acitretin in renal transplant patients and found a statistically significant decrease in number of SCCs in patients on supplementation (P=.002). Solomon-Cohen et al²⁶ performed a retrospective case-crossover study in solid organ transplant recipients and found that those treated with 10 mg of acitretin daily for 2 years had a significant reduction in the number of new keratinocyte carcinomas (P=.002). Other investigators have demonstrated similar results, and in 2006, Otley et al²⁷ proposed standardized dosing of acitretin for chemoprevention in high-risk patients, including patients developing 5 to 10 NMSCs per year, solid organ transplant recipients, and those with syndromes associated with the development of NMSC.^28,29 Overall, in the general population, vitamin A and related compounds have not demonstrated a significant association with decreased development of NMSC; however, oral retinoids have proven useful for high-risk patients. Furthermore, several studies have suggested a negative association between vitamin A levels and the incidence of melanoma, specifically in the retinol formulation. 

Vitamin B₃—Nicotinamide (also known as niacinamide) is a water-soluble form of vitamin B₃ and is obtained from animal-based and plant-based foods, such as meat, fish, and legumes.³⁰ Nicotinamide plays a key role in cellular metabolism, cellular signaling, and DNA repair, including protection from UV damage within keratinocytes.^31,32 Early mouse models demonstrated decreased formation of skin tumors in mice treated with topical or oral nicotinamide.^32,33 A number of human studies have revealed similar results.^34-36

Chen et al³⁴ conducted the ONTRAC study, a phase 3, double-blind, randomized controlled trial (RCT) looking at 386 participants with a history of at least 2 NMSCs in the preceding 5 years. At 12 months, those treated with 500 mg of nicotinamide twice daily demonstrated a statistically significant decreased rate of SCC formation (P=.05). A decreased incidence of BCC development was noted; however, this trend did not reach statistical significance (P=.12). Precancerous skin lesions also were found to be decreased in the treatment group, with 20% lower incidence of actinic keratoses (AKs) after 9 months of treatment (P<.001).³⁴ Drago et al³⁵ specifically studied the incidence of AKs in 38 transplant recipients—8 liver and 30 kidney—and found that previously noted AKs had decreased in size for 18 of 19 patients taking 500 mg of nicotinamide daily when originally photographed AKs were remeasured at 6-month follow-up, with 7 of these 18 patients demonstrating complete clinical regression. Of those on nicotinamide supplementation, no new AKs developed compared to the control group, which demonstrated increased size of AKs or development of new AKs in 91% of patients, with 7 AKs progressing into SCC.³⁵

Nicotinamide has been demonstrated to be useful in preventing skin cancer in high-risk populations, such as transplant patients or those with a high incidence of NMSC.^34,36 Despite promising results within the laboratory setting, nicotinamide’s effects on melanoma in humans remains less clear.^31,37 Studies suggest that nicotinamide enhances tumor-infiltrating lymphocytes and DNA repair mechanisms in melanocytes, which may translate into nicotinamide, providing chemoprevention for melanoma, but research in human patients is limited.^31,37

Vitamin B₉—Folate, the natural form of vitamin B₉, is a water-soluble compound that is found in many foods, especially green leafy vegetables, and often is supplemented because of its health benefits.^38,39 In the skin, folic acid plays a key role in cellular replication and proliferation.³⁸ Controversy exists regarding folate’s effects on cellular growth and turnover with respect to cancer incidence.^38,40 Donnenfeld et al⁴¹ conducted a prospective study assessing dietary folic acid intake and development of NMSC. A total of 5880 participants completed dietary records throughout the first 2 years of the study. After an average follow-up period of 12.6 years, there was an overall increased incidence of skin cancer in those with increased dietary folate (P=.03). Furthermore, when striating by skin cancer type, there was an increased incidence of NMSC overall as well as BCC when analyzing by type of NMSC (P=.03 for NMSC; P=.05 for BCC). However, when stratifying by gender, these findings only held true for women.⁴¹ Similar effects were observed by Fung et al,⁴² who prospectively studied the intake of various vitamins in relationship to the development of BCC in women. During 12 years of follow-up, a positive association was observed between folate intake and BCC development (OR, 1.2; 95% CI, 1.10-1.31).⁴² Fung et al⁴³ also investigated the role of several vitamins in the development of SCC and found that folate showed a negative association, which did not reach statistical significance (RR, 0.79; 95% CI, 0.56-1.11). Furthermore, Vollset et al⁴⁰ conducted a meta-analysis comparing folic acid to placebo in the incidence of various types of cancer. The study excluded NMSC but reported no significant association between the development of melanoma and folic acid supplementation.⁴⁰ In summary, the effects of folate have diverse consequences, potentially promoting the formation of NMSC, but studies suggest that an individual’s gender and other genetic and environmental factors also may play a role.

Vitamin C—Vitamin C (also known as ascorbic acid) is a water-soluble vitamin with antioxidant immune-mediating effects. It is found in various fruits and vegetables and serves as a cofactor for enzymes within the body playing a key role in immune function and collagen formation.^44,45 It has been postulated that ascorbic acid can provide protection from UV radiation damage via its intracellular activity but conversely can contribute to oxidative damage.⁴⁴ Multiple in vitro laboratory studies and animal models have demonstrated photoprotective effects of ascorbic acid.^46-48 Despite these findings, minimal photoprotective effects have been found in the human population.

Kune et al⁴⁹ performed a case-control study of 88 males with previously diagnosed NMSC undergoing surgical removal and investigated patients’ prior dietary habits. Patients with NMSC had a statistically significantly lower level of vitamin C–containing food in their diet than those without NMSC (P=.004).⁴⁹ In addition, Vural et al⁵⁰ analyzed plasma samples and blood cells of patients with AK and BCC and found a significant decrease in ascorbic acid levels in both the AK (P<.001) and BCC (P<.001) groups compared with controls. However, studies have found that consumption of certain dietary compounds can rapidly increase plasma concentration levels, which may serve as a major confounding variable in this study. Plasma concentrations of ascorbic acid and beta carotene were found to be significantly increased following consumption of a high-antioxidant diet for as short a duration as 2 weeks (P<.05).⁵¹ More recently, Heinen et al⁵² performed a prospective study on 1001 adults. In patients without a history of skin cancer, they found that vitamin C from food sources plus dietary supplements was positively associated with the development of BCC (P=.03).⁵² Similarly, Fung et al⁴² performed a study in women and found a positive association between vitamin C intake and the development of BCC (OR, 1.13; 95% CI, 1.03-1.23).

The relationship between vitamin C intake—either in dietary or supplemental form—and melanoma remains controversial. Mice-based studies found that high concentrations of orally administered vitamin C induce cytotoxicity in melanoma cell lines, but at low concentrations they promote tumor growth of malignant melanoma.⁵³ Feskanich et al²³ examined the relationship between vitamin C intake and melanoma development via food frequency questionnaires in White women and found that vitamin C was associated with a higher risk for melanoma (P=.05), and furthermore, a positive dose response with frequency of orange juice intake was observed (P=.008). Overall, despite promising laboratory studies, there is a lack of RCTs investigating the use of vitamin C supplementation for prevention of NMSC and melanoma in humans, and the oral benefits of vitamin C for chemoprevention remain unclear.

Vitamin D—Vitamin D is a fat-soluble vitamin that is found in fish, liver, egg, and cheese, and is endogenously produced when UV radiation from sun exposure interacts with the skin, triggering the synthesis of vitamin D.⁵⁴ Vitamin D is biologically inactive and must be converted to its active form 1,25-dihydroxyvitamin D after entering the body. Vitamin D modulates many genes involved in cellular proliferation and differentiation.⁵⁴ Vitamin D receptors are expressed on keratinocytes and melanocytes.⁵⁵ Animal studies have demonstrated a potentially protective effect of vitamin D in the development of NMSC.⁵⁶ In a mouse model, Ellison et al⁵⁶ found that mice without vitamin D receptors developed skin tumors more rapidly than those with vitamin D receptors.

Unfortunately, these findings have not been demonstrated in humans, and studies have even reported an increased risk for development of NMSC in patients with normal or increased vitamin D levels compared with those with low levels of vitamin D.^57-60 Eide et al⁵⁷ studied 3223 patients seeking advice for low bone density by recording their vitamin D levels at the time of presentation and monitoring development of NMSC. Vitamin D levels greater than 15 ng/mL were positively associated with the development of NMSC (OR, 1.7; 95% CI, 1.04-2.7). This association held true for both SCC and BCC, with a higher risk estimated for SCC (OR, 3.2; 95% CI, 0.4-24.0 for SCC; OR, 1.7; 95% CI, 0.5-5.8 for BCC).⁵⁷ An increased vitamin D serum level also was found to be significantly associated with a higher risk for BCC and melanoma by van der Pols et al.⁵⁸ This prospective study looked at the incidence of skin cancer over 11 years. Study participants with vitamin D levels over 75 nmol/L more frequently developed BCC (P=.01) and melanoma (P=.05). In contrast, SCC was less frequently observed in participants with these high levels of vitamin D (P=.07).⁵⁸ Furthermore, Park et al⁶⁰ looked at vitamin D and skin cancer risk for men and women in the United States and found no association with risk for SCC or melanoma but a positive association with BCC (P=.05 for total vitamin D; P<.01 for dietary vitamin D). Additional studies have been performed with inconsistent results, and multiple authors suggest the possible confounding relationship between vitamin D levels and UV radiation exposure.^59-62 Furthermore, some studies have even demonstrated a negative association between vitamin D and NMSC. Tang et al⁶³ performed a retrospective case-control study in elderly males, investigating serum levels of vitamin D and patients’ self-reported history of NMSC, which demonstrated that higher levels of vitamin D were associated with a decreased risk for NMSC. Overall, the relationship between vitamin D and skin cancer development remains unclear for both melanoma and NMSC.

Vitamin E—Vitamin E is a fat-soluble vitamin that is found in plant-based oils, nuts, seeds, fruits, and vegetables.⁶⁴ It works as an antioxidant to protect against free radicals and heighten immune function, and it also serves as a pro-oxidant.^65,66 Vitamin E naturally exists in 8 chemical forms, of which gamma-tocopherol is the most frequently obtained form in the diet, and alpha-tocopherol is the most abundant form found in the body.^64,65

Early animal studies demonstrated the inhibition of UV-induced damage in mice receiving vitamin E supplementation.^67,68 Human studies have not consistently shown these effects. Vural et al⁵⁰ investigated plasma samples and blood cells of patients with AKs and BCCs and reported a significant decrease in alpha-tocopherol levels in both the AK (P<.05) and BCC (P<.001) groups compared with controls. However, studies also have demonstrated a positive association between vitamin E intake and the development of BCC, including one by Fung et al,⁴² which found a significant association in women (OR, 1.15; 95% CI, 1.06-1.26).

Vitamin E has been found to inhibit melanin synthesis in the laboratory, suggesting a potentially protective effect in melanoma.^69,70 However, in the study performed by Feskanich et al²³ examining vitamin intake and melanoma incidence via food-frequency questionnaires, vitamin E was not associated with a lower risk for melanoma. Despite promising laboratory studies, the data surrounding the use of a vitamin E supplement for prevention of melanoma and NMSC in humans remains unclear.

Selenium—Selenium is a trace mineral found in plants, meat, and fish. It plays a key role in reproduction, hormone metabolism, DNA synthesis, and protection from oxidative damage.⁷¹ In mice studies, lack of selenium-containing proteins resulted in skin abnormalities, including the development of a hyperplastic epidermis and aberrant hair follicle morphogenesis with alopecia after birth, and numerous experimental studies have demonstrated a negative association between selenium intake and cancer.^72,73 However, human studies have yielded alternative results. 

The Nutritional Prevention of Cancer Study Group analyzed 1312 dermatology patients with a history of NMSC.⁷⁴ The study population was obtained from 7 dermatology clinics with randomization to control for confounding variables. Study participants received either 200 μg of selenium daily or placebo.⁷⁴ Baseline characteristics of each study group were overall balanced. Selenium intake was found to have no effect on the development of BCC (hazard ratio [HR], 1.09; 95% CI, 0.94-1.26) but an increased risk for developing SCC (HR, 1.25; 95% CI, 1.03-1.51) and total NMSC (HR, 1.17; 95% CI, 1.02-1.34).^74,75 Similarly, Reid et al⁷⁶ performed an RCT comparing patients treated with 400 μg/d of selenium to those treated with 200 μg/d of selenium. When compared with placebo, those treated with 200 μg/d of selenium had a statistically significantly increased incidence of NMSC (P=.006); however, those treated with 400 μg/d of selenium had no significant change in total incidence of NMSC (P=.51).⁷⁶ Furthermore, Vinceti et al⁷⁷ performed a review of 83 studies from the literature investigating the effect of dietary selenium, and from the RCTs, there was no beneficial effect of selenium in reducing cancer risk in general; however, some studies demonstrated an increased incidence of other types of cancer, including melanoma. Of the RCTs included in the study investigating NMSC incidence specifically, it was found that the incidence was not affected by selenium administration (RR, 1.16; 95% CI, 0.30-4.42; 2 studies, 2027 participants).⁷⁷ Despite data from several studies demonstrating an increased risk for NMSC, the effects of selenium on the risk for NMSC and melanoma remain unclear. 

Combination Antioxidant Studies

In addition to investigating the use of single antioxidants in skin cancer prevention, studies utilizing the combination of various antioxidants or other dietary minerals have been conducted. Hercberg et al⁷⁸ performed a randomized, double-blinded, placebo-controlled trial of 13,017 adults (7876 women and 5141 men) receiving a combination of 120 mg vitamin C, 30 mg vitamin E, 100 μg selenium, 6 mg beta carotene, and 20 mg zinc. Study participants were followed for an average of 7.5 years, and the development of skin cancers were recorded. Overall, the incidence rate of skin cancer did not differ between the 2 treatment groups; however, when segregated by gender, the study found that there was an increased risk for developing skin cancer in women taking the antioxidant supplement combination compared with placebo (P=.03). This difference was not observed in the 2 treatment groups of male patients (P=.11). When looking specifically at NMSC, there was no difference between treatment groups for male or female patients (P=.39 for males; P=.15 for females). In contrast, there was a higher incidence of melanoma identified in female patients taking the combination antioxidant supplement (P=.01), but this was not seen within the male study population (P=.51).⁷⁸ In addition, Chang et al⁷⁹ performed a meta-analysis of 10 previously published RCTs. Analysis revealed that treatment with a variety of supplements, including vitamins A, C, E, and beta carotene, were found to have no preventative effects on the incidence of skin cancer development (RR, 0.98; CI, 0.98-1.03). Notable limitations to this study included the variability in protocols of the studies included in this meta-analysis, the limited number of RCTs investigating vitamin supplementation and the risk for skin cancer development, and the influence of dietary intake on study outcomes.⁷⁹

Other Dietary Agents

Furocoumarins—Furocoumarins are botanical substances found in various fruits and plants, including many citrus products. Furocoumarins are activated by UV light radiation and can lead to development of a phototoxic eruption. Several studies have suggested a pharmacogenetic effect of furocoumarins.⁸⁰ Sun et al⁸⁰ collected dietary data from 47,453 men and 75,291 women on furocoumarin intake and correlation with the development of NMSC. Overall, the study suggested that the intake of furocoumarins may lead to an increase in the development of BCC (HR, 1.16; 95% CI, 1.11-1.21; P=.002); however, there was no significant association identified between total intake of furocoumarins in the risk for SCC or melanoma.⁸⁰ Furthermore, Sakaki et al⁸¹ conducted a survey study looking at the consumption of citrus products and the development of NMSC. The group found that there was an increased risk for NMSC in those consuming an increased amount of citrus products (P=.007).⁸¹

Conclusion

Dietary antioxidants have been investigated for their potential role in the prevention of tumorigenesis. Specific antioxidant vitamins, such as vitamin A derivatives and niacinamide, have demonstrated clinical utility in the prevention of NMSC in high-risk populations. Retinol also has been associated with a reduced incidence of melanoma. Numerous antioxidants have demonstrated promising data within the laboratory setting; however, inconsistent results have been appreciated in humans. Furthermore, several research studies suggest that folate, vitamin D, and furocoumarins may be associated with an increased risk for skin cancer development; however, these studies are inconclusive, and dietary studies are challenging to conduct. Overall, RCTs investigating the role of antioxidants for chemoprevention are limited. Moreover, the study of dietary antioxidants and vitamins may be affected by various confounding variables that can be difficult to account for because of patients’ potentially poor recall of dietary intake and the effect of dietary intake in supplemental studies. Given the increasing prevalence of skin cancer worldwide, further research into the clinical utility of antioxidants in skin cancer prevention is warranted. 

Nonmelanoma skin cancer (NMSC) is the most common cancer in the United States, and cutaneous melanoma is projected to be the fifth most common form of cancer in 2022, with increasing incidence and high potential for mortality.^1-3 Estimates indicate that 35% to 45% of all cancers in White patients are cutaneous, with 4% to 5% occurring in Hispanic patients, 2% to 4% in Asian patients, and 1% to 2% in Black patients.⁴ Of the keratinocyte carcinomas, basal cell carcinoma (BCC) is the most prevalent, projected to affect approximately 33% to 39% of White males and 23% to 28% of White females in the United States during their lifetimes. Squamous cell carcinoma (SCC) is the second most common skin malignancy, with a lifetime risk of 9% to 14% for White males and 4% to 9% for White females in the United States.⁵ The incidence of melanoma continues to increase, with approximately 99,780 new cases expected in the United States in 2022.¹

UV-induced DNA damage plays a key role in the pathogenesis and development of various skin malignancies.⁶ UV radiation from sunlight or tanning devices causes photocarcinogenesis due to molecular and cellular effects, including the generation of reactive oxygen species, DNA damage due to the formation of cyclobutane pyrimidine dimers and pyrimidine-pyrimidone, melanogenesis, apoptosis, and the increased expression of harmful genes and proteins.⁶ The summation of this damage can result in skin malignancies, including NMSC and melanoma.^6,7 Dietary antioxidants theoretically help prevent oxidative reactions from occurring within the body, and it has been suggested that intake of dietary antioxidants may decrease DNA damage and prevent tumorigenesis secondary to UV radiation.⁸ Antioxidants exist naturally in the body but can be acquired exogenously. Investigators have studied dietary antioxidants in preventing skin cancer formation with promising results in the laboratory setting.^8-11 Recently, more robust human studies have been initiated to further delineate this relationship. We present clinical evidence of several frequently utilized antioxidant vitamins and their effects on melanoma and NMSC.

Antioxidants

Vitamin A—Vitamin A is a fat-soluble vitamin found in animal sources, including fish, liver, and eggs. Carotenoids, such as beta carotene, are provitamin A plant derivatives found in fruits and vegetables that are converted into biologically active retinol and retinoic acid.¹² Retinols play a key role in cellular growth and differentiation and are thought to be protective against skin cancer via the inactivation of free radicals and immunologic enhancement due to their antiproliferative, antioxidative, and antiapoptotic effects.^13-16 Animal studies have demonstrated this protective effect and the ability of retinoids to suppress carcinogenesis; however, human studies reveal conflicting results.^17,18

Greenberg et al¹⁹ investigated the use of beta carotene in preventing the formation of NMSC. Patients (N=1805) were randomized to receive 50 mg of beta carotene daily or placebo. Over a 5-year period, there was no significant reduction in the occurrence of NMSC (relative risk [RR], 1.05; 95% CI, 0.91-1.22).¹⁹ Frieling et al²⁰ conducted a similar randomized, double-blind, placebo-controlled trial investigating beta carotene for primary prevention of NMSC in 22,071 healthy male physicians. The study group received 50 mg of beta carotene every other day for 12 years’ duration, and there was no significant effect on the incidence of first NMSC development (RR, 0.98; 95% CI, 0.92-1.05).²⁰

A case-control study by Naldi et al²¹ found an inverse association between vitamin A intake and development of melanoma. Study participants were stratified into quartiles based on level of dietary intake and found an odds ratio (OR) of 0.71 for beta carotene (95% CI, 0.50-1.02), 0.57 for retinol (95% CI, 0.39-0.83), and 0.51 for total vitamin A (95% CI, 0.35-0.75) when comparing the upper quartile of vitamin A intake to the lower quartile. Upper-quartile cutoff values of vitamin A intake were 214 µg/d for beta carotene, 149 µg/d for retinol, and 359 µg/d for total vitamin A.²¹ More recently, a meta-analysis by Zhang et al²² pooled data from 8 case-control studies and 2 prospective studies. Intake of retinol but not total vitamin A or beta carotene was associated with a reduced risk for development of melanoma (retinol: OR, 0.80; 95% CI, 0.69-0.92; total vitamin A: OR, 0.86; 95% CI, 0.59-1.25; beta carotene: OR, 0.87; 95% CI, 0.62-1.20).²² Feskanich et al²³ demonstrated similar findings with use of food-frequency questionnaires in White women, suggesting that retinol intake from food combined with supplements may be protective for women who were otherwise at a low risk for melanoma based on nondietary factors. These factors included painful or blistering sunburns during childhood, history of more than 6 sunburns, more than 3 moles on the left arm, having red or blonde hair, and having a parent or sibling with melanoma (P=.01). However, this relationship did not hold true when looking at women at an intermediate or high risk for melanoma (P=.16 and P=.46).²³

When looking at high-risk patients, such as transplant patients, oral retinoids have been beneficial in preventing NMSC.^24-27 Bavinck et al²⁴ investigated 44 renal transplant patients with a history of more than 10 NMSCs treated with 30 mg of acitretin daily vs placebo. Patients receiving oral retinoid supplementation developed fewer NMSCs over a 6-month treatment period (P=.01).²⁴ Similarly, George et al²⁵ investigated acitretin in renal transplant patients and found a statistically significant decrease in number of SCCs in patients on supplementation (P=.002). Solomon-Cohen et al²⁶ performed a retrospective case-crossover study in solid organ transplant recipients and found that those treated with 10 mg of acitretin daily for 2 years had a significant reduction in the number of new keratinocyte carcinomas (P=.002). Other investigators have demonstrated similar results, and in 2006, Otley et al²⁷ proposed standardized dosing of acitretin for chemoprevention in high-risk patients, including patients developing 5 to 10 NMSCs per year, solid organ transplant recipients, and those with syndromes associated with the development of NMSC.^28,29 Overall, in the general population, vitamin A and related compounds have not demonstrated a significant association with decreased development of NMSC; however, oral retinoids have proven useful for high-risk patients. Furthermore, several studies have suggested a negative association between vitamin A levels and the incidence of melanoma, specifically in the retinol formulation. 

Vitamin B₃—Nicotinamide (also known as niacinamide) is a water-soluble form of vitamin B₃ and is obtained from animal-based and plant-based foods, such as meat, fish, and legumes.³⁰ Nicotinamide plays a key role in cellular metabolism, cellular signaling, and DNA repair, including protection from UV damage within keratinocytes.^31,32 Early mouse models demonstrated decreased formation of skin tumors in mice treated with topical or oral nicotinamide.^32,33 A number of human studies have revealed similar results.^34-36

Chen et al³⁴ conducted the ONTRAC study, a phase 3, double-blind, randomized controlled trial (RCT) looking at 386 participants with a history of at least 2 NMSCs in the preceding 5 years. At 12 months, those treated with 500 mg of nicotinamide twice daily demonstrated a statistically significant decreased rate of SCC formation (P=.05). A decreased incidence of BCC development was noted; however, this trend did not reach statistical significance (P=.12). Precancerous skin lesions also were found to be decreased in the treatment group, with 20% lower incidence of actinic keratoses (AKs) after 9 months of treatment (P<.001).³⁴ Drago et al³⁵ specifically studied the incidence of AKs in 38 transplant recipients—8 liver and 30 kidney—and found that previously noted AKs had decreased in size for 18 of 19 patients taking 500 mg of nicotinamide daily when originally photographed AKs were remeasured at 6-month follow-up, with 7 of these 18 patients demonstrating complete clinical regression. Of those on nicotinamide supplementation, no new AKs developed compared to the control group, which demonstrated increased size of AKs or development of new AKs in 91% of patients, with 7 AKs progressing into SCC.³⁵

Nicotinamide has been demonstrated to be useful in preventing skin cancer in high-risk populations, such as transplant patients or those with a high incidence of NMSC.^34,36 Despite promising results within the laboratory setting, nicotinamide’s effects on melanoma in humans remains less clear.^31,37 Studies suggest that nicotinamide enhances tumor-infiltrating lymphocytes and DNA repair mechanisms in melanocytes, which may translate into nicotinamide, providing chemoprevention for melanoma, but research in human patients is limited.^31,37

Vitamin B₉—Folate, the natural form of vitamin B₉, is a water-soluble compound that is found in many foods, especially green leafy vegetables, and often is supplemented because of its health benefits.^38,39 In the skin, folic acid plays a key role in cellular replication and proliferation.³⁸ Controversy exists regarding folate’s effects on cellular growth and turnover with respect to cancer incidence.^38,40 Donnenfeld et al⁴¹ conducted a prospective study assessing dietary folic acid intake and development of NMSC. A total of 5880 participants completed dietary records throughout the first 2 years of the study. After an average follow-up period of 12.6 years, there was an overall increased incidence of skin cancer in those with increased dietary folate (P=.03). Furthermore, when striating by skin cancer type, there was an increased incidence of NMSC overall as well as BCC when analyzing by type of NMSC (P=.03 for NMSC; P=.05 for BCC). However, when stratifying by gender, these findings only held true for women.⁴¹ Similar effects were observed by Fung et al,⁴² who prospectively studied the intake of various vitamins in relationship to the development of BCC in women. During 12 years of follow-up, a positive association was observed between folate intake and BCC development (OR, 1.2; 95% CI, 1.10-1.31).⁴² Fung et al⁴³ also investigated the role of several vitamins in the development of SCC and found that folate showed a negative association, which did not reach statistical significance (RR, 0.79; 95% CI, 0.56-1.11). Furthermore, Vollset et al⁴⁰ conducted a meta-analysis comparing folic acid to placebo in the incidence of various types of cancer. The study excluded NMSC but reported no significant association between the development of melanoma and folic acid supplementation.⁴⁰ In summary, the effects of folate have diverse consequences, potentially promoting the formation of NMSC, but studies suggest that an individual’s gender and other genetic and environmental factors also may play a role.

Vitamin C—Vitamin C (also known as ascorbic acid) is a water-soluble vitamin with antioxidant immune-mediating effects. It is found in various fruits and vegetables and serves as a cofactor for enzymes within the body playing a key role in immune function and collagen formation.^44,45 It has been postulated that ascorbic acid can provide protection from UV radiation damage via its intracellular activity but conversely can contribute to oxidative damage.⁴⁴ Multiple in vitro laboratory studies and animal models have demonstrated photoprotective effects of ascorbic acid.^46-48 Despite these findings, minimal photoprotective effects have been found in the human population.

Kune et al⁴⁹ performed a case-control study of 88 males with previously diagnosed NMSC undergoing surgical removal and investigated patients’ prior dietary habits. Patients with NMSC had a statistically significantly lower level of vitamin C–containing food in their diet than those without NMSC (P=.004).⁴⁹ In addition, Vural et al⁵⁰ analyzed plasma samples and blood cells of patients with AK and BCC and found a significant decrease in ascorbic acid levels in both the AK (P<.001) and BCC (P<.001) groups compared with controls. However, studies have found that consumption of certain dietary compounds can rapidly increase plasma concentration levels, which may serve as a major confounding variable in this study. Plasma concentrations of ascorbic acid and beta carotene were found to be significantly increased following consumption of a high-antioxidant diet for as short a duration as 2 weeks (P<.05).⁵¹ More recently, Heinen et al⁵² performed a prospective study on 1001 adults. In patients without a history of skin cancer, they found that vitamin C from food sources plus dietary supplements was positively associated with the development of BCC (P=.03).⁵² Similarly, Fung et al⁴² performed a study in women and found a positive association between vitamin C intake and the development of BCC (OR, 1.13; 95% CI, 1.03-1.23).

The relationship between vitamin C intake—either in dietary or supplemental form—and melanoma remains controversial. Mice-based studies found that high concentrations of orally administered vitamin C induce cytotoxicity in melanoma cell lines, but at low concentrations they promote tumor growth of malignant melanoma.⁵³ Feskanich et al²³ examined the relationship between vitamin C intake and melanoma development via food frequency questionnaires in White women and found that vitamin C was associated with a higher risk for melanoma (P=.05), and furthermore, a positive dose response with frequency of orange juice intake was observed (P=.008). Overall, despite promising laboratory studies, there is a lack of RCTs investigating the use of vitamin C supplementation for prevention of NMSC and melanoma in humans, and the oral benefits of vitamin C for chemoprevention remain unclear.

Vitamin D—Vitamin D is a fat-soluble vitamin that is found in fish, liver, egg, and cheese, and is endogenously produced when UV radiation from sun exposure interacts with the skin, triggering the synthesis of vitamin D.⁵⁴ Vitamin D is biologically inactive and must be converted to its active form 1,25-dihydroxyvitamin D after entering the body. Vitamin D modulates many genes involved in cellular proliferation and differentiation.⁵⁴ Vitamin D receptors are expressed on keratinocytes and melanocytes.⁵⁵ Animal studies have demonstrated a potentially protective effect of vitamin D in the development of NMSC.⁵⁶ In a mouse model, Ellison et al⁵⁶ found that mice without vitamin D receptors developed skin tumors more rapidly than those with vitamin D receptors.

Unfortunately, these findings have not been demonstrated in humans, and studies have even reported an increased risk for development of NMSC in patients with normal or increased vitamin D levels compared with those with low levels of vitamin D.^57-60 Eide et al⁵⁷ studied 3223 patients seeking advice for low bone density by recording their vitamin D levels at the time of presentation and monitoring development of NMSC. Vitamin D levels greater than 15 ng/mL were positively associated with the development of NMSC (OR, 1.7; 95% CI, 1.04-2.7). This association held true for both SCC and BCC, with a higher risk estimated for SCC (OR, 3.2; 95% CI, 0.4-24.0 for SCC; OR, 1.7; 95% CI, 0.5-5.8 for BCC).⁵⁷ An increased vitamin D serum level also was found to be significantly associated with a higher risk for BCC and melanoma by van der Pols et al.⁵⁸ This prospective study looked at the incidence of skin cancer over 11 years. Study participants with vitamin D levels over 75 nmol/L more frequently developed BCC (P=.01) and melanoma (P=.05). In contrast, SCC was less frequently observed in participants with these high levels of vitamin D (P=.07).⁵⁸ Furthermore, Park et al⁶⁰ looked at vitamin D and skin cancer risk for men and women in the United States and found no association with risk for SCC or melanoma but a positive association with BCC (P=.05 for total vitamin D; P<.01 for dietary vitamin D). Additional studies have been performed with inconsistent results, and multiple authors suggest the possible confounding relationship between vitamin D levels and UV radiation exposure.^59-62 Furthermore, some studies have even demonstrated a negative association between vitamin D and NMSC. Tang et al⁶³ performed a retrospective case-control study in elderly males, investigating serum levels of vitamin D and patients’ self-reported history of NMSC, which demonstrated that higher levels of vitamin D were associated with a decreased risk for NMSC. Overall, the relationship between vitamin D and skin cancer development remains unclear for both melanoma and NMSC.

Vitamin E—Vitamin E is a fat-soluble vitamin that is found in plant-based oils, nuts, seeds, fruits, and vegetables.⁶⁴ It works as an antioxidant to protect against free radicals and heighten immune function, and it also serves as a pro-oxidant.^65,66 Vitamin E naturally exists in 8 chemical forms, of which gamma-tocopherol is the most frequently obtained form in the diet, and alpha-tocopherol is the most abundant form found in the body.^64,65

Early animal studies demonstrated the inhibition of UV-induced damage in mice receiving vitamin E supplementation.^67,68 Human studies have not consistently shown these effects. Vural et al⁵⁰ investigated plasma samples and blood cells of patients with AKs and BCCs and reported a significant decrease in alpha-tocopherol levels in both the AK (P<.05) and BCC (P<.001) groups compared with controls. However, studies also have demonstrated a positive association between vitamin E intake and the development of BCC, including one by Fung et al,⁴² which found a significant association in women (OR, 1.15; 95% CI, 1.06-1.26).

Vitamin E has been found to inhibit melanin synthesis in the laboratory, suggesting a potentially protective effect in melanoma.^69,70 However, in the study performed by Feskanich et al²³ examining vitamin intake and melanoma incidence via food-frequency questionnaires, vitamin E was not associated with a lower risk for melanoma. Despite promising laboratory studies, the data surrounding the use of a vitamin E supplement for prevention of melanoma and NMSC in humans remains unclear.

Selenium—Selenium is a trace mineral found in plants, meat, and fish. It plays a key role in reproduction, hormone metabolism, DNA synthesis, and protection from oxidative damage.⁷¹ In mice studies, lack of selenium-containing proteins resulted in skin abnormalities, including the development of a hyperplastic epidermis and aberrant hair follicle morphogenesis with alopecia after birth, and numerous experimental studies have demonstrated a negative association between selenium intake and cancer.^72,73 However, human studies have yielded alternative results. 

The Nutritional Prevention of Cancer Study Group analyzed 1312 dermatology patients with a history of NMSC.⁷⁴ The study population was obtained from 7 dermatology clinics with randomization to control for confounding variables. Study participants received either 200 μg of selenium daily or placebo.⁷⁴ Baseline characteristics of each study group were overall balanced. Selenium intake was found to have no effect on the development of BCC (hazard ratio [HR], 1.09; 95% CI, 0.94-1.26) but an increased risk for developing SCC (HR, 1.25; 95% CI, 1.03-1.51) and total NMSC (HR, 1.17; 95% CI, 1.02-1.34).^74,75 Similarly, Reid et al⁷⁶ performed an RCT comparing patients treated with 400 μg/d of selenium to those treated with 200 μg/d of selenium. When compared with placebo, those treated with 200 μg/d of selenium had a statistically significantly increased incidence of NMSC (P=.006); however, those treated with 400 μg/d of selenium had no significant change in total incidence of NMSC (P=.51).⁷⁶ Furthermore, Vinceti et al⁷⁷ performed a review of 83 studies from the literature investigating the effect of dietary selenium, and from the RCTs, there was no beneficial effect of selenium in reducing cancer risk in general; however, some studies demonstrated an increased incidence of other types of cancer, including melanoma. Of the RCTs included in the study investigating NMSC incidence specifically, it was found that the incidence was not affected by selenium administration (RR, 1.16; 95% CI, 0.30-4.42; 2 studies, 2027 participants).⁷⁷ Despite data from several studies demonstrating an increased risk for NMSC, the effects of selenium on the risk for NMSC and melanoma remain unclear. 

Combination Antioxidant Studies

In addition to investigating the use of single antioxidants in skin cancer prevention, studies utilizing the combination of various antioxidants or other dietary minerals have been conducted. Hercberg et al⁷⁸ performed a randomized, double-blinded, placebo-controlled trial of 13,017 adults (7876 women and 5141 men) receiving a combination of 120 mg vitamin C, 30 mg vitamin E, 100 μg selenium, 6 mg beta carotene, and 20 mg zinc. Study participants were followed for an average of 7.5 years, and the development of skin cancers were recorded. Overall, the incidence rate of skin cancer did not differ between the 2 treatment groups; however, when segregated by gender, the study found that there was an increased risk for developing skin cancer in women taking the antioxidant supplement combination compared with placebo (P=.03). This difference was not observed in the 2 treatment groups of male patients (P=.11). When looking specifically at NMSC, there was no difference between treatment groups for male or female patients (P=.39 for males; P=.15 for females). In contrast, there was a higher incidence of melanoma identified in female patients taking the combination antioxidant supplement (P=.01), but this was not seen within the male study population (P=.51).⁷⁸ In addition, Chang et al⁷⁹ performed a meta-analysis of 10 previously published RCTs. Analysis revealed that treatment with a variety of supplements, including vitamins A, C, E, and beta carotene, were found to have no preventative effects on the incidence of skin cancer development (RR, 0.98; CI, 0.98-1.03). Notable limitations to this study included the variability in protocols of the studies included in this meta-analysis, the limited number of RCTs investigating vitamin supplementation and the risk for skin cancer development, and the influence of dietary intake on study outcomes.⁷⁹

Other Dietary Agents

Furocoumarins—Furocoumarins are botanical substances found in various fruits and plants, including many citrus products. Furocoumarins are activated by UV light radiation and can lead to development of a phototoxic eruption. Several studies have suggested a pharmacogenetic effect of furocoumarins.⁸⁰ Sun et al⁸⁰ collected dietary data from 47,453 men and 75,291 women on furocoumarin intake and correlation with the development of NMSC. Overall, the study suggested that the intake of furocoumarins may lead to an increase in the development of BCC (HR, 1.16; 95% CI, 1.11-1.21; P=.002); however, there was no significant association identified between total intake of furocoumarins in the risk for SCC or melanoma.⁸⁰ Furthermore, Sakaki et al⁸¹ conducted a survey study looking at the consumption of citrus products and the development of NMSC. The group found that there was an increased risk for NMSC in those consuming an increased amount of citrus products (P=.007).⁸¹

Conclusion

Dietary antioxidants have been investigated for their potential role in the prevention of tumorigenesis. Specific antioxidant vitamins, such as vitamin A derivatives and niacinamide, have demonstrated clinical utility in the prevention of NMSC in high-risk populations. Retinol also has been associated with a reduced incidence of melanoma. Numerous antioxidants have demonstrated promising data within the laboratory setting; however, inconsistent results have been appreciated in humans. Furthermore, several research studies suggest that folate, vitamin D, and furocoumarins may be associated with an increased risk for skin cancer development; however, these studies are inconclusive, and dietary studies are challenging to conduct. Overall, RCTs investigating the role of antioxidants for chemoprevention are limited. Moreover, the study of dietary antioxidants and vitamins may be affected by various confounding variables that can be difficult to account for because of patients’ potentially poor recall of dietary intake and the effect of dietary intake in supplemental studies. Given the increasing prevalence of skin cancer worldwide, further research into the clinical utility of antioxidants in skin cancer prevention is warranted. 

Nonmelanoma skin cancer (NMSC) is the most common cancer in the United States, and cutaneous melanoma is projected to be the fifth most common form of cancer in 2022, with increasing incidence and high potential for mortality.^1-3 Estimates indicate that 35% to 45% of all cancers in White patients are cutaneous, with 4% to 5% occurring in Hispanic patients, 2% to 4% in Asian patients, and 1% to 2% in Black patients.⁴ Of the keratinocyte carcinomas, basal cell carcinoma (BCC) is the most prevalent, projected to affect approximately 33% to 39% of White males and 23% to 28% of White females in the United States during their lifetimes. Squamous cell carcinoma (SCC) is the second most common skin malignancy, with a lifetime risk of 9% to 14% for White males and 4% to 9% for White females in the United States.⁵ The incidence of melanoma continues to increase, with approximately 99,780 new cases expected in the United States in 2022.¹

UV-induced DNA damage plays a key role in the pathogenesis and development of various skin malignancies.⁶ UV radiation from sunlight or tanning devices causes photocarcinogenesis due to molecular and cellular effects, including the generation of reactive oxygen species, DNA damage due to the formation of cyclobutane pyrimidine dimers and pyrimidine-pyrimidone, melanogenesis, apoptosis, and the increased expression of harmful genes and proteins.⁶ The summation of this damage can result in skin malignancies, including NMSC and melanoma.^6,7 Dietary antioxidants theoretically help prevent oxidative reactions from occurring within the body, and it has been suggested that intake of dietary antioxidants may decrease DNA damage and prevent tumorigenesis secondary to UV radiation.⁸ Antioxidants exist naturally in the body but can be acquired exogenously. Investigators have studied dietary antioxidants in preventing skin cancer formation with promising results in the laboratory setting.^8-11 Recently, more robust human studies have been initiated to further delineate this relationship. We present clinical evidence of several frequently utilized antioxidant vitamins and their effects on melanoma and NMSC.

Antioxidants

Vitamin A—Vitamin A is a fat-soluble vitamin found in animal sources, including fish, liver, and eggs. Carotenoids, such as beta carotene, are provitamin A plant derivatives found in fruits and vegetables that are converted into biologically active retinol and retinoic acid.¹² Retinols play a key role in cellular growth and differentiation and are thought to be protective against skin cancer via the inactivation of free radicals and immunologic enhancement due to their antiproliferative, antioxidative, and antiapoptotic effects.^13-16 Animal studies have demonstrated this protective effect and the ability of retinoids to suppress carcinogenesis; however, human studies reveal conflicting results.^17,18

Greenberg et al¹⁹ investigated the use of beta carotene in preventing the formation of NMSC. Patients (N=1805) were randomized to receive 50 mg of beta carotene daily or placebo. Over a 5-year period, there was no significant reduction in the occurrence of NMSC (relative risk [RR], 1.05; 95% CI, 0.91-1.22).¹⁹ Frieling et al²⁰ conducted a similar randomized, double-blind, placebo-controlled trial investigating beta carotene for primary prevention of NMSC in 22,071 healthy male physicians. The study group received 50 mg of beta carotene every other day for 12 years’ duration, and there was no significant effect on the incidence of first NMSC development (RR, 0.98; 95% CI, 0.92-1.05).²⁰

A case-control study by Naldi et al²¹ found an inverse association between vitamin A intake and development of melanoma. Study participants were stratified into quartiles based on level of dietary intake and found an odds ratio (OR) of 0.71 for beta carotene (95% CI, 0.50-1.02), 0.57 for retinol (95% CI, 0.39-0.83), and 0.51 for total vitamin A (95% CI, 0.35-0.75) when comparing the upper quartile of vitamin A intake to the lower quartile. Upper-quartile cutoff values of vitamin A intake were 214 µg/d for beta carotene, 149 µg/d for retinol, and 359 µg/d for total vitamin A.²¹ More recently, a meta-analysis by Zhang et al²² pooled data from 8 case-control studies and 2 prospective studies. Intake of retinol but not total vitamin A or beta carotene was associated with a reduced risk for development of melanoma (retinol: OR, 0.80; 95% CI, 0.69-0.92; total vitamin A: OR, 0.86; 95% CI, 0.59-1.25; beta carotene: OR, 0.87; 95% CI, 0.62-1.20).²² Feskanich et al²³ demonstrated similar findings with use of food-frequency questionnaires in White women, suggesting that retinol intake from food combined with supplements may be protective for women who were otherwise at a low risk for melanoma based on nondietary factors. These factors included painful or blistering sunburns during childhood, history of more than 6 sunburns, more than 3 moles on the left arm, having red or blonde hair, and having a parent or sibling with melanoma (P=.01). However, this relationship did not hold true when looking at women at an intermediate or high risk for melanoma (P=.16 and P=.46).²³

When looking at high-risk patients, such as transplant patients, oral retinoids have been beneficial in preventing NMSC.^24-27 Bavinck et al²⁴ investigated 44 renal transplant patients with a history of more than 10 NMSCs treated with 30 mg of acitretin daily vs placebo. Patients receiving oral retinoid supplementation developed fewer NMSCs over a 6-month treatment period (P=.01).²⁴ Similarly, George et al²⁵ investigated acitretin in renal transplant patients and found a statistically significant decrease in number of SCCs in patients on supplementation (P=.002). Solomon-Cohen et al²⁶ performed a retrospective case-crossover study in solid organ transplant recipients and found that those treated with 10 mg of acitretin daily for 2 years had a significant reduction in the number of new keratinocyte carcinomas (P=.002). Other investigators have demonstrated similar results, and in 2006, Otley et al²⁷ proposed standardized dosing of acitretin for chemoprevention in high-risk patients, including patients developing 5 to 10 NMSCs per year, solid organ transplant recipients, and those with syndromes associated with the development of NMSC.^28,29 Overall, in the general population, vitamin A and related compounds have not demonstrated a significant association with decreased development of NMSC; however, oral retinoids have proven useful for high-risk patients. Furthermore, several studies have suggested a negative association between vitamin A levels and the incidence of melanoma, specifically in the retinol formulation. 

Vitamin B₃—Nicotinamide (also known as niacinamide) is a water-soluble form of vitamin B₃ and is obtained from animal-based and plant-based foods, such as meat, fish, and legumes.³⁰ Nicotinamide plays a key role in cellular metabolism, cellular signaling, and DNA repair, including protection from UV damage within keratinocytes.^31,32 Early mouse models demonstrated decreased formation of skin tumors in mice treated with topical or oral nicotinamide.^32,33 A number of human studies have revealed similar results.^34-36

Chen et al³⁴ conducted the ONTRAC study, a phase 3, double-blind, randomized controlled trial (RCT) looking at 386 participants with a history of at least 2 NMSCs in the preceding 5 years. At 12 months, those treated with 500 mg of nicotinamide twice daily demonstrated a statistically significant decreased rate of SCC formation (P=.05). A decreased incidence of BCC development was noted; however, this trend did not reach statistical significance (P=.12). Precancerous skin lesions also were found to be decreased in the treatment group, with 20% lower incidence of actinic keratoses (AKs) after 9 months of treatment (P<.001).³⁴ Drago et al³⁵ specifically studied the incidence of AKs in 38 transplant recipients—8 liver and 30 kidney—and found that previously noted AKs had decreased in size for 18 of 19 patients taking 500 mg of nicotinamide daily when originally photographed AKs were remeasured at 6-month follow-up, with 7 of these 18 patients demonstrating complete clinical regression. Of those on nicotinamide supplementation, no new AKs developed compared to the control group, which demonstrated increased size of AKs or development of new AKs in 91% of patients, with 7 AKs progressing into SCC.³⁵

Nicotinamide has been demonstrated to be useful in preventing skin cancer in high-risk populations, such as transplant patients or those with a high incidence of NMSC.^34,36 Despite promising results within the laboratory setting, nicotinamide’s effects on melanoma in humans remains less clear.^31,37 Studies suggest that nicotinamide enhances tumor-infiltrating lymphocytes and DNA repair mechanisms in melanocytes, which may translate into nicotinamide, providing chemoprevention for melanoma, but research in human patients is limited.^31,37

Vitamin B₉—Folate, the natural form of vitamin B₉, is a water-soluble compound that is found in many foods, especially green leafy vegetables, and often is supplemented because of its health benefits.^38,39 In the skin, folic acid plays a key role in cellular replication and proliferation.³⁸ Controversy exists regarding folate’s effects on cellular growth and turnover with respect to cancer incidence.^38,40 Donnenfeld et al⁴¹ conducted a prospective study assessing dietary folic acid intake and development of NMSC. A total of 5880 participants completed dietary records throughout the first 2 years of the study. After an average follow-up period of 12.6 years, there was an overall increased incidence of skin cancer in those with increased dietary folate (P=.03). Furthermore, when striating by skin cancer type, there was an increased incidence of NMSC overall as well as BCC when analyzing by type of NMSC (P=.03 for NMSC; P=.05 for BCC). However, when stratifying by gender, these findings only held true for women.⁴¹ Similar effects were observed by Fung et al,⁴² who prospectively studied the intake of various vitamins in relationship to the development of BCC in women. During 12 years of follow-up, a positive association was observed between folate intake and BCC development (OR, 1.2; 95% CI, 1.10-1.31).⁴² Fung et al⁴³ also investigated the role of several vitamins in the development of SCC and found that folate showed a negative association, which did not reach statistical significance (RR, 0.79; 95% CI, 0.56-1.11). Furthermore, Vollset et al⁴⁰ conducted a meta-analysis comparing folic acid to placebo in the incidence of various types of cancer. The study excluded NMSC but reported no significant association between the development of melanoma and folic acid supplementation.⁴⁰ In summary, the effects of folate have diverse consequences, potentially promoting the formation of NMSC, but studies suggest that an individual’s gender and other genetic and environmental factors also may play a role.

Vitamin C—Vitamin C (also known as ascorbic acid) is a water-soluble vitamin with antioxidant immune-mediating effects. It is found in various fruits and vegetables and serves as a cofactor for enzymes within the body playing a key role in immune function and collagen formation.^44,45 It has been postulated that ascorbic acid can provide protection from UV radiation damage via its intracellular activity but conversely can contribute to oxidative damage.⁴⁴ Multiple in vitro laboratory studies and animal models have demonstrated photoprotective effects of ascorbic acid.^46-48 Despite these findings, minimal photoprotective effects have been found in the human population.

Kune et al⁴⁹ performed a case-control study of 88 males with previously diagnosed NMSC undergoing surgical removal and investigated patients’ prior dietary habits. Patients with NMSC had a statistically significantly lower level of vitamin C–containing food in their diet than those without NMSC (P=.004).⁴⁹ In addition, Vural et al⁵⁰ analyzed plasma samples and blood cells of patients with AK and BCC and found a significant decrease in ascorbic acid levels in both the AK (P<.001) and BCC (P<.001) groups compared with controls. However, studies have found that consumption of certain dietary compounds can rapidly increase plasma concentration levels, which may serve as a major confounding variable in this study. Plasma concentrations of ascorbic acid and beta carotene were found to be significantly increased following consumption of a high-antioxidant diet for as short a duration as 2 weeks (P<.05).⁵¹ More recently, Heinen et al⁵² performed a prospective study on 1001 adults. In patients without a history of skin cancer, they found that vitamin C from food sources plus dietary supplements was positively associated with the development of BCC (P=.03).⁵² Similarly, Fung et al⁴² performed a study in women and found a positive association between vitamin C intake and the development of BCC (OR, 1.13; 95% CI, 1.03-1.23).

The relationship between vitamin C intake—either in dietary or supplemental form—and melanoma remains controversial. Mice-based studies found that high concentrations of orally administered vitamin C induce cytotoxicity in melanoma cell lines, but at low concentrations they promote tumor growth of malignant melanoma.⁵³ Feskanich et al²³ examined the relationship between vitamin C intake and melanoma development via food frequency questionnaires in White women and found that vitamin C was associated with a higher risk for melanoma (P=.05), and furthermore, a positive dose response with frequency of orange juice intake was observed (P=.008). Overall, despite promising laboratory studies, there is a lack of RCTs investigating the use of vitamin C supplementation for prevention of NMSC and melanoma in humans, and the oral benefits of vitamin C for chemoprevention remain unclear.

Vitamin D—Vitamin D is a fat-soluble vitamin that is found in fish, liver, egg, and cheese, and is endogenously produced when UV radiation from sun exposure interacts with the skin, triggering the synthesis of vitamin D.⁵⁴ Vitamin D is biologically inactive and must be converted to its active form 1,25-dihydroxyvitamin D after entering the body. Vitamin D modulates many genes involved in cellular proliferation and differentiation.⁵⁴ Vitamin D receptors are expressed on keratinocytes and melanocytes.⁵⁵ Animal studies have demonstrated a potentially protective effect of vitamin D in the development of NMSC.⁵⁶ In a mouse model, Ellison et al⁵⁶ found that mice without vitamin D receptors developed skin tumors more rapidly than those with vitamin D receptors.

Unfortunately, these findings have not been demonstrated in humans, and studies have even reported an increased risk for development of NMSC in patients with normal or increased vitamin D levels compared with those with low levels of vitamin D.^57-60 Eide et al⁵⁷ studied 3223 patients seeking advice for low bone density by recording their vitamin D levels at the time of presentation and monitoring development of NMSC. Vitamin D levels greater than 15 ng/mL were positively associated with the development of NMSC (OR, 1.7; 95% CI, 1.04-2.7). This association held true for both SCC and BCC, with a higher risk estimated for SCC (OR, 3.2; 95% CI, 0.4-24.0 for SCC; OR, 1.7; 95% CI, 0.5-5.8 for BCC).⁵⁷ An increased vitamin D serum level also was found to be significantly associated with a higher risk for BCC and melanoma by van der Pols et al.⁵⁸ This prospective study looked at the incidence of skin cancer over 11 years. Study participants with vitamin D levels over 75 nmol/L more frequently developed BCC (P=.01) and melanoma (P=.05). In contrast, SCC was less frequently observed in participants with these high levels of vitamin D (P=.07).⁵⁸ Furthermore, Park et al⁶⁰ looked at vitamin D and skin cancer risk for men and women in the United States and found no association with risk for SCC or melanoma but a positive association with BCC (P=.05 for total vitamin D; P<.01 for dietary vitamin D). Additional studies have been performed with inconsistent results, and multiple authors suggest the possible confounding relationship between vitamin D levels and UV radiation exposure.^59-62 Furthermore, some studies have even demonstrated a negative association between vitamin D and NMSC. Tang et al⁶³ performed a retrospective case-control study in elderly males, investigating serum levels of vitamin D and patients’ self-reported history of NMSC, which demonstrated that higher levels of vitamin D were associated with a decreased risk for NMSC. Overall, the relationship between vitamin D and skin cancer development remains unclear for both melanoma and NMSC.

Vitamin E—Vitamin E is a fat-soluble vitamin that is found in plant-based oils, nuts, seeds, fruits, and vegetables.⁶⁴ It works as an antioxidant to protect against free radicals and heighten immune function, and it also serves as a pro-oxidant.^65,66 Vitamin E naturally exists in 8 chemical forms, of which gamma-tocopherol is the most frequently obtained form in the diet, and alpha-tocopherol is the most abundant form found in the body.^64,65

Early animal studies demonstrated the inhibition of UV-induced damage in mice receiving vitamin E supplementation.^67,68 Human studies have not consistently shown these effects. Vural et al⁵⁰ investigated plasma samples and blood cells of patients with AKs and BCCs and reported a significant decrease in alpha-tocopherol levels in both the AK (P<.05) and BCC (P<.001) groups compared with controls. However, studies also have demonstrated a positive association between vitamin E intake and the development of BCC, including one by Fung et al,⁴² which found a significant association in women (OR, 1.15; 95% CI, 1.06-1.26).

Vitamin E has been found to inhibit melanin synthesis in the laboratory, suggesting a potentially protective effect in melanoma.^69,70 However, in the study performed by Feskanich et al²³ examining vitamin intake and melanoma incidence via food-frequency questionnaires, vitamin E was not associated with a lower risk for melanoma. Despite promising laboratory studies, the data surrounding the use of a vitamin E supplement for prevention of melanoma and NMSC in humans remains unclear.

Selenium—Selenium is a trace mineral found in plants, meat, and fish. It plays a key role in reproduction, hormone metabolism, DNA synthesis, and protection from oxidative damage.⁷¹ In mice studies, lack of selenium-containing proteins resulted in skin abnormalities, including the development of a hyperplastic epidermis and aberrant hair follicle morphogenesis with alopecia after birth, and numerous experimental studies have demonstrated a negative association between selenium intake and cancer.^72,73 However, human studies have yielded alternative results. 

The Nutritional Prevention of Cancer Study Group analyzed 1312 dermatology patients with a history of NMSC.⁷⁴ The study population was obtained from 7 dermatology clinics with randomization to control for confounding variables. Study participants received either 200 μg of selenium daily or placebo.⁷⁴ Baseline characteristics of each study group were overall balanced. Selenium intake was found to have no effect on the development of BCC (hazard ratio [HR], 1.09; 95% CI, 0.94-1.26) but an increased risk for developing SCC (HR, 1.25; 95% CI, 1.03-1.51) and total NMSC (HR, 1.17; 95% CI, 1.02-1.34).^74,75 Similarly, Reid et al⁷⁶ performed an RCT comparing patients treated with 400 μg/d of selenium to those treated with 200 μg/d of selenium. When compared with placebo, those treated with 200 μg/d of selenium had a statistically significantly increased incidence of NMSC (P=.006); however, those treated with 400 μg/d of selenium had no significant change in total incidence of NMSC (P=.51).⁷⁶ Furthermore, Vinceti et al⁷⁷ performed a review of 83 studies from the literature investigating the effect of dietary selenium, and from the RCTs, there was no beneficial effect of selenium in reducing cancer risk in general; however, some studies demonstrated an increased incidence of other types of cancer, including melanoma. Of the RCTs included in the study investigating NMSC incidence specifically, it was found that the incidence was not affected by selenium administration (RR, 1.16; 95% CI, 0.30-4.42; 2 studies, 2027 participants).⁷⁷ Despite data from several studies demonstrating an increased risk for NMSC, the effects of selenium on the risk for NMSC and melanoma remain unclear. 

Combination Antioxidant Studies

In addition to investigating the use of single antioxidants in skin cancer prevention, studies utilizing the combination of various antioxidants or other dietary minerals have been conducted. Hercberg et al⁷⁸ performed a randomized, double-blinded, placebo-controlled trial of 13,017 adults (7876 women and 5141 men) receiving a combination of 120 mg vitamin C, 30 mg vitamin E, 100 μg selenium, 6 mg beta carotene, and 20 mg zinc. Study participants were followed for an average of 7.5 years, and the development of skin cancers were recorded. Overall, the incidence rate of skin cancer did not differ between the 2 treatment groups; however, when segregated by gender, the study found that there was an increased risk for developing skin cancer in women taking the antioxidant supplement combination compared with placebo (P=.03). This difference was not observed in the 2 treatment groups of male patients (P=.11). When looking specifically at NMSC, there was no difference between treatment groups for male or female patients (P=.39 for males; P=.15 for females). In contrast, there was a higher incidence of melanoma identified in female patients taking the combination antioxidant supplement (P=.01), but this was not seen within the male study population (P=.51).⁷⁸ In addition, Chang et al⁷⁹ performed a meta-analysis of 10 previously published RCTs. Analysis revealed that treatment with a variety of supplements, including vitamins A, C, E, and beta carotene, were found to have no preventative effects on the incidence of skin cancer development (RR, 0.98; CI, 0.98-1.03). Notable limitations to this study included the variability in protocols of the studies included in this meta-analysis, the limited number of RCTs investigating vitamin supplementation and the risk for skin cancer development, and the influence of dietary intake on study outcomes.⁷⁹

Other Dietary Agents

Furocoumarins—Furocoumarins are botanical substances found in various fruits and plants, including many citrus products. Furocoumarins are activated by UV light radiation and can lead to development of a phototoxic eruption. Several studies have suggested a pharmacogenetic effect of furocoumarins.⁸⁰ Sun et al⁸⁰ collected dietary data from 47,453 men and 75,291 women on furocoumarin intake and correlation with the development of NMSC. Overall, the study suggested that the intake of furocoumarins may lead to an increase in the development of BCC (HR, 1.16; 95% CI, 1.11-1.21; P=.002); however, there was no significant association identified between total intake of furocoumarins in the risk for SCC or melanoma.⁸⁰ Furthermore, Sakaki et al⁸¹ conducted a survey study looking at the consumption of citrus products and the development of NMSC. The group found that there was an increased risk for NMSC in those consuming an increased amount of citrus products (P=.007).⁸¹

Conclusion

Dietary antioxidants have been investigated for their potential role in the prevention of tumorigenesis. Specific antioxidant vitamins, such as vitamin A derivatives and niacinamide, have demonstrated clinical utility in the prevention of NMSC in high-risk populations. Retinol also has been associated with a reduced incidence of melanoma. Numerous antioxidants have demonstrated promising data within the laboratory setting; however, inconsistent results have been appreciated in humans. Furthermore, several research studies suggest that folate, vitamin D, and furocoumarins may be associated with an increased risk for skin cancer development; however, these studies are inconclusive, and dietary studies are challenging to conduct. Overall, RCTs investigating the role of antioxidants for chemoprevention are limited. Moreover, the study of dietary antioxidants and vitamins may be affected by various confounding variables that can be difficult to account for because of patients’ potentially poor recall of dietary intake and the effect of dietary intake in supplemental studies. Given the increasing prevalence of skin cancer worldwide, further research into the clinical utility of antioxidants in skin cancer prevention is warranted. 

Epidermal growth factor receptor (EGFR) inhibitors cause numerous cutaneous adverse events (AEs), including papulopustular eruptions, paronychia, acral fissures, xerosis, alopecia, and trichomegaly.¹ Symmetrical drug-related intertriginous and flexural exanthema (SDRIFE) is an uncommon type IV hypersensitivity reaction reported most commonly in association with β-lactam antibiotics and other medications.² Treatment of SDRIFE generally involves withdrawing the inciting medication; however, in SDRIFE secondary to oncologic therapies, medication withdrawal may not be feasible or desirable. We present 2 cases of SDRIFE secondary to EGFR inhibitors in which treatment was continued alongside supportive skin-directed therapies. We also review the literature.

Case Reports

Patient 1—A 65-year-old man with stage IV non–small cell lung cancer presented to the dermatology clinic with an eruption of 2 months’ duration that began in the periumbilical area and spread to the perianal area within 2 weeks of starting treatment with lazertinib and amivantamab. Physical examination was notable for Common Terminology Criteria for Adverse Events (CTCAE) Grade 2 periumbilical erythema and erosions as well as symmetric red-brown patches with linear erosions in the gluteal cleft (Figure 1) and Grade 2 facial papulopustular rash. Herpes simplex virus polymerase chain reaction and bacterial culture were negative. A skin biopsy from the left buttock revealed dermal edema and a perivascular lymphocytic infiltrate compatible with SDRIFE. Triamcinolone ointment 0.1% twice daily was initiated, then uptitrated to betamethasone ointment 0.05% twice daily with moderate improvement. The patient had a treatment interruption due to malignancy complications, at which time his skin improved, with recurrence of the eruption after treatment re-initiation. He resumed skin-directed treatment and was maintained on betamethasone ointment 0.05% and tacrolimus ointment 0.1% twice daily on alternating days. This treatment was continued for 4 months before the patient died from complications of the malignancy.

Patient 2—A 68-year-old woman with stage IV lung adenocarcinoma presented to the dermatology clinic with a rash of 3 weeks’ duration. Treatment with osimertinib was initiated 8 months prior to presentation, and there were no recent medication changes. Physical examination revealed CTCAE Grade 2 erythematous patches in the inguinal folds (Figure 2A), inframammary folds (Figure 2B), and on the nasal tip, as well as Grade 2 paronychia. The patient was managed with hydrocortisone cream 1% twice daily, and osimertinib was continued. At follow-up 4 weeks later, the erythema had faded to hyperpigmentation in affected areas with resolution of symptoms. No further treatment was required.

Comment

Supportive oncodermatologists and dermatology hospitalists should be aware of SDRIFE as an uncommon but increasingly recognized cutaneous AE of EGFR inhibitors. Other cases of SDRIFE secondary to EGFR inhibition are described in the Table.^2-5 Although SDRIFE typically is treated by discontinuation of the offending agent, in all reported cases of EGFR inhibitor–associated SDRIFE the rash was CTCAE Grade 2, meaning that it did not interfere with instrumental activities of daily living. In 5 of 6 cases, EGFR therapy was continued while skin-directed therapies were used for symptom management.

Presentation of SDRIFE—Symmetrical drug-related intertriginous and flexural exanthema is characterized by a symmetric, sharply demarcated erythema in the inguinal, gluteal, or perianal area with at least 1 other flexural localization involved in the absence of systemic signs. It is observed most frequently at initial exposure or re-exposure to a medication. Onset typically is within a few hours to a few days after exposure to a medication.⁶ Interestingly, in this case series, half of reported SDRIFE cases developed 8 months or more after EGFR inhibitor initiation.

Pathophysiology of SDRIFE—The mechanism of SDRIFE has not been clearly elucidated; it generally is accepted to be a delayed-type hypersensitivity drug reaction, though other proposed pathophysiologic mechanisms for the distribution of SDRIFE include recall phenomenon or predisposing anatomic factors such as temperature, humidity, and apocrine or eccrine gland density.^6,7 Epidermal growth factor receptor plays a critical role in regulating differentiation and proliferation of epidermal keratinocytes, hair follicles, and the sweat gland apparatus. Additionally, it has been hypothesized that EGFR inhibitor use may affect the microflora of the skin and that EGFR inhibitors directly affect the immune system, as demonstrated in an experiment showing EGFR inhibitor–treated mice had enhanced skin inflammation and contact hypersensitivity responses.⁸ How these disparate mechanisms may interact to produce SDRIFE and the reason for the notably delayed presentation of SDRIFE in half of the cases we reviewed is not known. Other delayed cutaneous AEs of EGFR inhibitor therapy, such as paronychia, are thought to be secondary to development of skin fragility and decreased keratinocyte proliferation with secondary infection.¹ It is conceivable that a combination of proliferative, immunologic, and microbiome-related factors may each be playing a role in EGFR inhibitor–related SDRIFE.

Dermatology Inpatient Considerations—As seen in our cases, dermatologists can play a valuable role in diagnosing, grading, and managing cutaneous AEs associated with the administration of oncologic therapies. The array of cutaneous AEs has grown as cancer treatment options have expanded from conventional antimetabolite agents to kinase inhibitors and immune checkpoint inhibitors. Dermatologists may play an important role in differentiating the etiology of a skin finding (eg, infectious vs inflammatory) and can identify serious or dose-limiting reactions, such as Stevens-Johnson syndrome or drug reaction with eosinophilia and systemic symptoms (DRESS). If cutaneous AEs appear to occur secondary to administration of a chemotherapeutic agent, use of the National Cancer Institute CTCAE should be employed. For certain AEs (eg, alopecia, acneiform rashes, bullous dermatitis), specific grading has been developed based on a combination of body surface area involved, psychosocial impact, symptoms, and other associated morbidity.⁹

In management of chemotherapy-associated cutaneous AEs, dermatologists are likely to be the members of the health care team most comfortable with prescribing high-potency anti-inflammatory topical medications. Dermatologic consultation for management of cutaneous AEs has been shown to both reduce the need for systemic immunosuppression and limit interruptions in oncologic treatment.¹⁰

Conclusion

Epidermal growth factor receptor inhibitors commonly are prescribed for colorectal cancer, non–small cell lung cancer, and squamous cell carcinoma of the head and neck. They are associated with a variety of cutaneous AEs, including acneiform eruptions, paronychia, and xerosis, which rarely necessitate stopping EGFR inhibitor therapy. Our cases support an approach to managing EGFR inhibitor–related SDRIFE that does not involve discontinuation of the offending agent. Further studies are needed on the best supportive topical and systemic regimens for EGFR inhibitor–associated SDRIFE.

Epidermal growth factor receptor (EGFR) inhibitors cause numerous cutaneous adverse events (AEs), including papulopustular eruptions, paronychia, acral fissures, xerosis, alopecia, and trichomegaly.¹ Symmetrical drug-related intertriginous and flexural exanthema (SDRIFE) is an uncommon type IV hypersensitivity reaction reported most commonly in association with β-lactam antibiotics and other medications.² Treatment of SDRIFE generally involves withdrawing the inciting medication; however, in SDRIFE secondary to oncologic therapies, medication withdrawal may not be feasible or desirable. We present 2 cases of SDRIFE secondary to EGFR inhibitors in which treatment was continued alongside supportive skin-directed therapies. We also review the literature.

Case Reports

Patient 1—A 65-year-old man with stage IV non–small cell lung cancer presented to the dermatology clinic with an eruption of 2 months’ duration that began in the periumbilical area and spread to the perianal area within 2 weeks of starting treatment with lazertinib and amivantamab. Physical examination was notable for Common Terminology Criteria for Adverse Events (CTCAE) Grade 2 periumbilical erythema and erosions as well as symmetric red-brown patches with linear erosions in the gluteal cleft (Figure 1) and Grade 2 facial papulopustular rash. Herpes simplex virus polymerase chain reaction and bacterial culture were negative. A skin biopsy from the left buttock revealed dermal edema and a perivascular lymphocytic infiltrate compatible with SDRIFE. Triamcinolone ointment 0.1% twice daily was initiated, then uptitrated to betamethasone ointment 0.05% twice daily with moderate improvement. The patient had a treatment interruption due to malignancy complications, at which time his skin improved, with recurrence of the eruption after treatment re-initiation. He resumed skin-directed treatment and was maintained on betamethasone ointment 0.05% and tacrolimus ointment 0.1% twice daily on alternating days. This treatment was continued for 4 months before the patient died from complications of the malignancy.

Patient 2—A 68-year-old woman with stage IV lung adenocarcinoma presented to the dermatology clinic with a rash of 3 weeks’ duration. Treatment with osimertinib was initiated 8 months prior to presentation, and there were no recent medication changes. Physical examination revealed CTCAE Grade 2 erythematous patches in the inguinal folds (Figure 2A), inframammary folds (Figure 2B), and on the nasal tip, as well as Grade 2 paronychia. The patient was managed with hydrocortisone cream 1% twice daily, and osimertinib was continued. At follow-up 4 weeks later, the erythema had faded to hyperpigmentation in affected areas with resolution of symptoms. No further treatment was required.

Comment

Supportive oncodermatologists and dermatology hospitalists should be aware of SDRIFE as an uncommon but increasingly recognized cutaneous AE of EGFR inhibitors. Other cases of SDRIFE secondary to EGFR inhibition are described in the Table.^2-5 Although SDRIFE typically is treated by discontinuation of the offending agent, in all reported cases of EGFR inhibitor–associated SDRIFE the rash was CTCAE Grade 2, meaning that it did not interfere with instrumental activities of daily living. In 5 of 6 cases, EGFR therapy was continued while skin-directed therapies were used for symptom management.

Presentation of SDRIFE—Symmetrical drug-related intertriginous and flexural exanthema is characterized by a symmetric, sharply demarcated erythema in the inguinal, gluteal, or perianal area with at least 1 other flexural localization involved in the absence of systemic signs. It is observed most frequently at initial exposure or re-exposure to a medication. Onset typically is within a few hours to a few days after exposure to a medication.⁶ Interestingly, in this case series, half of reported SDRIFE cases developed 8 months or more after EGFR inhibitor initiation.

Pathophysiology of SDRIFE—The mechanism of SDRIFE has not been clearly elucidated; it generally is accepted to be a delayed-type hypersensitivity drug reaction, though other proposed pathophysiologic mechanisms for the distribution of SDRIFE include recall phenomenon or predisposing anatomic factors such as temperature, humidity, and apocrine or eccrine gland density.^6,7 Epidermal growth factor receptor plays a critical role in regulating differentiation and proliferation of epidermal keratinocytes, hair follicles, and the sweat gland apparatus. Additionally, it has been hypothesized that EGFR inhibitor use may affect the microflora of the skin and that EGFR inhibitors directly affect the immune system, as demonstrated in an experiment showing EGFR inhibitor–treated mice had enhanced skin inflammation and contact hypersensitivity responses.⁸ How these disparate mechanisms may interact to produce SDRIFE and the reason for the notably delayed presentation of SDRIFE in half of the cases we reviewed is not known. Other delayed cutaneous AEs of EGFR inhibitor therapy, such as paronychia, are thought to be secondary to development of skin fragility and decreased keratinocyte proliferation with secondary infection.¹ It is conceivable that a combination of proliferative, immunologic, and microbiome-related factors may each be playing a role in EGFR inhibitor–related SDRIFE.

Dermatology Inpatient Considerations—As seen in our cases, dermatologists can play a valuable role in diagnosing, grading, and managing cutaneous AEs associated with the administration of oncologic therapies. The array of cutaneous AEs has grown as cancer treatment options have expanded from conventional antimetabolite agents to kinase inhibitors and immune checkpoint inhibitors. Dermatologists may play an important role in differentiating the etiology of a skin finding (eg, infectious vs inflammatory) and can identify serious or dose-limiting reactions, such as Stevens-Johnson syndrome or drug reaction with eosinophilia and systemic symptoms (DRESS). If cutaneous AEs appear to occur secondary to administration of a chemotherapeutic agent, use of the National Cancer Institute CTCAE should be employed. For certain AEs (eg, alopecia, acneiform rashes, bullous dermatitis), specific grading has been developed based on a combination of body surface area involved, psychosocial impact, symptoms, and other associated morbidity.⁹

In management of chemotherapy-associated cutaneous AEs, dermatologists are likely to be the members of the health care team most comfortable with prescribing high-potency anti-inflammatory topical medications. Dermatologic consultation for management of cutaneous AEs has been shown to both reduce the need for systemic immunosuppression and limit interruptions in oncologic treatment.¹⁰

Conclusion

Epidermal growth factor receptor inhibitors commonly are prescribed for colorectal cancer, non–small cell lung cancer, and squamous cell carcinoma of the head and neck. They are associated with a variety of cutaneous AEs, including acneiform eruptions, paronychia, and xerosis, which rarely necessitate stopping EGFR inhibitor therapy. Our cases support an approach to managing EGFR inhibitor–related SDRIFE that does not involve discontinuation of the offending agent. Further studies are needed on the best supportive topical and systemic regimens for EGFR inhibitor–associated SDRIFE.

Epidermal growth factor receptor (EGFR) inhibitors cause numerous cutaneous adverse events (AEs), including papulopustular eruptions, paronychia, acral fissures, xerosis, alopecia, and trichomegaly.¹ Symmetrical drug-related intertriginous and flexural exanthema (SDRIFE) is an uncommon type IV hypersensitivity reaction reported most commonly in association with β-lactam antibiotics and other medications.² Treatment of SDRIFE generally involves withdrawing the inciting medication; however, in SDRIFE secondary to oncologic therapies, medication withdrawal may not be feasible or desirable. We present 2 cases of SDRIFE secondary to EGFR inhibitors in which treatment was continued alongside supportive skin-directed therapies. We also review the literature.

Case Reports

Patient 1—A 65-year-old man with stage IV non–small cell lung cancer presented to the dermatology clinic with an eruption of 2 months’ duration that began in the periumbilical area and spread to the perianal area within 2 weeks of starting treatment with lazertinib and amivantamab. Physical examination was notable for Common Terminology Criteria for Adverse Events (CTCAE) Grade 2 periumbilical erythema and erosions as well as symmetric red-brown patches with linear erosions in the gluteal cleft (Figure 1) and Grade 2 facial papulopustular rash. Herpes simplex virus polymerase chain reaction and bacterial culture were negative. A skin biopsy from the left buttock revealed dermal edema and a perivascular lymphocytic infiltrate compatible with SDRIFE. Triamcinolone ointment 0.1% twice daily was initiated, then uptitrated to betamethasone ointment 0.05% twice daily with moderate improvement. The patient had a treatment interruption due to malignancy complications, at which time his skin improved, with recurrence of the eruption after treatment re-initiation. He resumed skin-directed treatment and was maintained on betamethasone ointment 0.05% and tacrolimus ointment 0.1% twice daily on alternating days. This treatment was continued for 4 months before the patient died from complications of the malignancy.

Patient 2—A 68-year-old woman with stage IV lung adenocarcinoma presented to the dermatology clinic with a rash of 3 weeks’ duration. Treatment with osimertinib was initiated 8 months prior to presentation, and there were no recent medication changes. Physical examination revealed CTCAE Grade 2 erythematous patches in the inguinal folds (Figure 2A), inframammary folds (Figure 2B), and on the nasal tip, as well as Grade 2 paronychia. The patient was managed with hydrocortisone cream 1% twice daily, and osimertinib was continued. At follow-up 4 weeks later, the erythema had faded to hyperpigmentation in affected areas with resolution of symptoms. No further treatment was required.

Comment

Supportive oncodermatologists and dermatology hospitalists should be aware of SDRIFE as an uncommon but increasingly recognized cutaneous AE of EGFR inhibitors. Other cases of SDRIFE secondary to EGFR inhibition are described in the Table.^2-5 Although SDRIFE typically is treated by discontinuation of the offending agent, in all reported cases of EGFR inhibitor–associated SDRIFE the rash was CTCAE Grade 2, meaning that it did not interfere with instrumental activities of daily living. In 5 of 6 cases, EGFR therapy was continued while skin-directed therapies were used for symptom management.

Presentation of SDRIFE—Symmetrical drug-related intertriginous and flexural exanthema is characterized by a symmetric, sharply demarcated erythema in the inguinal, gluteal, or perianal area with at least 1 other flexural localization involved in the absence of systemic signs. It is observed most frequently at initial exposure or re-exposure to a medication. Onset typically is within a few hours to a few days after exposure to a medication.⁶ Interestingly, in this case series, half of reported SDRIFE cases developed 8 months or more after EGFR inhibitor initiation.

Pathophysiology of SDRIFE—The mechanism of SDRIFE has not been clearly elucidated; it generally is accepted to be a delayed-type hypersensitivity drug reaction, though other proposed pathophysiologic mechanisms for the distribution of SDRIFE include recall phenomenon or predisposing anatomic factors such as temperature, humidity, and apocrine or eccrine gland density.^6,7 Epidermal growth factor receptor plays a critical role in regulating differentiation and proliferation of epidermal keratinocytes, hair follicles, and the sweat gland apparatus. Additionally, it has been hypothesized that EGFR inhibitor use may affect the microflora of the skin and that EGFR inhibitors directly affect the immune system, as demonstrated in an experiment showing EGFR inhibitor–treated mice had enhanced skin inflammation and contact hypersensitivity responses.⁸ How these disparate mechanisms may interact to produce SDRIFE and the reason for the notably delayed presentation of SDRIFE in half of the cases we reviewed is not known. Other delayed cutaneous AEs of EGFR inhibitor therapy, such as paronychia, are thought to be secondary to development of skin fragility and decreased keratinocyte proliferation with secondary infection.¹ It is conceivable that a combination of proliferative, immunologic, and microbiome-related factors may each be playing a role in EGFR inhibitor–related SDRIFE.

Dermatology Inpatient Considerations—As seen in our cases, dermatologists can play a valuable role in diagnosing, grading, and managing cutaneous AEs associated with the administration of oncologic therapies. The array of cutaneous AEs has grown as cancer treatment options have expanded from conventional antimetabolite agents to kinase inhibitors and immune checkpoint inhibitors. Dermatologists may play an important role in differentiating the etiology of a skin finding (eg, infectious vs inflammatory) and can identify serious or dose-limiting reactions, such as Stevens-Johnson syndrome or drug reaction with eosinophilia and systemic symptoms (DRESS). If cutaneous AEs appear to occur secondary to administration of a chemotherapeutic agent, use of the National Cancer Institute CTCAE should be employed. For certain AEs (eg, alopecia, acneiform rashes, bullous dermatitis), specific grading has been developed based on a combination of body surface area involved, psychosocial impact, symptoms, and other associated morbidity.⁹

In management of chemotherapy-associated cutaneous AEs, dermatologists are likely to be the members of the health care team most comfortable with prescribing high-potency anti-inflammatory topical medications. Dermatologic consultation for management of cutaneous AEs has been shown to both reduce the need for systemic immunosuppression and limit interruptions in oncologic treatment.¹⁰

Conclusion

Epidermal growth factor receptor inhibitors commonly are prescribed for colorectal cancer, non–small cell lung cancer, and squamous cell carcinoma of the head and neck. They are associated with a variety of cutaneous AEs, including acneiform eruptions, paronychia, and xerosis, which rarely necessitate stopping EGFR inhibitor therapy. Our cases support an approach to managing EGFR inhibitor–related SDRIFE that does not involve discontinuation of the offending agent. Further studies are needed on the best supportive topical and systemic regimens for EGFR inhibitor–associated SDRIFE.

SAN DIEGO – If approved, a novel topical gel that combines an antibiotic, an antibacterial, and a retinoid would mark an important advance for many patients with moderate-to-severe acne, according to Lawrence F. Eichenfield, MD.

The product, known as IDP-126 and being developed by Ortho Dermatologics, is a fixed dose triple combination of clindamycin 1.2% plus benzoyl peroxide 3.1% and adapalene 0.15% being evaluated in patients nine years of age and older. According to a 2021 press release from the company, results from a second 12-week pivotal phase 3 trial showed a treatment success of 50.5% and 20.5% for IDP-126 and its vehicle, respectively, along with significant changes from baseline in inflammatory lesion count and non-inflammatory lesion count.

olavs/Thinkstock

More recently, researchers led by Linda Stein Gold, MD, conducted a 12-week multicenter, randomized, double-blind study of IDP-126 in 741 children, adolescents, and adults with moderate to severe acne. They reported 52.5% of patients treated with IDP-126 gel achieved treatment success by week 12, with over 70% reduction in inflammatory and noninflammatory lesions.

“This will be interesting to follow as it moves along,” Dr. Eichenfield, chief of pediatric and adolescent dermatology at Rady Children’s Hospital, San Diego, said at the annual Masters of Aesthetics Symposium in a presentation on the newest topical acne treatments.

“If approved, we probably will be able to decrease our need for systemic therapies in some individuals,” he said. “It’s something that may become important in practices that mix and match between medical and procedural or surgical approaches to acne.”

Dr. Eichenfield highlighted other products for the topical treatment of acne:

• Trifarotene cream 0.005% (Aklief). In 2019, Food and Drug Administration approval made trifarotene cream the first new retinoid indicated for acne in several decades. It is indicated for the topical treatment of acne vulgaris in patients age 9 and older and has been studied in acne of the face, chest, and back.
• Tazarotene lotion 0.045% (Arazlo). The 0.1% formulation of tazarotene is commonly used for acne, but it can cause skin irritation, dryness, and erythema. The new 0.045% formulation was developed in a three-dimensional mesh matrix, with ingredients from an oil-in-water emulsion. “Many of the new acne products come with a background of vehicle delivery systems that minimize the concentration gradient, so it decreases irritation,” said Dr. Eichenfield, one of the authors of a 2021 review article on the management of acne vulgaris in JAMA. “This has very good efficacy without the traditional irritation of other tazarotene products,” Dr. Eichenfield said.
• Minocycline 4% topical foam (Amzeeq). The 2019 U.S. approval marked the first and so far only topical minocycline prescription treatment for acne. “Its hydrophobic composition allows for stable and efficient delivery of inherently unstable pharmaceutical ingredients,” he said. “It’s generally well tolerated.”
• Clascoterone cream 1% (Winlevi). This first-in-class topical androgen receptor inhibitor is approved for the treatment of acne in patients 12 years and older. It competes with dihydrotestosterone and selectively targets androgen receptors in sebocytes and hair papilla cells. “It is safe for use in men, has been studied on the face and trunk, and has been shown to inhibit sebum production, reduce secretion of inflammatory cytokines, and inhibit inflammatory pathways,” Dr. Eichenfield said.
• Micro-encapsulated benzoyl peroxide 3% and tretinoin 0.1% cream (Twyneo). This is a once-daily fixed-dose combination of tretinoin and benzoyl peroxide indicated for the treatment of acne vulgaris in patients age 9 and older. According to a press release from Sol-Gel, the manufacturer, silica (silicon dioxide) core shell structures separate micro-encapsulate tretinoin crystals and benzoyl peroxide crystals, enabling inclusion of the two active ingredients in the cream.

Dr. Eichenfield disclosed that he has been an investigator and/or consultant for Almirall, Cassiopea, Dermata, Galderma, and Ortho Dermatologics.

SAN DIEGO – If approved, a novel topical gel that combines an antibiotic, an antibacterial, and a retinoid would mark an important advance for many patients with moderate-to-severe acne, according to Lawrence F. Eichenfield, MD.

The product, known as IDP-126 and being developed by Ortho Dermatologics, is a fixed dose triple combination of clindamycin 1.2% plus benzoyl peroxide 3.1% and adapalene 0.15% being evaluated in patients nine years of age and older. According to a 2021 press release from the company, results from a second 12-week pivotal phase 3 trial showed a treatment success of 50.5% and 20.5% for IDP-126 and its vehicle, respectively, along with significant changes from baseline in inflammatory lesion count and non-inflammatory lesion count.

olavs/Thinkstock

More recently, researchers led by Linda Stein Gold, MD, conducted a 12-week multicenter, randomized, double-blind study of IDP-126 in 741 children, adolescents, and adults with moderate to severe acne. They reported 52.5% of patients treated with IDP-126 gel achieved treatment success by week 12, with over 70% reduction in inflammatory and noninflammatory lesions.

“This will be interesting to follow as it moves along,” Dr. Eichenfield, chief of pediatric and adolescent dermatology at Rady Children’s Hospital, San Diego, said at the annual Masters of Aesthetics Symposium in a presentation on the newest topical acne treatments.

“If approved, we probably will be able to decrease our need for systemic therapies in some individuals,” he said. “It’s something that may become important in practices that mix and match between medical and procedural or surgical approaches to acne.”

Dr. Eichenfield highlighted other products for the topical treatment of acne:

• Trifarotene cream 0.005% (Aklief). In 2019, Food and Drug Administration approval made trifarotene cream the first new retinoid indicated for acne in several decades. It is indicated for the topical treatment of acne vulgaris in patients age 9 and older and has been studied in acne of the face, chest, and back.
• Tazarotene lotion 0.045% (Arazlo). The 0.1% formulation of tazarotene is commonly used for acne, but it can cause skin irritation, dryness, and erythema. The new 0.045% formulation was developed in a three-dimensional mesh matrix, with ingredients from an oil-in-water emulsion. “Many of the new acne products come with a background of vehicle delivery systems that minimize the concentration gradient, so it decreases irritation,” said Dr. Eichenfield, one of the authors of a 2021 review article on the management of acne vulgaris in JAMA. “This has very good efficacy without the traditional irritation of other tazarotene products,” Dr. Eichenfield said.
• Minocycline 4% topical foam (Amzeeq). The 2019 U.S. approval marked the first and so far only topical minocycline prescription treatment for acne. “Its hydrophobic composition allows for stable and efficient delivery of inherently unstable pharmaceutical ingredients,” he said. “It’s generally well tolerated.”
• Clascoterone cream 1% (Winlevi). This first-in-class topical androgen receptor inhibitor is approved for the treatment of acne in patients 12 years and older. It competes with dihydrotestosterone and selectively targets androgen receptors in sebocytes and hair papilla cells. “It is safe for use in men, has been studied on the face and trunk, and has been shown to inhibit sebum production, reduce secretion of inflammatory cytokines, and inhibit inflammatory pathways,” Dr. Eichenfield said.
• Micro-encapsulated benzoyl peroxide 3% and tretinoin 0.1% cream (Twyneo). This is a once-daily fixed-dose combination of tretinoin and benzoyl peroxide indicated for the treatment of acne vulgaris in patients age 9 and older. According to a press release from Sol-Gel, the manufacturer, silica (silicon dioxide) core shell structures separate micro-encapsulate tretinoin crystals and benzoyl peroxide crystals, enabling inclusion of the two active ingredients in the cream.

Dr. Eichenfield disclosed that he has been an investigator and/or consultant for Almirall, Cassiopea, Dermata, Galderma, and Ortho Dermatologics.

SAN DIEGO – If approved, a novel topical gel that combines an antibiotic, an antibacterial, and a retinoid would mark an important advance for many patients with moderate-to-severe acne, according to Lawrence F. Eichenfield, MD.

The product, known as IDP-126 and being developed by Ortho Dermatologics, is a fixed dose triple combination of clindamycin 1.2% plus benzoyl peroxide 3.1% and adapalene 0.15% being evaluated in patients nine years of age and older. According to a 2021 press release from the company, results from a second 12-week pivotal phase 3 trial showed a treatment success of 50.5% and 20.5% for IDP-126 and its vehicle, respectively, along with significant changes from baseline in inflammatory lesion count and non-inflammatory lesion count.

olavs/Thinkstock

More recently, researchers led by Linda Stein Gold, MD, conducted a 12-week multicenter, randomized, double-blind study of IDP-126 in 741 children, adolescents, and adults with moderate to severe acne. They reported 52.5% of patients treated with IDP-126 gel achieved treatment success by week 12, with over 70% reduction in inflammatory and noninflammatory lesions.

“This will be interesting to follow as it moves along,” Dr. Eichenfield, chief of pediatric and adolescent dermatology at Rady Children’s Hospital, San Diego, said at the annual Masters of Aesthetics Symposium in a presentation on the newest topical acne treatments.

“If approved, we probably will be able to decrease our need for systemic therapies in some individuals,” he said. “It’s something that may become important in practices that mix and match between medical and procedural or surgical approaches to acne.”

Dr. Eichenfield highlighted other products for the topical treatment of acne:

• Trifarotene cream 0.005% (Aklief). In 2019, Food and Drug Administration approval made trifarotene cream the first new retinoid indicated for acne in several decades. It is indicated for the topical treatment of acne vulgaris in patients age 9 and older and has been studied in acne of the face, chest, and back.
• Tazarotene lotion 0.045% (Arazlo). The 0.1% formulation of tazarotene is commonly used for acne, but it can cause skin irritation, dryness, and erythema. The new 0.045% formulation was developed in a three-dimensional mesh matrix, with ingredients from an oil-in-water emulsion. “Many of the new acne products come with a background of vehicle delivery systems that minimize the concentration gradient, so it decreases irritation,” said Dr. Eichenfield, one of the authors of a 2021 review article on the management of acne vulgaris in JAMA. “This has very good efficacy without the traditional irritation of other tazarotene products,” Dr. Eichenfield said.
• Minocycline 4% topical foam (Amzeeq). The 2019 U.S. approval marked the first and so far only topical minocycline prescription treatment for acne. “Its hydrophobic composition allows for stable and efficient delivery of inherently unstable pharmaceutical ingredients,” he said. “It’s generally well tolerated.”
• Clascoterone cream 1% (Winlevi). This first-in-class topical androgen receptor inhibitor is approved for the treatment of acne in patients 12 years and older. It competes with dihydrotestosterone and selectively targets androgen receptors in sebocytes and hair papilla cells. “It is safe for use in men, has been studied on the face and trunk, and has been shown to inhibit sebum production, reduce secretion of inflammatory cytokines, and inhibit inflammatory pathways,” Dr. Eichenfield said.
• Micro-encapsulated benzoyl peroxide 3% and tretinoin 0.1% cream (Twyneo). This is a once-daily fixed-dose combination of tretinoin and benzoyl peroxide indicated for the treatment of acne vulgaris in patients age 9 and older. According to a press release from Sol-Gel, the manufacturer, silica (silicon dioxide) core shell structures separate micro-encapsulate tretinoin crystals and benzoyl peroxide crystals, enabling inclusion of the two active ingredients in the cream.

Dr. Eichenfield disclosed that he has been an investigator and/or consultant for Almirall, Cassiopea, Dermata, Galderma, and Ortho Dermatologics.

Key clinical point: The use of rituximab in patients with rheumatoid arthritis (RA) was associated with worse COVID-19 outcomes compared with the use of conventional synthetic disease-modifying antirheumatic drugs (csDMARD).

Major finding: The risk for COVID-19-related hospitalization (adjusted odds ratio [aOR] 2.14; 95% CI 1.51-3.04), intensive care unit admission (aOR 5.22; 95% CI 1.77-15.41), and invasive ventilation (aOR 2.74; 95% CI 1.36-5.51) was significantly higher with baseline use of rituximab vs csDMARD.

Study details: The data come from a retrospective cohort study including 69,549 patients with RA, of which 22,956 patients were diagnosed with COVID-19 and 364 patients were exposed to rituximab prior to the first COVID-19 diagnosis.

Disclosures: This study did not report the source of funding. JA Singh reported receiving consulting fees, owning stock options, serving on speaker’s bureaus, and being a member of various committees.

Source: Singh N et al. Rituximab is associated with worse COVID-19 outcomes in patients with rheumatoid arthritis: A retrospective, nationally sampled cohort study from the U.S. National COVID Cohort Collaborative (N3C). Semin Arthritis Rheum. 2022;58:152149 (Dec 8). Doi: 10.1016/j.semarthrit.2022.152149

Key clinical point: The use of rituximab in patients with rheumatoid arthritis (RA) was associated with worse COVID-19 outcomes compared with the use of conventional synthetic disease-modifying antirheumatic drugs (csDMARD).

Major finding: The risk for COVID-19-related hospitalization (adjusted odds ratio [aOR] 2.14; 95% CI 1.51-3.04), intensive care unit admission (aOR 5.22; 95% CI 1.77-15.41), and invasive ventilation (aOR 2.74; 95% CI 1.36-5.51) was significantly higher with baseline use of rituximab vs csDMARD.

Study details: The data come from a retrospective cohort study including 69,549 patients with RA, of which 22,956 patients were diagnosed with COVID-19 and 364 patients were exposed to rituximab prior to the first COVID-19 diagnosis.

Disclosures: This study did not report the source of funding. JA Singh reported receiving consulting fees, owning stock options, serving on speaker’s bureaus, and being a member of various committees.

Source: Singh N et al. Rituximab is associated with worse COVID-19 outcomes in patients with rheumatoid arthritis: A retrospective, nationally sampled cohort study from the U.S. National COVID Cohort Collaborative (N3C). Semin Arthritis Rheum. 2022;58:152149 (Dec 8). Doi: 10.1016/j.semarthrit.2022.152149

Key clinical point: The use of rituximab in patients with rheumatoid arthritis (RA) was associated with worse COVID-19 outcomes compared with the use of conventional synthetic disease-modifying antirheumatic drugs (csDMARD).

Major finding: The risk for COVID-19-related hospitalization (adjusted odds ratio [aOR] 2.14; 95% CI 1.51-3.04), intensive care unit admission (aOR 5.22; 95% CI 1.77-15.41), and invasive ventilation (aOR 2.74; 95% CI 1.36-5.51) was significantly higher with baseline use of rituximab vs csDMARD.

Study details: The data come from a retrospective cohort study including 69,549 patients with RA, of which 22,956 patients were diagnosed with COVID-19 and 364 patients were exposed to rituximab prior to the first COVID-19 diagnosis.

Disclosures: This study did not report the source of funding. JA Singh reported receiving consulting fees, owning stock options, serving on speaker’s bureaus, and being a member of various committees.

Source: Singh N et al. Rituximab is associated with worse COVID-19 outcomes in patients with rheumatoid arthritis: A retrospective, nationally sampled cohort study from the U.S. National COVID Cohort Collaborative (N3C). Semin Arthritis Rheum. 2022;58:152149 (Dec 8). Doi: 10.1016/j.semarthrit.2022.152149

Key clinical point: Myopenia was prevalent and associated with physical dysfunction in patients with early rheumatoid arthritis (RA).

Major finding: The prevalence of myopenia was higher in patients with early RA vs matched control individuals (41.3% vs 15.8%; P < .0167) but similar among patients with early and established RA. Myopenia was independently associated with physical dysfunction in patients with early RA (adjusted odds ratio 2.983; 95% CI 1.192-7.465).

Study details: This cross-sectional study included 1008 patients with RA (early RA n = 190; established RA n = 818) and 2017 control individuals who were age- and sex-matched for comparison.

Disclosures: This study was supported by the National Natural Science Foundation of China and other sources. Two authors declared being employees of Shanghai Healthcare Co. Ltd.

Source: Pan J et al. Muscle mass loss is associated with physical dysfunction in patients with early rheumatoid arthritis. Front Nutr. 2022;9:1007184 (Nov 23). Doi: 10.3389/fnut.2022.1007184

Key clinical point: Myopenia was prevalent and associated with physical dysfunction in patients with early rheumatoid arthritis (RA).

Major finding: The prevalence of myopenia was higher in patients with early RA vs matched control individuals (41.3% vs 15.8%; P < .0167) but similar among patients with early and established RA. Myopenia was independently associated with physical dysfunction in patients with early RA (adjusted odds ratio 2.983; 95% CI 1.192-7.465).

Study details: This cross-sectional study included 1008 patients with RA (early RA n = 190; established RA n = 818) and 2017 control individuals who were age- and sex-matched for comparison.

Disclosures: This study was supported by the National Natural Science Foundation of China and other sources. Two authors declared being employees of Shanghai Healthcare Co. Ltd.

Source: Pan J et al. Muscle mass loss is associated with physical dysfunction in patients with early rheumatoid arthritis. Front Nutr. 2022;9:1007184 (Nov 23). Doi: 10.3389/fnut.2022.1007184

Key clinical point: Myopenia was prevalent and associated with physical dysfunction in patients with early rheumatoid arthritis (RA).

Major finding: The prevalence of myopenia was higher in patients with early RA vs matched control individuals (41.3% vs 15.8%; P < .0167) but similar among patients with early and established RA. Myopenia was independently associated with physical dysfunction in patients with early RA (adjusted odds ratio 2.983; 95% CI 1.192-7.465).

Study details: This cross-sectional study included 1008 patients with RA (early RA n = 190; established RA n = 818) and 2017 control individuals who were age- and sex-matched for comparison.

Disclosures: This study was supported by the National Natural Science Foundation of China and other sources. Two authors declared being employees of Shanghai Healthcare Co. Ltd.

Source: Pan J et al. Muscle mass loss is associated with physical dysfunction in patients with early rheumatoid arthritis. Front Nutr. 2022;9:1007184 (Nov 23). Doi: 10.3389/fnut.2022.1007184

Key clinical point: Patients with late-onset rheumatoid arthritis (LORA; disease onset at ≥60 years) had poor control of inflammation after diagnosis compared with those with young-onset RA (YORA), with late onset being associated with a greater cumulative inflammatory burden over time.

Major finding: Moderate-high inflammatory activity (P = .018) was more frequent in LORA vs YORA. The median C-reactive protein (P = .039) and interleukin-6 (P = .045) levels at onset were significantly higher in patients with LORA vs YORA, and late-onset was significantly associated with a high cumulative inflammatory activity of RA (odds ratio 4.694; P = .008).

Study details: This was a nested cohort study of a prospective cohort including 110 patients with incident RA (LORA n = 22; YORA n = 88) and 110 age- and sex-matched control individuals.

Disclosures: This study was supported by grants from Fondos FEDER, University of Malaga, and other sources. The authors declared no conflicts of interest.

Source: Mena-Vázquez N et al. Inflammatory profile of incident cases of late-onset compared with young-onset rheumatoid arthritis: A nested cohort study. Front Med (Lausanne). 2022;9:1016159 (Nov 8). Doi: 10.3389/fmed.2022.1016159

Key clinical point: Patients with late-onset rheumatoid arthritis (LORA; disease onset at ≥60 years) had poor control of inflammation after diagnosis compared with those with young-onset RA (YORA), with late onset being associated with a greater cumulative inflammatory burden over time.

Major finding: Moderate-high inflammatory activity (P = .018) was more frequent in LORA vs YORA. The median C-reactive protein (P = .039) and interleukin-6 (P = .045) levels at onset were significantly higher in patients with LORA vs YORA, and late-onset was significantly associated with a high cumulative inflammatory activity of RA (odds ratio 4.694; P = .008).

Study details: This was a nested cohort study of a prospective cohort including 110 patients with incident RA (LORA n = 22; YORA n = 88) and 110 age- and sex-matched control individuals.

Disclosures: This study was supported by grants from Fondos FEDER, University of Malaga, and other sources. The authors declared no conflicts of interest.

Source: Mena-Vázquez N et al. Inflammatory profile of incident cases of late-onset compared with young-onset rheumatoid arthritis: A nested cohort study. Front Med (Lausanne). 2022;9:1016159 (Nov 8). Doi: 10.3389/fmed.2022.1016159

Key clinical point: Patients with late-onset rheumatoid arthritis (LORA; disease onset at ≥60 years) had poor control of inflammation after diagnosis compared with those with young-onset RA (YORA), with late onset being associated with a greater cumulative inflammatory burden over time.

Major finding: Moderate-high inflammatory activity (P = .018) was more frequent in LORA vs YORA. The median C-reactive protein (P = .039) and interleukin-6 (P = .045) levels at onset were significantly higher in patients with LORA vs YORA, and late-onset was significantly associated with a high cumulative inflammatory activity of RA (odds ratio 4.694; P = .008).

Study details: This was a nested cohort study of a prospective cohort including 110 patients with incident RA (LORA n = 22; YORA n = 88) and 110 age- and sex-matched control individuals.

Disclosures: This study was supported by grants from Fondos FEDER, University of Malaga, and other sources. The authors declared no conflicts of interest.

Source: Mena-Vázquez N et al. Inflammatory profile of incident cases of late-onset compared with young-onset rheumatoid arthritis: A nested cohort study. Front Med (Lausanne). 2022;9:1016159 (Nov 8). Doi: 10.3389/fmed.2022.1016159