Oncology

This transcript has been edited for clarity. 

I’d like to reflect a little on the ever-rising incidence of early-onset colorectal cancer. I saw two patients in the clinic on Friday, both in their early thirties, presenting with stage IV disease. Both had young families — a disaster.

This is an issue that we must address, I think, epidemiologically. We know that early-onset colorectal cancer is defined as a disease arising in those under the age of 50. There’s been a very sharp increase globally over the past 20-30 years, and currently, around 200,000 such cases are diagnosed every year, but it is said to increase unquestionably.

The epidemiologists, I think, correctly have identified that this sharp, rapid increase does imply that there is a new environmental change that is underpinning or underscoring this rise in early-onset disease. 

There’s a fantastic team that has been put together by Paul Brennan, Mike Stratton, and colleagues, a collaborative group of epidemiologists, geneticists, and bioinformaticians, who are looking at a global study to try to understand the basis of early-onset colorectal cancer. Their approach is to combine conventional epidemiology, genomics, and fantastic computational support to try to unpick the mutational signatures involved.

The dominant hypothesis is that, over the past 20-25 years or so, there has been a change in diet that has allowed an alteration in the gut microbiome such that we now harbor, in some cases, more bacteria capable of manufacturing, synthesizing, and releasing mutagenic chemicals. There’s a subtype of Escherichia coli which manufactures one such mutagen called colibactin.

Again, through some of the painstaking, extraordinary work that Mike Stratton and colleagues have done at the Sanger Institute, they have managed to, using a variety of different techniques — in vitro, observational, and so on — relate exposure to the mutagen colibactin to a particular mutational signature.

They plan to do a large global study — one of the strengths — involving many different countries around the globe, collect material from older colorectal cancer patients and early-onset colorectal cancer patients, and undertake a staggeringly large mutational study to see if the mutational signature associated with colibactin is more highly represented in these early-onset cases. The hypothesis is that, if you’re exposed to this mutagen in childhood, then it increases the tumor mutational burden and therefore the likelihood of developing cancer at an earlier age. 

All of us believe that converting a normal cell into a tumor cell usually requires five or six or seven separate mutational events occurring at random. The earlier these occur, the greater the tumor, the greater the normal single-cellular mutational burden, and the more likely it is to develop cancer sooner rather than later. 

This is a fantastically interesting study, and it’s the way ahead with modern genetic epidemiology, one would say. We wish them well. This will be a 3- to 5-year truly international effort, bringing together a genuinely internationally outstanding research team. We hope that they are able to shed more light on the epidemiology of this early-onset disease, because only by understanding can we deflect and deal with it. 

Knowledge is power, as I’ve said many times before. If we understand the underlying epidemiology, that will allow us to intervene, one would hope, and avoid the chaotic disaster of my clinic on Friday, with these two young patients with an extremely limited lifespan and large families who will be left bereft in having lost a parent.

More power to the team. We wish them well with the study, but again, this is a pointer to the future, one would hope, of modern genetic computational epidemiology. 

I’d be really interested in any ideas or comments that you might have. Are you in the field? Are you seeing more young patients? Do you have any ideas or hypotheses of your own around the microbiome and what bugs might be involved and so on?

Dr. Kerr, Professor, Nuffield Department of Clinical Laboratory Science, University of Oxford, England; Professor of Cancer Medicine, Oxford Cancer Centre, Oxford, United Kingdom, has disclosed relevant financial relationships with Celleron Therapeutics, Oxford Cancer Biomarkers, Afrox, GlaxoSmithKline, Bayer, Genomic Health, Merck Serono, and Roche. 

A version of this article appeared on Medscape.com.

This transcript has been edited for clarity. 

I’d like to reflect a little on the ever-rising incidence of early-onset colorectal cancer. I saw two patients in the clinic on Friday, both in their early thirties, presenting with stage IV disease. Both had young families — a disaster.

This is an issue that we must address, I think, epidemiologically. We know that early-onset colorectal cancer is defined as a disease arising in those under the age of 50. There’s been a very sharp increase globally over the past 20-30 years, and currently, around 200,000 such cases are diagnosed every year, but it is said to increase unquestionably.

The epidemiologists, I think, correctly have identified that this sharp, rapid increase does imply that there is a new environmental change that is underpinning or underscoring this rise in early-onset disease. 

There’s a fantastic team that has been put together by Paul Brennan, Mike Stratton, and colleagues, a collaborative group of epidemiologists, geneticists, and bioinformaticians, who are looking at a global study to try to understand the basis of early-onset colorectal cancer. Their approach is to combine conventional epidemiology, genomics, and fantastic computational support to try to unpick the mutational signatures involved.

The dominant hypothesis is that, over the past 20-25 years or so, there has been a change in diet that has allowed an alteration in the gut microbiome such that we now harbor, in some cases, more bacteria capable of manufacturing, synthesizing, and releasing mutagenic chemicals. There’s a subtype of Escherichia coli which manufactures one such mutagen called colibactin.

Again, through some of the painstaking, extraordinary work that Mike Stratton and colleagues have done at the Sanger Institute, they have managed to, using a variety of different techniques — in vitro, observational, and so on — relate exposure to the mutagen colibactin to a particular mutational signature.

They plan to do a large global study — one of the strengths — involving many different countries around the globe, collect material from older colorectal cancer patients and early-onset colorectal cancer patients, and undertake a staggeringly large mutational study to see if the mutational signature associated with colibactin is more highly represented in these early-onset cases. The hypothesis is that, if you’re exposed to this mutagen in childhood, then it increases the tumor mutational burden and therefore the likelihood of developing cancer at an earlier age. 

All of us believe that converting a normal cell into a tumor cell usually requires five or six or seven separate mutational events occurring at random. The earlier these occur, the greater the tumor, the greater the normal single-cellular mutational burden, and the more likely it is to develop cancer sooner rather than later. 

This is a fantastically interesting study, and it’s the way ahead with modern genetic epidemiology, one would say. We wish them well. This will be a 3- to 5-year truly international effort, bringing together a genuinely internationally outstanding research team. We hope that they are able to shed more light on the epidemiology of this early-onset disease, because only by understanding can we deflect and deal with it. 

Knowledge is power, as I’ve said many times before. If we understand the underlying epidemiology, that will allow us to intervene, one would hope, and avoid the chaotic disaster of my clinic on Friday, with these two young patients with an extremely limited lifespan and large families who will be left bereft in having lost a parent.

More power to the team. We wish them well with the study, but again, this is a pointer to the future, one would hope, of modern genetic computational epidemiology. 

I’d be really interested in any ideas or comments that you might have. Are you in the field? Are you seeing more young patients? Do you have any ideas or hypotheses of your own around the microbiome and what bugs might be involved and so on?

Dr. Kerr, Professor, Nuffield Department of Clinical Laboratory Science, University of Oxford, England; Professor of Cancer Medicine, Oxford Cancer Centre, Oxford, United Kingdom, has disclosed relevant financial relationships with Celleron Therapeutics, Oxford Cancer Biomarkers, Afrox, GlaxoSmithKline, Bayer, Genomic Health, Merck Serono, and Roche. 

A version of this article appeared on Medscape.com.

This transcript has been edited for clarity. 

I’d like to reflect a little on the ever-rising incidence of early-onset colorectal cancer. I saw two patients in the clinic on Friday, both in their early thirties, presenting with stage IV disease. Both had young families — a disaster.

This is an issue that we must address, I think, epidemiologically. We know that early-onset colorectal cancer is defined as a disease arising in those under the age of 50. There’s been a very sharp increase globally over the past 20-30 years, and currently, around 200,000 such cases are diagnosed every year, but it is said to increase unquestionably.

The epidemiologists, I think, correctly have identified that this sharp, rapid increase does imply that there is a new environmental change that is underpinning or underscoring this rise in early-onset disease. 

There’s a fantastic team that has been put together by Paul Brennan, Mike Stratton, and colleagues, a collaborative group of epidemiologists, geneticists, and bioinformaticians, who are looking at a global study to try to understand the basis of early-onset colorectal cancer. Their approach is to combine conventional epidemiology, genomics, and fantastic computational support to try to unpick the mutational signatures involved.

The dominant hypothesis is that, over the past 20-25 years or so, there has been a change in diet that has allowed an alteration in the gut microbiome such that we now harbor, in some cases, more bacteria capable of manufacturing, synthesizing, and releasing mutagenic chemicals. There’s a subtype of Escherichia coli which manufactures one such mutagen called colibactin.

Again, through some of the painstaking, extraordinary work that Mike Stratton and colleagues have done at the Sanger Institute, they have managed to, using a variety of different techniques — in vitro, observational, and so on — relate exposure to the mutagen colibactin to a particular mutational signature.

They plan to do a large global study — one of the strengths — involving many different countries around the globe, collect material from older colorectal cancer patients and early-onset colorectal cancer patients, and undertake a staggeringly large mutational study to see if the mutational signature associated with colibactin is more highly represented in these early-onset cases. The hypothesis is that, if you’re exposed to this mutagen in childhood, then it increases the tumor mutational burden and therefore the likelihood of developing cancer at an earlier age. 

All of us believe that converting a normal cell into a tumor cell usually requires five or six or seven separate mutational events occurring at random. The earlier these occur, the greater the tumor, the greater the normal single-cellular mutational burden, and the more likely it is to develop cancer sooner rather than later. 

This is a fantastically interesting study, and it’s the way ahead with modern genetic epidemiology, one would say. We wish them well. This will be a 3- to 5-year truly international effort, bringing together a genuinely internationally outstanding research team. We hope that they are able to shed more light on the epidemiology of this early-onset disease, because only by understanding can we deflect and deal with it. 

Knowledge is power, as I’ve said many times before. If we understand the underlying epidemiology, that will allow us to intervene, one would hope, and avoid the chaotic disaster of my clinic on Friday, with these two young patients with an extremely limited lifespan and large families who will be left bereft in having lost a parent.

More power to the team. We wish them well with the study, but again, this is a pointer to the future, one would hope, of modern genetic computational epidemiology. 

I’d be really interested in any ideas or comments that you might have. Are you in the field? Are you seeing more young patients? Do you have any ideas or hypotheses of your own around the microbiome and what bugs might be involved and so on?

Dr. Kerr, Professor, Nuffield Department of Clinical Laboratory Science, University of Oxford, England; Professor of Cancer Medicine, Oxford Cancer Centre, Oxford, United Kingdom, has disclosed relevant financial relationships with Celleron Therapeutics, Oxford Cancer Biomarkers, Afrox, GlaxoSmithKline, Bayer, Genomic Health, Merck Serono, and Roche. 

A version of this article appeared on Medscape.com.

TOPLINE:

Proprotein convertase subtilisin/kexin type 9 (PCSK9) inhibitors, lipid-lowering drugs, were associated with a 22% lower risk for nonmelanoma skin cancer (NMSC) in patients with atherosclerotic cardiovascular disease (ASCVD), an effect that was particularly significant among men, those older than 65 years, and those with immunosuppression.

METHODOLOGY:

• To evaluate the risk for NMSC — basal cell carcinoma (BCC) and squamous cell carcinoma (SCC) — in patients with ASCVD on PCSK9 inhibitors, researchers analyzed data from the US Collaborative Network in the TriNetX database of adults aged ≥ 40 years with ASCVD who received statin therapy between 2016 and 2022.
• A total of 73,636 patients were included, divided equally between those receiving a PCSK9 inhibitor (evolocumab, alirocumab, or inclisiran) plus statin therapy and the control group (those on statin therapy only).
• The analysis used propensity score matching for head-to-head comparisons, with hazard ratios (HRs) estimated using Cox proportional hazard models.
• Stratified analyses examined outcomes by age, sex, Fitzpatrick skin type, and immune status. (Immunosuppressed patients were those treated with immunosuppressants for more than 90 days in the year before the index date — the date when exposed patients were first prescribed a PCSK9 inhibitor, which was also index date for matched patients in the statin-only group.)

TAKEAWAY:

• Patients with ASCVD in the PCSK9 group showed significantly lower risks for NMSC (HR, 0.78; 95% CI, 0.71-0.87), BCC (HR, 0.78; 95% CI, 0.69-0.89), and SCC (HR, 0.79; 95% CI, 0.67-0.93) than control individuals on a statin only (P < .001 for all three).
• Both evolocumab and alirocumab demonstrated similar protective effects against the development of NMSC.
• The reduced risk for NMSC was particularly notable among patients aged 65-79 years (HR, 0.75; 95% CI, 0.66-0.86) and those aged ≥ 80 years (HR, 0.74; 95% CI, 0.60-0.91).
• Men showed a more pronounced reduction in the risk for NMSC (HR, 0.73; 95% CI, 0.64-0.83) than women (HR, 0.93; 95% CI, 0.78-1.11). The effect on lowering NMSC risk was also evident among immunosuppressed patients in the PCSK9 group (HR, 0.68; 95% CI, 0.60-0.75).

IN PRACTICE:

“The findings suggest the promising pleiotropic effect of PCSK9 inhibitors on the chemoprevention of NMSC,” the study authors wrote. Referring to previous studies that “provided mechanistic clues to our findings,” they added that “further studies are required to investigate the underlying mechanisms and establish causality.”

SOURCE:

The study was led by Cheng-Yuan Li, Taipei Veterans General Hospital, Taipei, Taiwan, and was published online in The British Journal of Dermatology.

LIMITATIONS:

Electronic health records lack information on sun protection habits, family history of skin cancer, diet, body mass index, and air pollution exposure, risk factors for NMSC. The study also lacked detailed information on enrollees’ lipid profiles and was focused mostly on patients in the United States, limiting the generalizability of the findings to other regions.

DISCLOSURES:

The study was supported by grants from Taipei Veterans General Hospital and the Ministry of Science and Technology, Taiwan. The authors reported no conflicts of interest.

This article was created using several editorial tools, including AI, as part of the process. Human editors reviewed this content before publication. A version of this article first appeared on Medscape.com.

TOPLINE:

Proprotein convertase subtilisin/kexin type 9 (PCSK9) inhibitors, lipid-lowering drugs, were associated with a 22% lower risk for nonmelanoma skin cancer (NMSC) in patients with atherosclerotic cardiovascular disease (ASCVD), an effect that was particularly significant among men, those older than 65 years, and those with immunosuppression.

METHODOLOGY:

• To evaluate the risk for NMSC — basal cell carcinoma (BCC) and squamous cell carcinoma (SCC) — in patients with ASCVD on PCSK9 inhibitors, researchers analyzed data from the US Collaborative Network in the TriNetX database of adults aged ≥ 40 years with ASCVD who received statin therapy between 2016 and 2022.
• A total of 73,636 patients were included, divided equally between those receiving a PCSK9 inhibitor (evolocumab, alirocumab, or inclisiran) plus statin therapy and the control group (those on statin therapy only).
• The analysis used propensity score matching for head-to-head comparisons, with hazard ratios (HRs) estimated using Cox proportional hazard models.
• Stratified analyses examined outcomes by age, sex, Fitzpatrick skin type, and immune status. (Immunosuppressed patients were those treated with immunosuppressants for more than 90 days in the year before the index date — the date when exposed patients were first prescribed a PCSK9 inhibitor, which was also index date for matched patients in the statin-only group.)

TAKEAWAY:

• Patients with ASCVD in the PCSK9 group showed significantly lower risks for NMSC (HR, 0.78; 95% CI, 0.71-0.87), BCC (HR, 0.78; 95% CI, 0.69-0.89), and SCC (HR, 0.79; 95% CI, 0.67-0.93) than control individuals on a statin only (P < .001 for all three).
• Both evolocumab and alirocumab demonstrated similar protective effects against the development of NMSC.
• The reduced risk for NMSC was particularly notable among patients aged 65-79 years (HR, 0.75; 95% CI, 0.66-0.86) and those aged ≥ 80 years (HR, 0.74; 95% CI, 0.60-0.91).
• Men showed a more pronounced reduction in the risk for NMSC (HR, 0.73; 95% CI, 0.64-0.83) than women (HR, 0.93; 95% CI, 0.78-1.11). The effect on lowering NMSC risk was also evident among immunosuppressed patients in the PCSK9 group (HR, 0.68; 95% CI, 0.60-0.75).

IN PRACTICE:

“The findings suggest the promising pleiotropic effect of PCSK9 inhibitors on the chemoprevention of NMSC,” the study authors wrote. Referring to previous studies that “provided mechanistic clues to our findings,” they added that “further studies are required to investigate the underlying mechanisms and establish causality.”

SOURCE:

The study was led by Cheng-Yuan Li, Taipei Veterans General Hospital, Taipei, Taiwan, and was published online in The British Journal of Dermatology.

LIMITATIONS:

Electronic health records lack information on sun protection habits, family history of skin cancer, diet, body mass index, and air pollution exposure, risk factors for NMSC. The study also lacked detailed information on enrollees’ lipid profiles and was focused mostly on patients in the United States, limiting the generalizability of the findings to other regions.

DISCLOSURES:

The study was supported by grants from Taipei Veterans General Hospital and the Ministry of Science and Technology, Taiwan. The authors reported no conflicts of interest.

This article was created using several editorial tools, including AI, as part of the process. Human editors reviewed this content before publication. A version of this article first appeared on Medscape.com.

TOPLINE:

Proprotein convertase subtilisin/kexin type 9 (PCSK9) inhibitors, lipid-lowering drugs, were associated with a 22% lower risk for nonmelanoma skin cancer (NMSC) in patients with atherosclerotic cardiovascular disease (ASCVD), an effect that was particularly significant among men, those older than 65 years, and those with immunosuppression.

METHODOLOGY:

• To evaluate the risk for NMSC — basal cell carcinoma (BCC) and squamous cell carcinoma (SCC) — in patients with ASCVD on PCSK9 inhibitors, researchers analyzed data from the US Collaborative Network in the TriNetX database of adults aged ≥ 40 years with ASCVD who received statin therapy between 2016 and 2022.
• A total of 73,636 patients were included, divided equally between those receiving a PCSK9 inhibitor (evolocumab, alirocumab, or inclisiran) plus statin therapy and the control group (those on statin therapy only).
• The analysis used propensity score matching for head-to-head comparisons, with hazard ratios (HRs) estimated using Cox proportional hazard models.
• Stratified analyses examined outcomes by age, sex, Fitzpatrick skin type, and immune status. (Immunosuppressed patients were those treated with immunosuppressants for more than 90 days in the year before the index date — the date when exposed patients were first prescribed a PCSK9 inhibitor, which was also index date for matched patients in the statin-only group.)

TAKEAWAY:

• Patients with ASCVD in the PCSK9 group showed significantly lower risks for NMSC (HR, 0.78; 95% CI, 0.71-0.87), BCC (HR, 0.78; 95% CI, 0.69-0.89), and SCC (HR, 0.79; 95% CI, 0.67-0.93) than control individuals on a statin only (P < .001 for all three).
• Both evolocumab and alirocumab demonstrated similar protective effects against the development of NMSC.
• The reduced risk for NMSC was particularly notable among patients aged 65-79 years (HR, 0.75; 95% CI, 0.66-0.86) and those aged ≥ 80 years (HR, 0.74; 95% CI, 0.60-0.91).
• Men showed a more pronounced reduction in the risk for NMSC (HR, 0.73; 95% CI, 0.64-0.83) than women (HR, 0.93; 95% CI, 0.78-1.11). The effect on lowering NMSC risk was also evident among immunosuppressed patients in the PCSK9 group (HR, 0.68; 95% CI, 0.60-0.75).

IN PRACTICE:

“The findings suggest the promising pleiotropic effect of PCSK9 inhibitors on the chemoprevention of NMSC,” the study authors wrote. Referring to previous studies that “provided mechanistic clues to our findings,” they added that “further studies are required to investigate the underlying mechanisms and establish causality.”

SOURCE:

The study was led by Cheng-Yuan Li, Taipei Veterans General Hospital, Taipei, Taiwan, and was published online in The British Journal of Dermatology.

LIMITATIONS:

Electronic health records lack information on sun protection habits, family history of skin cancer, diet, body mass index, and air pollution exposure, risk factors for NMSC. The study also lacked detailed information on enrollees’ lipid profiles and was focused mostly on patients in the United States, limiting the generalizability of the findings to other regions.

DISCLOSURES:

The study was supported by grants from Taipei Veterans General Hospital and the Ministry of Science and Technology, Taiwan. The authors reported no conflicts of interest.

This article was created using several editorial tools, including AI, as part of the process. Human editors reviewed this content before publication. A version of this article first appeared on Medscape.com.

Vaccines for treating and preventing cancer have long been considered a holy grail in oncology.

But aside from a few notable exceptions — including the human papillomavirus (HPV) vaccine, which has dramatically reduced the incidence of HPV-related cancers, and a Bacillus Calmette-Guerin vaccine, which helps prevent early-stage bladder cancer recurrence — most have failed to deliver.

Following a string of disappointments over the past decade, recent advances in the immunotherapy space are bringing renewed hope for progress.

In an American Association for Cancer Research (AACR) series earlier in 2024, Catherine J. Wu, MD, predicted big strides for cancer vaccines, especially for personalized vaccines that target patient-specific neoantigens — the proteins that form on cancer cells — as well as vaccines that can treat diverse tumor types.

“A focus on neoantigens that arise from driver mutations in different tumor types could allow us to make progress in creating off-the-shelf vaccines,” said Wu, the Lavine Family Chair of Preventative Cancer Therapies at Dana-Farber Cancer Institute and a professor of medicine at Harvard Medical School, both in Boston, Massachusetts.

A prime example is a personalized, messenger RNA (mRNA)–based vaccine designed to prevent melanoma recurrence. The mRNA-4157 vaccine encodes up to 34 different patient-specific neoantigens.

“This is one of the most exciting developments in modern cancer therapy,” said Lawrence Young, a virologist and professor of molecular oncology at the University of Warwick, Coventry, England, who commented on the investigational vaccine via the UK-based Science Media Centre.

Other promising options are on the horizon as well. In August, BioNTech announced a phase 1 global trial to study BNT116 — a vaccine to treat non–small cell lung cancer (NSCLC). BNT116, like mRNA-4157, targets specific antigens in the lung cancer cells.

“This technology is the next big phase of cancer treatment,” Siow Ming Lee, MD, a consultant medical oncologist at University College London Hospitals in England, which is leading the UK trial for the lung cancer and melanoma vaccines, told The Guardian. “We are now entering this very exciting new era of mRNA-based immunotherapy clinical trials to investigate the treatment of lung cancer.”

Still, these predictions have a familiar ring. While the prospects are exciting, delivering on them is another story. There are simply no guarantees these strategies will work as hoped.

 

Then: Where We Were

Cancer vaccine research began to ramp up in the 2000s, and in 2006, the first-generation HPV vaccine, Gardasil, was approved. Gardasil prevents infection from four strains of HPV that cause about 80% of cervical cancer cases.

In 2010, the Food and Drug Administration approved sipuleucel-T, the first therapeutic cancer vaccine, which improved overall survival in patients with hormone-refractory prostate cancer.

Researchers predicted this approval would “pave the way for developing innovative, next generation of vaccines with enhanced antitumor potency.”

In a 2015 AACR research forecast report, Drew Pardoll, MD, PhD, co-director of the Cancer Immunology and Hematopoiesis Program at Johns Hopkins University, Baltimore, Maryland, said that “we can expect to see encouraging results from studies using cancer vaccines.”

Despite the excitement surrounding cancer vaccines alongside a few successes, the next decade brought a longer string of late-phase disappointments.

In 2016, the phase 3 ACT IV trial of a therapeutic vaccine to treat glioblastoma multiforme (CDX-110) was terminated after it failed to demonstrate improved survival.

In 2017, a phase 3 trial of the therapeutic pancreatic cancer vaccine, GVAX, was stopped early for lack of efficacy.

That year, an attenuated Listeria monocytogenes vaccine to treat pancreatic cancer and mesothelioma also failed to come to fruition. In late 2017, concerns over listeria infections prompted Aduro Biotech to cancel its listeria-based cancer treatment program.

In 2018, a phase 3 trial of belagenpumatucel-L, a therapeutic NSCLC vaccine, failed to demonstrate a significant improvement in survival and further study was discontinued.

And in 2019, a vaccine targeting MAGE-A3, a cancer-testis antigen present in multiple tumor types, failed to meet endpoints for improved survival in a phase 3 trial, leading to discontinuation of the vaccine program.

But these disappointments and failures are normal parts of medical research and drug development and have allowed for incremental advances that helped fuel renewed interest and hope for cancer vaccines, when the timing was right, explained vaccine pioneer Larry W. Kwak, MD, PhD, deputy director of the Comprehensive Cancer Center at City of Hope, Duarte, California.

When it comes to vaccine progress, timing makes a difference. In 2011, Kwak and colleagues published promising phase 3 trial results on a personalized vaccine. The vaccine was a patient-specific tumor-derived antigen for patients with follicular lymphoma in their first remission following chemotherapy. Patients who received the vaccine demonstrated significantly longer disease-free survival.

But, at the time, personalized vaccines faced strong headwinds due, largely, to high costs, and commercial interest failed to materialize. “That’s been the major hurdle for a long time,” said Kwak.

Now, however, interest has returned alongside advances in technology and research. The big shift has been the emergence of lower-cost rapid-production mRNA and DNA platforms and a better understanding of how vaccines and potent immune stimulants, like checkpoint inhibitors, can work together to improve outcomes, he explained.

“The timing wasn’t right” back then, Kwak noted. “Now, it’s a different environment and a different time.”

 

A Turning Point?

Indeed, a decade later, cancer vaccine development appears to be headed in a more promising direction.

Among key cancer vaccines to watch is the mRNA-4157 vaccine, developed by Merck and Moderna, designed to prevent melanoma recurrence. In a recent phase 2 study, patients receiving the mRNA-4157 vaccine alongside pembrolizumab had nearly half the risk for melanoma recurrence or death at 3 years compared with those receiving pembrolizumab alone. Investigators are now evaluating the vaccine in a global phase 3 study in patients with high-risk, stage IIB to IV melanoma following surgery.

Another one to watch is the BNT116 NSCLC vaccine from BioNTech. This vaccine presents the immune system with NSCLC tumor markers to encourage the body to fight cancer cells expressing those markers while ignoring healthy cells. BioNTech also launched a global clinical trial for its vaccine this year.

Other notables include a pancreatic cancer mRNA vaccine, which has shown promising early results in a small trial of 16 patients. Of 16 patients who received the vaccine alongside chemotherapy and after surgery and immunotherapy, 8 responded. Of these eight, six remained recurrence free at 3 years. Investigators noted that the vaccine appeared to stimulate a durable T-cell response in patients who responded.

Kwak has also continued his work on lymphoma vaccines. In August, his team published promising first-in-human data on the use of personalized neoantigen vaccines as an early intervention in untreated patients with lymphoplasmacytic lymphoma. Among nine asymptomatic patients who received the vaccine, all achieved stable disease or better, with no dose-limiting toxicities. One patient had a minor response, and the median time to progression was greater than 72 months.

“The current setting is more for advanced disease,” Kwak explained. “It’s a tougher task, but combined with checkpoint blockade, it may be potent enough to work.” 

Still, caution is important. Despite early promise, it’s too soon to tell which, if any, of these investigational vaccines will pan out in the long run. Like investigational drugs, cancer vaccines may show big promising initially but then fail in larger trials.

One key to success, according to Kwak, is to design trials so that even negative results will inform next steps.

But, he noted, failures in large clinical trials will “put a chilling effect on cancer vaccine research again.”

“That’s what keeps me up at night,” he said. “We know the science is fundamentally sound and we have seen glimpses over decades of research that cancer vaccines can work, so it’s really just a matter of tweaking things to optimize trial design.”

Companies tend to design trials to test if a vaccine works or not, without trying to understand why, he said.

“What we need to do is design those so that we can learn from negative results,” he said. That’s what he and his colleagues attempted to do in their recent trial. “We didn’t just look at clinical results; we’re interrogating the actual tumor environment to understand what worked and didn’t and how to tweak that for the next trial.”

Kwak and his colleagues found, for instance, that the vaccine had a greater effect on B cell–derived tumor cells than on cells of plasma origin, so “the most rational design for the next iteration is to combine the vaccine with agents that work directly against plasma cells,” he explained.

As for what’s next, Kwak said: “We’re just focused on trying to do good science and understand. We’ve seen glimpses of success. That’s where we are.”

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

Vaccines for treating and preventing cancer have long been considered a holy grail in oncology.

But aside from a few notable exceptions — including the human papillomavirus (HPV) vaccine, which has dramatically reduced the incidence of HPV-related cancers, and a Bacillus Calmette-Guerin vaccine, which helps prevent early-stage bladder cancer recurrence — most have failed to deliver.

Following a string of disappointments over the past decade, recent advances in the immunotherapy space are bringing renewed hope for progress.

In an American Association for Cancer Research (AACR) series earlier in 2024, Catherine J. Wu, MD, predicted big strides for cancer vaccines, especially for personalized vaccines that target patient-specific neoantigens — the proteins that form on cancer cells — as well as vaccines that can treat diverse tumor types.

“A focus on neoantigens that arise from driver mutations in different tumor types could allow us to make progress in creating off-the-shelf vaccines,” said Wu, the Lavine Family Chair of Preventative Cancer Therapies at Dana-Farber Cancer Institute and a professor of medicine at Harvard Medical School, both in Boston, Massachusetts.

A prime example is a personalized, messenger RNA (mRNA)–based vaccine designed to prevent melanoma recurrence. The mRNA-4157 vaccine encodes up to 34 different patient-specific neoantigens.

“This is one of the most exciting developments in modern cancer therapy,” said Lawrence Young, a virologist and professor of molecular oncology at the University of Warwick, Coventry, England, who commented on the investigational vaccine via the UK-based Science Media Centre.

Other promising options are on the horizon as well. In August, BioNTech announced a phase 1 global trial to study BNT116 — a vaccine to treat non–small cell lung cancer (NSCLC). BNT116, like mRNA-4157, targets specific antigens in the lung cancer cells.

“This technology is the next big phase of cancer treatment,” Siow Ming Lee, MD, a consultant medical oncologist at University College London Hospitals in England, which is leading the UK trial for the lung cancer and melanoma vaccines, told The Guardian. “We are now entering this very exciting new era of mRNA-based immunotherapy clinical trials to investigate the treatment of lung cancer.”

Still, these predictions have a familiar ring. While the prospects are exciting, delivering on them is another story. There are simply no guarantees these strategies will work as hoped.

 

Then: Where We Were

Cancer vaccine research began to ramp up in the 2000s, and in 2006, the first-generation HPV vaccine, Gardasil, was approved. Gardasil prevents infection from four strains of HPV that cause about 80% of cervical cancer cases.

In 2010, the Food and Drug Administration approved sipuleucel-T, the first therapeutic cancer vaccine, which improved overall survival in patients with hormone-refractory prostate cancer.

Researchers predicted this approval would “pave the way for developing innovative, next generation of vaccines with enhanced antitumor potency.”

In a 2015 AACR research forecast report, Drew Pardoll, MD, PhD, co-director of the Cancer Immunology and Hematopoiesis Program at Johns Hopkins University, Baltimore, Maryland, said that “we can expect to see encouraging results from studies using cancer vaccines.”

Despite the excitement surrounding cancer vaccines alongside a few successes, the next decade brought a longer string of late-phase disappointments.

In 2016, the phase 3 ACT IV trial of a therapeutic vaccine to treat glioblastoma multiforme (CDX-110) was terminated after it failed to demonstrate improved survival.

In 2017, a phase 3 trial of the therapeutic pancreatic cancer vaccine, GVAX, was stopped early for lack of efficacy.

That year, an attenuated Listeria monocytogenes vaccine to treat pancreatic cancer and mesothelioma also failed to come to fruition. In late 2017, concerns over listeria infections prompted Aduro Biotech to cancel its listeria-based cancer treatment program.

In 2018, a phase 3 trial of belagenpumatucel-L, a therapeutic NSCLC vaccine, failed to demonstrate a significant improvement in survival and further study was discontinued.

And in 2019, a vaccine targeting MAGE-A3, a cancer-testis antigen present in multiple tumor types, failed to meet endpoints for improved survival in a phase 3 trial, leading to discontinuation of the vaccine program.

But these disappointments and failures are normal parts of medical research and drug development and have allowed for incremental advances that helped fuel renewed interest and hope for cancer vaccines, when the timing was right, explained vaccine pioneer Larry W. Kwak, MD, PhD, deputy director of the Comprehensive Cancer Center at City of Hope, Duarte, California.

When it comes to vaccine progress, timing makes a difference. In 2011, Kwak and colleagues published promising phase 3 trial results on a personalized vaccine. The vaccine was a patient-specific tumor-derived antigen for patients with follicular lymphoma in their first remission following chemotherapy. Patients who received the vaccine demonstrated significantly longer disease-free survival.

But, at the time, personalized vaccines faced strong headwinds due, largely, to high costs, and commercial interest failed to materialize. “That’s been the major hurdle for a long time,” said Kwak.

Now, however, interest has returned alongside advances in technology and research. The big shift has been the emergence of lower-cost rapid-production mRNA and DNA platforms and a better understanding of how vaccines and potent immune stimulants, like checkpoint inhibitors, can work together to improve outcomes, he explained.

“The timing wasn’t right” back then, Kwak noted. “Now, it’s a different environment and a different time.”

 

A Turning Point?

Indeed, a decade later, cancer vaccine development appears to be headed in a more promising direction.

Among key cancer vaccines to watch is the mRNA-4157 vaccine, developed by Merck and Moderna, designed to prevent melanoma recurrence. In a recent phase 2 study, patients receiving the mRNA-4157 vaccine alongside pembrolizumab had nearly half the risk for melanoma recurrence or death at 3 years compared with those receiving pembrolizumab alone. Investigators are now evaluating the vaccine in a global phase 3 study in patients with high-risk, stage IIB to IV melanoma following surgery.

Another one to watch is the BNT116 NSCLC vaccine from BioNTech. This vaccine presents the immune system with NSCLC tumor markers to encourage the body to fight cancer cells expressing those markers while ignoring healthy cells. BioNTech also launched a global clinical trial for its vaccine this year.

Other notables include a pancreatic cancer mRNA vaccine, which has shown promising early results in a small trial of 16 patients. Of 16 patients who received the vaccine alongside chemotherapy and after surgery and immunotherapy, 8 responded. Of these eight, six remained recurrence free at 3 years. Investigators noted that the vaccine appeared to stimulate a durable T-cell response in patients who responded.

Kwak has also continued his work on lymphoma vaccines. In August, his team published promising first-in-human data on the use of personalized neoantigen vaccines as an early intervention in untreated patients with lymphoplasmacytic lymphoma. Among nine asymptomatic patients who received the vaccine, all achieved stable disease or better, with no dose-limiting toxicities. One patient had a minor response, and the median time to progression was greater than 72 months.

“The current setting is more for advanced disease,” Kwak explained. “It’s a tougher task, but combined with checkpoint blockade, it may be potent enough to work.” 

Still, caution is important. Despite early promise, it’s too soon to tell which, if any, of these investigational vaccines will pan out in the long run. Like investigational drugs, cancer vaccines may show big promising initially but then fail in larger trials.

One key to success, according to Kwak, is to design trials so that even negative results will inform next steps.

But, he noted, failures in large clinical trials will “put a chilling effect on cancer vaccine research again.”

“That’s what keeps me up at night,” he said. “We know the science is fundamentally sound and we have seen glimpses over decades of research that cancer vaccines can work, so it’s really just a matter of tweaking things to optimize trial design.”

Companies tend to design trials to test if a vaccine works or not, without trying to understand why, he said.

“What we need to do is design those so that we can learn from negative results,” he said. That’s what he and his colleagues attempted to do in their recent trial. “We didn’t just look at clinical results; we’re interrogating the actual tumor environment to understand what worked and didn’t and how to tweak that for the next trial.”

Kwak and his colleagues found, for instance, that the vaccine had a greater effect on B cell–derived tumor cells than on cells of plasma origin, so “the most rational design for the next iteration is to combine the vaccine with agents that work directly against plasma cells,” he explained.

As for what’s next, Kwak said: “We’re just focused on trying to do good science and understand. We’ve seen glimpses of success. That’s where we are.”

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

Vaccines for treating and preventing cancer have long been considered a holy grail in oncology.

But aside from a few notable exceptions — including the human papillomavirus (HPV) vaccine, which has dramatically reduced the incidence of HPV-related cancers, and a Bacillus Calmette-Guerin vaccine, which helps prevent early-stage bladder cancer recurrence — most have failed to deliver.

Following a string of disappointments over the past decade, recent advances in the immunotherapy space are bringing renewed hope for progress.

In an American Association for Cancer Research (AACR) series earlier in 2024, Catherine J. Wu, MD, predicted big strides for cancer vaccines, especially for personalized vaccines that target patient-specific neoantigens — the proteins that form on cancer cells — as well as vaccines that can treat diverse tumor types.

“A focus on neoantigens that arise from driver mutations in different tumor types could allow us to make progress in creating off-the-shelf vaccines,” said Wu, the Lavine Family Chair of Preventative Cancer Therapies at Dana-Farber Cancer Institute and a professor of medicine at Harvard Medical School, both in Boston, Massachusetts.

A prime example is a personalized, messenger RNA (mRNA)–based vaccine designed to prevent melanoma recurrence. The mRNA-4157 vaccine encodes up to 34 different patient-specific neoantigens.

“This is one of the most exciting developments in modern cancer therapy,” said Lawrence Young, a virologist and professor of molecular oncology at the University of Warwick, Coventry, England, who commented on the investigational vaccine via the UK-based Science Media Centre.

Other promising options are on the horizon as well. In August, BioNTech announced a phase 1 global trial to study BNT116 — a vaccine to treat non–small cell lung cancer (NSCLC). BNT116, like mRNA-4157, targets specific antigens in the lung cancer cells.

“This technology is the next big phase of cancer treatment,” Siow Ming Lee, MD, a consultant medical oncologist at University College London Hospitals in England, which is leading the UK trial for the lung cancer and melanoma vaccines, told The Guardian. “We are now entering this very exciting new era of mRNA-based immunotherapy clinical trials to investigate the treatment of lung cancer.”

Still, these predictions have a familiar ring. While the prospects are exciting, delivering on them is another story. There are simply no guarantees these strategies will work as hoped.

 

Then: Where We Were

Cancer vaccine research began to ramp up in the 2000s, and in 2006, the first-generation HPV vaccine, Gardasil, was approved. Gardasil prevents infection from four strains of HPV that cause about 80% of cervical cancer cases.

In 2010, the Food and Drug Administration approved sipuleucel-T, the first therapeutic cancer vaccine, which improved overall survival in patients with hormone-refractory prostate cancer.

Researchers predicted this approval would “pave the way for developing innovative, next generation of vaccines with enhanced antitumor potency.”

In a 2015 AACR research forecast report, Drew Pardoll, MD, PhD, co-director of the Cancer Immunology and Hematopoiesis Program at Johns Hopkins University, Baltimore, Maryland, said that “we can expect to see encouraging results from studies using cancer vaccines.”

Despite the excitement surrounding cancer vaccines alongside a few successes, the next decade brought a longer string of late-phase disappointments.

In 2016, the phase 3 ACT IV trial of a therapeutic vaccine to treat glioblastoma multiforme (CDX-110) was terminated after it failed to demonstrate improved survival.

In 2017, a phase 3 trial of the therapeutic pancreatic cancer vaccine, GVAX, was stopped early for lack of efficacy.

That year, an attenuated Listeria monocytogenes vaccine to treat pancreatic cancer and mesothelioma also failed to come to fruition. In late 2017, concerns over listeria infections prompted Aduro Biotech to cancel its listeria-based cancer treatment program.

In 2018, a phase 3 trial of belagenpumatucel-L, a therapeutic NSCLC vaccine, failed to demonstrate a significant improvement in survival and further study was discontinued.

And in 2019, a vaccine targeting MAGE-A3, a cancer-testis antigen present in multiple tumor types, failed to meet endpoints for improved survival in a phase 3 trial, leading to discontinuation of the vaccine program.

But these disappointments and failures are normal parts of medical research and drug development and have allowed for incremental advances that helped fuel renewed interest and hope for cancer vaccines, when the timing was right, explained vaccine pioneer Larry W. Kwak, MD, PhD, deputy director of the Comprehensive Cancer Center at City of Hope, Duarte, California.

When it comes to vaccine progress, timing makes a difference. In 2011, Kwak and colleagues published promising phase 3 trial results on a personalized vaccine. The vaccine was a patient-specific tumor-derived antigen for patients with follicular lymphoma in their first remission following chemotherapy. Patients who received the vaccine demonstrated significantly longer disease-free survival.

But, at the time, personalized vaccines faced strong headwinds due, largely, to high costs, and commercial interest failed to materialize. “That’s been the major hurdle for a long time,” said Kwak.

Now, however, interest has returned alongside advances in technology and research. The big shift has been the emergence of lower-cost rapid-production mRNA and DNA platforms and a better understanding of how vaccines and potent immune stimulants, like checkpoint inhibitors, can work together to improve outcomes, he explained.

“The timing wasn’t right” back then, Kwak noted. “Now, it’s a different environment and a different time.”

 

A Turning Point?

Indeed, a decade later, cancer vaccine development appears to be headed in a more promising direction.

Among key cancer vaccines to watch is the mRNA-4157 vaccine, developed by Merck and Moderna, designed to prevent melanoma recurrence. In a recent phase 2 study, patients receiving the mRNA-4157 vaccine alongside pembrolizumab had nearly half the risk for melanoma recurrence or death at 3 years compared with those receiving pembrolizumab alone. Investigators are now evaluating the vaccine in a global phase 3 study in patients with high-risk, stage IIB to IV melanoma following surgery.

Another one to watch is the BNT116 NSCLC vaccine from BioNTech. This vaccine presents the immune system with NSCLC tumor markers to encourage the body to fight cancer cells expressing those markers while ignoring healthy cells. BioNTech also launched a global clinical trial for its vaccine this year.

Other notables include a pancreatic cancer mRNA vaccine, which has shown promising early results in a small trial of 16 patients. Of 16 patients who received the vaccine alongside chemotherapy and after surgery and immunotherapy, 8 responded. Of these eight, six remained recurrence free at 3 years. Investigators noted that the vaccine appeared to stimulate a durable T-cell response in patients who responded.

Kwak has also continued his work on lymphoma vaccines. In August, his team published promising first-in-human data on the use of personalized neoantigen vaccines as an early intervention in untreated patients with lymphoplasmacytic lymphoma. Among nine asymptomatic patients who received the vaccine, all achieved stable disease or better, with no dose-limiting toxicities. One patient had a minor response, and the median time to progression was greater than 72 months.

“The current setting is more for advanced disease,” Kwak explained. “It’s a tougher task, but combined with checkpoint blockade, it may be potent enough to work.” 

Still, caution is important. Despite early promise, it’s too soon to tell which, if any, of these investigational vaccines will pan out in the long run. Like investigational drugs, cancer vaccines may show big promising initially but then fail in larger trials.

One key to success, according to Kwak, is to design trials so that even negative results will inform next steps.

But, he noted, failures in large clinical trials will “put a chilling effect on cancer vaccine research again.”

“That’s what keeps me up at night,” he said. “We know the science is fundamentally sound and we have seen glimpses over decades of research that cancer vaccines can work, so it’s really just a matter of tweaking things to optimize trial design.”

Companies tend to design trials to test if a vaccine works or not, without trying to understand why, he said.

“What we need to do is design those so that we can learn from negative results,” he said. That’s what he and his colleagues attempted to do in their recent trial. “We didn’t just look at clinical results; we’re interrogating the actual tumor environment to understand what worked and didn’t and how to tweak that for the next trial.”

Kwak and his colleagues found, for instance, that the vaccine had a greater effect on B cell–derived tumor cells than on cells of plasma origin, so “the most rational design for the next iteration is to combine the vaccine with agents that work directly against plasma cells,” he explained.

As for what’s next, Kwak said: “We’re just focused on trying to do good science and understand. We’ve seen glimpses of success. That’s where we are.”

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

TOPLINE:

Merkel cell polyomavirus (MCPyV) and ambient ultraviolet radiation (UVR) exposure account for most Merkel cell carcinoma (MCC) cases in the United States.

METHODOLOGY:

• Researchers evaluated 38,020 MCC cases (38% women; 93% non-Hispanic White, 4% Hispanic, 1% non-Hispanic Black) diagnosed in the United States from 2001 to 2019 to estimate the contribution of potentially modifiable risk factors to the burden of MCC.
• Population-based cancer registries and linkages with HIV and transplant registries were utilized to identify MCC cases in patients with HIV, solid organ transplant recipients, and patients with chronic lymphocytic leukemia (CLL).
• Data on cloud-adjusted daily ambient UVR irradiance were merged with cancer registry information on the county of residence at diagnosis to assess UVR exposure. Studies reporting the prevalence of MCPyV in MCC specimens collected in the United States were combined via a meta-analysis.
• The study assessed population attributable fractions of MCC cases that were attributable to major immunosuppressive conditions (HIV, solid organ transplant, and chronic CLL), ambient UVR exposure, and MCPyV.

TAKEAWAY:

• The incidence of MCC was higher in people with HIV (standardized incidence ratio [SIR], 2.78), organ transplant recipients (SIR, 13.1), and patients with CLL (SIR, 5.75) than in the general US population. However, only 2.5% of MCC cases were attributable to these immunosuppressive conditions.
• Non-Hispanic White individuals showed elevated MCC incidence at both lower and higher ambient UVR exposure levels, with incidence rate ratios of 4.05 and 4.91, respectively, for MCC on the head and neck.
• A meta-analysis of 19 case series revealed that 63.8% of MCC cases were attributable to MCPyV, with a similar prevalence observed between immunocompromised and immunocompetent patients.
• Overall, 65.1% of MCC cases were attributable to ambient UVR exposure, with higher attribution for cases diagnosed on the head and neck than those diagnosed on other sites (72.1% vs 60.2%).

IN PRACTICE:

“The results of this study suggest that most MCC cases in the US are attributable to MCPyV and/or ambient UVR [UV radiation] exposure, with a smaller fraction attributable to three major immunosuppressive conditions,” the authors wrote. “Future studies should investigate UVR mutational signature, TMB [tumor mutational burden], and MCPyV prevalence according to race and ethnicity and patient immune status to help clarify the overlap between MCC risk factors.”

SOURCE:

The study was led by Jacob T. Tribble, BA, Division of Cancer Epidemiology and Genetics, National Cancer Institute (NCI), Rockville, Maryland. It was published online on November 27, 2024, in JAMA Dermatology.

LIMITATIONS:

Incidences of MCC may have been inflated because of increased medical surveillance in immunosuppressed populations. The analysis assumed that only cases among non-Hispanic White individuals were associated with UVR. Additionally, the meta-analysis of MCPyV prevalence primarily included studies from large academic institutions, which may not be representative of the entire US population.

DISCLOSURES:

This study was supported in part by the Intramural Research Program of the NCI and the National Institutes of Health Medical Research Scholars Program. Additional funding was provided through a public-private partnership with contributions from the American Association for Dental Research and the Colgate-Palmolive Company to the Foundation for the National Institutes of Health. The authors reported no relevant conflicts of interest.

This article was created using several editorial tools, including artificial intelligence, as part of the process. Human editors reviewed this content before publication. A version of this article appeared on Medscape.com.

TOPLINE:

Merkel cell polyomavirus (MCPyV) and ambient ultraviolet radiation (UVR) exposure account for most Merkel cell carcinoma (MCC) cases in the United States.

METHODOLOGY:

• Researchers evaluated 38,020 MCC cases (38% women; 93% non-Hispanic White, 4% Hispanic, 1% non-Hispanic Black) diagnosed in the United States from 2001 to 2019 to estimate the contribution of potentially modifiable risk factors to the burden of MCC.
• Population-based cancer registries and linkages with HIV and transplant registries were utilized to identify MCC cases in patients with HIV, solid organ transplant recipients, and patients with chronic lymphocytic leukemia (CLL).
• Data on cloud-adjusted daily ambient UVR irradiance were merged with cancer registry information on the county of residence at diagnosis to assess UVR exposure. Studies reporting the prevalence of MCPyV in MCC specimens collected in the United States were combined via a meta-analysis.
• The study assessed population attributable fractions of MCC cases that were attributable to major immunosuppressive conditions (HIV, solid organ transplant, and chronic CLL), ambient UVR exposure, and MCPyV.

TAKEAWAY:

• The incidence of MCC was higher in people with HIV (standardized incidence ratio [SIR], 2.78), organ transplant recipients (SIR, 13.1), and patients with CLL (SIR, 5.75) than in the general US population. However, only 2.5% of MCC cases were attributable to these immunosuppressive conditions.
• Non-Hispanic White individuals showed elevated MCC incidence at both lower and higher ambient UVR exposure levels, with incidence rate ratios of 4.05 and 4.91, respectively, for MCC on the head and neck.
• A meta-analysis of 19 case series revealed that 63.8% of MCC cases were attributable to MCPyV, with a similar prevalence observed between immunocompromised and immunocompetent patients.
• Overall, 65.1% of MCC cases were attributable to ambient UVR exposure, with higher attribution for cases diagnosed on the head and neck than those diagnosed on other sites (72.1% vs 60.2%).

IN PRACTICE:

“The results of this study suggest that most MCC cases in the US are attributable to MCPyV and/or ambient UVR [UV radiation] exposure, with a smaller fraction attributable to three major immunosuppressive conditions,” the authors wrote. “Future studies should investigate UVR mutational signature, TMB [tumor mutational burden], and MCPyV prevalence according to race and ethnicity and patient immune status to help clarify the overlap between MCC risk factors.”

SOURCE:

The study was led by Jacob T. Tribble, BA, Division of Cancer Epidemiology and Genetics, National Cancer Institute (NCI), Rockville, Maryland. It was published online on November 27, 2024, in JAMA Dermatology.

LIMITATIONS:

Incidences of MCC may have been inflated because of increased medical surveillance in immunosuppressed populations. The analysis assumed that only cases among non-Hispanic White individuals were associated with UVR. Additionally, the meta-analysis of MCPyV prevalence primarily included studies from large academic institutions, which may not be representative of the entire US population.

DISCLOSURES:

This study was supported in part by the Intramural Research Program of the NCI and the National Institutes of Health Medical Research Scholars Program. Additional funding was provided through a public-private partnership with contributions from the American Association for Dental Research and the Colgate-Palmolive Company to the Foundation for the National Institutes of Health. The authors reported no relevant conflicts of interest.

This article was created using several editorial tools, including artificial intelligence, as part of the process. Human editors reviewed this content before publication. A version of this article appeared on Medscape.com.

TOPLINE:

Merkel cell polyomavirus (MCPyV) and ambient ultraviolet radiation (UVR) exposure account for most Merkel cell carcinoma (MCC) cases in the United States.

METHODOLOGY:

• Researchers evaluated 38,020 MCC cases (38% women; 93% non-Hispanic White, 4% Hispanic, 1% non-Hispanic Black) diagnosed in the United States from 2001 to 2019 to estimate the contribution of potentially modifiable risk factors to the burden of MCC.
• Population-based cancer registries and linkages with HIV and transplant registries were utilized to identify MCC cases in patients with HIV, solid organ transplant recipients, and patients with chronic lymphocytic leukemia (CLL).
• Data on cloud-adjusted daily ambient UVR irradiance were merged with cancer registry information on the county of residence at diagnosis to assess UVR exposure. Studies reporting the prevalence of MCPyV in MCC specimens collected in the United States were combined via a meta-analysis.
• The study assessed population attributable fractions of MCC cases that were attributable to major immunosuppressive conditions (HIV, solid organ transplant, and chronic CLL), ambient UVR exposure, and MCPyV.

TAKEAWAY:

• The incidence of MCC was higher in people with HIV (standardized incidence ratio [SIR], 2.78), organ transplant recipients (SIR, 13.1), and patients with CLL (SIR, 5.75) than in the general US population. However, only 2.5% of MCC cases were attributable to these immunosuppressive conditions.
• Non-Hispanic White individuals showed elevated MCC incidence at both lower and higher ambient UVR exposure levels, with incidence rate ratios of 4.05 and 4.91, respectively, for MCC on the head and neck.
• A meta-analysis of 19 case series revealed that 63.8% of MCC cases were attributable to MCPyV, with a similar prevalence observed between immunocompromised and immunocompetent patients.
• Overall, 65.1% of MCC cases were attributable to ambient UVR exposure, with higher attribution for cases diagnosed on the head and neck than those diagnosed on other sites (72.1% vs 60.2%).

IN PRACTICE:

“The results of this study suggest that most MCC cases in the US are attributable to MCPyV and/or ambient UVR [UV radiation] exposure, with a smaller fraction attributable to three major immunosuppressive conditions,” the authors wrote. “Future studies should investigate UVR mutational signature, TMB [tumor mutational burden], and MCPyV prevalence according to race and ethnicity and patient immune status to help clarify the overlap between MCC risk factors.”

SOURCE:

The study was led by Jacob T. Tribble, BA, Division of Cancer Epidemiology and Genetics, National Cancer Institute (NCI), Rockville, Maryland. It was published online on November 27, 2024, in JAMA Dermatology.

LIMITATIONS:

Incidences of MCC may have been inflated because of increased medical surveillance in immunosuppressed populations. The analysis assumed that only cases among non-Hispanic White individuals were associated with UVR. Additionally, the meta-analysis of MCPyV prevalence primarily included studies from large academic institutions, which may not be representative of the entire US population.

DISCLOSURES:

This study was supported in part by the Intramural Research Program of the NCI and the National Institutes of Health Medical Research Scholars Program. Additional funding was provided through a public-private partnership with contributions from the American Association for Dental Research and the Colgate-Palmolive Company to the Foundation for the National Institutes of Health. The authors reported no relevant conflicts of interest.

This article was created using several editorial tools, including artificial intelligence, as part of the process. Human editors reviewed this content before publication. A version of this article appeared on Medscape.com.

VANCOUVER, BRITISH COLUMBIA — Canadian women aged 40-49 years at no or moderate risk for breast cancer who participated in organized mammography screening programs had a significantly greater breast cancer 10-year net survival than that of similar women who did not participate in such programs, according to data presented here at the Family Medicine Forum 2024. 

The data call into question draft guidelines from the Canadian Task Force on Preventive Health Care, which suggest not systematically screening women in this age group with mammography.

 

Overdiagnosis Challenged

Given that some jurisdictions in Canada have organized screening programs and some do not, there was an opportunity to compare breast cancer 10-year net survival of women who lived in jurisdictions with and without such programs, explained family physician Anna N. Wilkinson, MD, Ottawa regional cancer primary care lead and associate professor at the University of Ottawa in Ontario, Canada.

“The question was [whether] we could use big cancer data to figure out what’s going on,” she told this news organization. 

To investigate, Wilkinson and co-investigators reviewed data from the Canadian Cancer Registry linked to mortality information and assessed outcomes for women aged 40-49 and 50-59 years diagnosed with breast cancer from 2002 to 2007. They compared 10-year net survival estimates in jurisdictions with organized screening programs for those aged 40-49 years with the jurisdictions without them. 

“Net survival is important because it’s a survival measure that looks at only the cancer in question,” Wilkinson explained.

Investigators determined breast cancer to be the primary cause of 10-year mortality in women aged 40-49 years diagnosed with the disease (90.7% of deaths). 

Furthermore, the 10-year net survival in jurisdictions that screened these women (84.8%) was 1.9 percentage points higher than for jurisdictions that did not (82.9%). 

The difference in 10-year net survival favoring jurisdictions that offered screening was significant for women aged 45-49 years (2.6 percentage points) but not for those aged 40-44 years (0.9 percentage points).

Given that 90% of the deaths in women in their 40s who had a breast cancer diagnosis were due to breast cancer, Wilkinson challenged the concept of women in their 40s being overdiagnosed with breast cancer, meaning that the cancers detected were indolent and did not require treatment nor result in death.

Earlier detection would generally mean finding disease at an earlier stage and the need for less invasive treatment, she noted. “And one of the biggest benefits [of screening women in their 40s] is that you have diagnosis at earlier stage disease, which means fewer intensive therapies, less time off work, less long-term morbidity, and less cost to our healthcare system.”

 

Modeling Shows Little Screening Benefit

The task force’s draft guidelines, released earlier this year, were based on evidence from 165 studies including randomized, controlled trials, observational studies, time-trend studies and modeling. They suggest not systematically screening women 40-49 with mammography who are not high risk.

Family physician Guylène Thériault, MD, chair of the task force and its breast cancer working group, and director of the Pedagogy Center at the Outaouais Campus, McGill University, Montreal, Quebec, Canada, explained that to come to that conclusion, the task force had assessed the impact of organized screening for women in Canada aged 40-49 years and calculated the impact of mammography for every 1000 women over 10 years.

The model suggested that screening would yield 368 false positives, leading to 55 biopsies, and then to a breast cancer diagnosis in 19 women. Of those 19, the task force estimated 17 or 18 would not die of breast cancer over 10 years, two would be treated for breast cancer that would not have caused problems, ie, overdiagnosis, and one to two would die of breast cancer.

Without screening, on the other hand, the model suggested that 983 of 1000 women aged 40-49 years would not be diagnosed with breast cancer, and 17 would be, 15 of whom would not die from breast cancer over 10 years (no overdiagnosis, no deaths prevented) and two would die.

It is important that family physicians provide their patients with this information to assist in shared decision making about screening, Thériault said.

Wilkinson concluded that screening programs that included women in their 40s were associated with a significantly higher breast cancer 10-year survival, without an increased rate of diagnosis. She suggested that the study findings can inform the screening guidelines for women aged 40-49 years. 

The study was supported by the University of Ottawa’s department of family medicine. 

Wilkinson, MD, is a consultant for Thrive Health. Thériault, MD, disclosed no relevant financial relationships.

 

A version of this article appeared on Medscape.com.

VANCOUVER, BRITISH COLUMBIA — Canadian women aged 40-49 years at no or moderate risk for breast cancer who participated in organized mammography screening programs had a significantly greater breast cancer 10-year net survival than that of similar women who did not participate in such programs, according to data presented here at the Family Medicine Forum 2024. 

The data call into question draft guidelines from the Canadian Task Force on Preventive Health Care, which suggest not systematically screening women in this age group with mammography.

 

Overdiagnosis Challenged

Given that some jurisdictions in Canada have organized screening programs and some do not, there was an opportunity to compare breast cancer 10-year net survival of women who lived in jurisdictions with and without such programs, explained family physician Anna N. Wilkinson, MD, Ottawa regional cancer primary care lead and associate professor at the University of Ottawa in Ontario, Canada.

“The question was [whether] we could use big cancer data to figure out what’s going on,” she told this news organization. 

To investigate, Wilkinson and co-investigators reviewed data from the Canadian Cancer Registry linked to mortality information and assessed outcomes for women aged 40-49 and 50-59 years diagnosed with breast cancer from 2002 to 2007. They compared 10-year net survival estimates in jurisdictions with organized screening programs for those aged 40-49 years with the jurisdictions without them. 

“Net survival is important because it’s a survival measure that looks at only the cancer in question,” Wilkinson explained.

Investigators determined breast cancer to be the primary cause of 10-year mortality in women aged 40-49 years diagnosed with the disease (90.7% of deaths). 

Furthermore, the 10-year net survival in jurisdictions that screened these women (84.8%) was 1.9 percentage points higher than for jurisdictions that did not (82.9%). 

The difference in 10-year net survival favoring jurisdictions that offered screening was significant for women aged 45-49 years (2.6 percentage points) but not for those aged 40-44 years (0.9 percentage points).

Given that 90% of the deaths in women in their 40s who had a breast cancer diagnosis were due to breast cancer, Wilkinson challenged the concept of women in their 40s being overdiagnosed with breast cancer, meaning that the cancers detected were indolent and did not require treatment nor result in death.

Earlier detection would generally mean finding disease at an earlier stage and the need for less invasive treatment, she noted. “And one of the biggest benefits [of screening women in their 40s] is that you have diagnosis at earlier stage disease, which means fewer intensive therapies, less time off work, less long-term morbidity, and less cost to our healthcare system.”

 

Modeling Shows Little Screening Benefit

The task force’s draft guidelines, released earlier this year, were based on evidence from 165 studies including randomized, controlled trials, observational studies, time-trend studies and modeling. They suggest not systematically screening women 40-49 with mammography who are not high risk.

Family physician Guylène Thériault, MD, chair of the task force and its breast cancer working group, and director of the Pedagogy Center at the Outaouais Campus, McGill University, Montreal, Quebec, Canada, explained that to come to that conclusion, the task force had assessed the impact of organized screening for women in Canada aged 40-49 years and calculated the impact of mammography for every 1000 women over 10 years.

The model suggested that screening would yield 368 false positives, leading to 55 biopsies, and then to a breast cancer diagnosis in 19 women. Of those 19, the task force estimated 17 or 18 would not die of breast cancer over 10 years, two would be treated for breast cancer that would not have caused problems, ie, overdiagnosis, and one to two would die of breast cancer.

Without screening, on the other hand, the model suggested that 983 of 1000 women aged 40-49 years would not be diagnosed with breast cancer, and 17 would be, 15 of whom would not die from breast cancer over 10 years (no overdiagnosis, no deaths prevented) and two would die.

It is important that family physicians provide their patients with this information to assist in shared decision making about screening, Thériault said.

Wilkinson concluded that screening programs that included women in their 40s were associated with a significantly higher breast cancer 10-year survival, without an increased rate of diagnosis. She suggested that the study findings can inform the screening guidelines for women aged 40-49 years. 

The study was supported by the University of Ottawa’s department of family medicine. 

Wilkinson, MD, is a consultant for Thrive Health. Thériault, MD, disclosed no relevant financial relationships.

 

A version of this article appeared on Medscape.com.

VANCOUVER, BRITISH COLUMBIA — Canadian women aged 40-49 years at no or moderate risk for breast cancer who participated in organized mammography screening programs had a significantly greater breast cancer 10-year net survival than that of similar women who did not participate in such programs, according to data presented here at the Family Medicine Forum 2024. 

The data call into question draft guidelines from the Canadian Task Force on Preventive Health Care, which suggest not systematically screening women in this age group with mammography.

 

Overdiagnosis Challenged

Given that some jurisdictions in Canada have organized screening programs and some do not, there was an opportunity to compare breast cancer 10-year net survival of women who lived in jurisdictions with and without such programs, explained family physician Anna N. Wilkinson, MD, Ottawa regional cancer primary care lead and associate professor at the University of Ottawa in Ontario, Canada.

“The question was [whether] we could use big cancer data to figure out what’s going on,” she told this news organization. 

To investigate, Wilkinson and co-investigators reviewed data from the Canadian Cancer Registry linked to mortality information and assessed outcomes for women aged 40-49 and 50-59 years diagnosed with breast cancer from 2002 to 2007. They compared 10-year net survival estimates in jurisdictions with organized screening programs for those aged 40-49 years with the jurisdictions without them. 

“Net survival is important because it’s a survival measure that looks at only the cancer in question,” Wilkinson explained.

Investigators determined breast cancer to be the primary cause of 10-year mortality in women aged 40-49 years diagnosed with the disease (90.7% of deaths). 

Furthermore, the 10-year net survival in jurisdictions that screened these women (84.8%) was 1.9 percentage points higher than for jurisdictions that did not (82.9%). 

The difference in 10-year net survival favoring jurisdictions that offered screening was significant for women aged 45-49 years (2.6 percentage points) but not for those aged 40-44 years (0.9 percentage points).

Given that 90% of the deaths in women in their 40s who had a breast cancer diagnosis were due to breast cancer, Wilkinson challenged the concept of women in their 40s being overdiagnosed with breast cancer, meaning that the cancers detected were indolent and did not require treatment nor result in death.

Earlier detection would generally mean finding disease at an earlier stage and the need for less invasive treatment, she noted. “And one of the biggest benefits [of screening women in their 40s] is that you have diagnosis at earlier stage disease, which means fewer intensive therapies, less time off work, less long-term morbidity, and less cost to our healthcare system.”

 

Modeling Shows Little Screening Benefit

The task force’s draft guidelines, released earlier this year, were based on evidence from 165 studies including randomized, controlled trials, observational studies, time-trend studies and modeling. They suggest not systematically screening women 40-49 with mammography who are not high risk.

Family physician Guylène Thériault, MD, chair of the task force and its breast cancer working group, and director of the Pedagogy Center at the Outaouais Campus, McGill University, Montreal, Quebec, Canada, explained that to come to that conclusion, the task force had assessed the impact of organized screening for women in Canada aged 40-49 years and calculated the impact of mammography for every 1000 women over 10 years.

The model suggested that screening would yield 368 false positives, leading to 55 biopsies, and then to a breast cancer diagnosis in 19 women. Of those 19, the task force estimated 17 or 18 would not die of breast cancer over 10 years, two would be treated for breast cancer that would not have caused problems, ie, overdiagnosis, and one to two would die of breast cancer.

Without screening, on the other hand, the model suggested that 983 of 1000 women aged 40-49 years would not be diagnosed with breast cancer, and 17 would be, 15 of whom would not die from breast cancer over 10 years (no overdiagnosis, no deaths prevented) and two would die.

It is important that family physicians provide their patients with this information to assist in shared decision making about screening, Thériault said.

Wilkinson concluded that screening programs that included women in their 40s were associated with a significantly higher breast cancer 10-year survival, without an increased rate of diagnosis. She suggested that the study findings can inform the screening guidelines for women aged 40-49 years. 

The study was supported by the University of Ottawa’s department of family medicine. 

Wilkinson, MD, is a consultant for Thrive Health. Thériault, MD, disclosed no relevant financial relationships.

 

A version of this article appeared on Medscape.com.

Rose Gerber was 39, mother to a third grader and a kindergartener, when the diagnosis came: Advanced HER2-positive breast cancer.

“On one of my first or second appointments, I took in a little picture of Alexander and Isabella,” Gerber said. Gerber showed her oncologist the picture and told her: “I’ll do anything. I just want to be there for them.”

That was 21 years ago. Today, her current cancer status is “no evidence of disease.”

Over the past 2 decades, Gerber has gotten to be there for her children. Her youngest is now a television producer and her oldest, a CPA.

In that time, Gerber has had one constant: Her oncologist, Kandhasamy Jagathambal, MD, or Dr. Jaga, as she’s often called. 

“I’ve seen multiple physicians over my 21 years, but my oncologist has always been the focal point, guiding me in the right direction,” Gerber said in an interview.

Over the years, Jaga guided Gerber through a range of treatment decisions, including a Herceptin clinical trial that the mom of two views as lifesaving. Jaga often took on the role of both doctor and therapist, even providing comfort in the smaller moments when Gerber would fret about her weight gain.

The oncologist-patient “bond is very, very, very special,” said Gerber, who now works as director of patient advocacy and education at the Community Oncology Alliance.

Gerber isn’t alone in calling out the depth of the oncologist-patient bond.

Over years, sometimes decades, patients and oncologists can experience a whole world together: The treatment successes, relapses, uncertainties, and tough calls. As a result, a deep therapeutic alliance often develops. And with each new hurdle or decision, that collaborative, human connection between doctor and patient continues to form new layers.

“It’s like a shared bonding experience over trauma, like strangers trapped on a subway and then we get out, and we’re now on the other side, celebrating together,” said Saad Khan, MD, an associate professor of medicine (oncology) at Stanford University in California.

 

Connecting Through Stress

Although studies exploring the oncologist-patient bond are limited, some research suggests that a strong therapeutic alliance between patients and oncologists not only provides a foundation for quality care but can also help improve patients’ quality of life, protect against suicidal ideation, and increase treatment adherence.

Because of how stressful and frightening a cancer diagnosis can be, creating “a trusting, uninterrupted, almost sacred environment for them” is paramount for Khan. “I have no doubt that the most important part of their treatment is that they find an oncologist in whom they have total confidence,” Khan wrote in a blog.

The stress that patients with cancer experience is well documented, but oncologists take on a lot themselves and can also experience intense stress (.

“I consider my patient’s battles to be my battles,” Khan wrote.

The stress can start with the daily schedule. Oncologists often have a high volume of patients and tend to spend more time with each individual than most.

According to a 2023 survey, oncologists see about 68 patients a week, on average, but some oncologists, like Khan, have many more. Khan typically sees 20-30 patients a day and continues to care for many over years.

The survey also found that oncologists tend to spend a lot of time with their patients. Compared with other physicians, oncologists are two times more likely to spend at least 25 minutes with each patient.

With this kind of patient volume and time, Khan said, “you’re going to be exhausted.”

What can compound the exhaustion are the occasions oncologists need to deliver bad news — this treatment isn’t working, your cancer has come roaring back and, perhaps the hardest, we have no therapeutic options left. The end-of-life conversations, in particular, can be heartbreaking, especially when a patient is young and not ready to stop trying.

“It can be hard for doctors to discuss the end of life,” Don Dizon, MD, director of the Pelvic Malignancies Program at Lifespan Cancer Institute and director of Medical Oncology at Rhode Island Hospital, Providence, wrote in a column in 2023. Instead, it can be tempting and is often easier to focus on the next treatment, “instilling hope that there’s more that can be done,” even if doing more will only do harm.

In the face of these challenging decisions, growing a personal connection with patients over time can help keep oncologists going.

“We’re not just chemotherapy salesmen,” Khan said in an interview. “We get to know their social support network, who’s going to be driving them [to and from appointments], where they go on vacation, their cat’s name, who their neighbors are.”

 

A ‘Special Relationship’

Ralph V. Boccia, MD, is often asked what he does.

The next question that often comes — “Why do I do what I do?” — is Boccia’s favorite.

“Someone needs to take these patients through their journey,” Boccia, the founder of The Center for Cancer and Blood Disorders, Bethesda, Maryland, typically responds. He also often notes that “it is a special relationship you develop with the patient and their families.”

Boccia thinks about one long-term patient who captures this bond.

Joan Pinson, 70, was diagnosed with multiple myeloma about 25 years ago, when patients’ average survival was about 4 years.

Over a quarter century, Pinson has pivoted to different treatments, amid multiple relapses and remissions. Throughout most of this cancer journey, Boccia has been her primary oncologist, performing a stem cell transplant in 2000 and steering her to six clinical trials.

Her last relapse was 2 years ago, and since then she has been doing well on oral chemotherapy.

“Every time I relapsed, by the next appointment, he’d say, ‘here is what we are going to do,’ ” Pinson recalled. “I never worried, I never panicked. I knew he would take care of me.”

Over the years, Pinson and Boccia have shared many personal moments, sometimes by accident. One special moment happened early on in Pinson’s cancer journey. During an appointment, Boccia had “one ear to the phone” as his wife was about to deliver their first baby, Pinson recalled.

Later, Pinson met that child as a young man working in Boccia’s lab. She has also met Boccia’s wife, a nurse, when she filled in one day in the chemotherapy room.

Boccia now also treats Pinson’s husband who has prostate cancer, and he ruled out cancer when Pinson’s son, now in his 40s, had some worrisome symptoms.

More than 2 decades ago, Pinson told Boccia her goal was to see her youngest child graduate from high school. Now, six grandsons later, she has lived far beyond that goal.

“He has kept me alive,” said Pinson.

 

The Dying Patient

Harsha Vyas, MD, FACP, remembers the first encounter his office had with a 29-year-old woman referred with a diagnosis of stage IV breast cancer.

After just 15 minutes in the waiting room, the woman announced she was leaving. Although office staff assured the woman that she was next, the patient walked out.

Several months later, Vyas was called for an inpatient consult. It was the same woman.

Her lungs were full of fluid, and she was struggling to breathe, said Vyas, president and CEO of the Cancer Center of Middle Georgia, Dublin, and assistant professor at Augusta University in Georgia.

The woman, a single mother, told Vyas about her three young kids at home and asked him, “Doc, do something, please help me,” he recalled.

“Absolutely,” Vyas told her. But he had to be brutally honest about her prognosis and firm that she needed to follow his instructions. “You have a breast cancer I cannot cure,” he said. “All I can do is control the disease.”

From that first day, until the day she died, she came to every appointment and followed the treatment plan Vyas laid out.

For about 2 years, she responded well to treatment. And as the time passed and the trust grew, she began to open up to him. She showed him pictures. She talked about her children and being a mother.

“I’ve got to get my kids in a better place. I’m going to be there for them,” he recalled her saying.

Vyas admired her resourcefulness. She held down a part-time job, working retail and at a local restaurant. She figured out childcare so she could get to her chemotherapy appointments every 3 weeks and manage the copays.

Several years later, when she knew she was approaching the end of her life, she asked Vyas a question that hit hard.

“Doc, I don’t want to die and my kids find me dead. What can we do about it?”

Vyas, who has three daughters, imagined how traumatic this would be for a child. She and Vyas made the shared decision to cease treatment and begin home hospice. When the end was approaching, a hospice worker took over, waiting for bodily functions to cease.

When news of a death comes, “I say a little prayer, it’s almost like a send-off for that soul. That helps me absorb the news ... and let it go.”

But when the bond grows strong over time, as with his patient with breast cancer, Vyas said, “a piece of her is still with me.”

Khan had no relevant disclosures. Boccia and Vyas had no disclosures.

A version of this article appeared on Medscape.com.

Rose Gerber was 39, mother to a third grader and a kindergartener, when the diagnosis came: Advanced HER2-positive breast cancer.

“On one of my first or second appointments, I took in a little picture of Alexander and Isabella,” Gerber said. Gerber showed her oncologist the picture and told her: “I’ll do anything. I just want to be there for them.”

That was 21 years ago. Today, her current cancer status is “no evidence of disease.”

Over the past 2 decades, Gerber has gotten to be there for her children. Her youngest is now a television producer and her oldest, a CPA.

In that time, Gerber has had one constant: Her oncologist, Kandhasamy Jagathambal, MD, or Dr. Jaga, as she’s often called. 

“I’ve seen multiple physicians over my 21 years, but my oncologist has always been the focal point, guiding me in the right direction,” Gerber said in an interview.

Over the years, Jaga guided Gerber through a range of treatment decisions, including a Herceptin clinical trial that the mom of two views as lifesaving. Jaga often took on the role of both doctor and therapist, even providing comfort in the smaller moments when Gerber would fret about her weight gain.

The oncologist-patient “bond is very, very, very special,” said Gerber, who now works as director of patient advocacy and education at the Community Oncology Alliance.

Gerber isn’t alone in calling out the depth of the oncologist-patient bond.

Over years, sometimes decades, patients and oncologists can experience a whole world together: The treatment successes, relapses, uncertainties, and tough calls. As a result, a deep therapeutic alliance often develops. And with each new hurdle or decision, that collaborative, human connection between doctor and patient continues to form new layers.

“It’s like a shared bonding experience over trauma, like strangers trapped on a subway and then we get out, and we’re now on the other side, celebrating together,” said Saad Khan, MD, an associate professor of medicine (oncology) at Stanford University in California.

 

Connecting Through Stress

Although studies exploring the oncologist-patient bond are limited, some research suggests that a strong therapeutic alliance between patients and oncologists not only provides a foundation for quality care but can also help improve patients’ quality of life, protect against suicidal ideation, and increase treatment adherence.

Because of how stressful and frightening a cancer diagnosis can be, creating “a trusting, uninterrupted, almost sacred environment for them” is paramount for Khan. “I have no doubt that the most important part of their treatment is that they find an oncologist in whom they have total confidence,” Khan wrote in a blog.

The stress that patients with cancer experience is well documented, but oncologists take on a lot themselves and can also experience intense stress (.

“I consider my patient’s battles to be my battles,” Khan wrote.

The stress can start with the daily schedule. Oncologists often have a high volume of patients and tend to spend more time with each individual than most.

According to a 2023 survey, oncologists see about 68 patients a week, on average, but some oncologists, like Khan, have many more. Khan typically sees 20-30 patients a day and continues to care for many over years.

The survey also found that oncologists tend to spend a lot of time with their patients. Compared with other physicians, oncologists are two times more likely to spend at least 25 minutes with each patient.

With this kind of patient volume and time, Khan said, “you’re going to be exhausted.”

What can compound the exhaustion are the occasions oncologists need to deliver bad news — this treatment isn’t working, your cancer has come roaring back and, perhaps the hardest, we have no therapeutic options left. The end-of-life conversations, in particular, can be heartbreaking, especially when a patient is young and not ready to stop trying.

“It can be hard for doctors to discuss the end of life,” Don Dizon, MD, director of the Pelvic Malignancies Program at Lifespan Cancer Institute and director of Medical Oncology at Rhode Island Hospital, Providence, wrote in a column in 2023. Instead, it can be tempting and is often easier to focus on the next treatment, “instilling hope that there’s more that can be done,” even if doing more will only do harm.

In the face of these challenging decisions, growing a personal connection with patients over time can help keep oncologists going.

“We’re not just chemotherapy salesmen,” Khan said in an interview. “We get to know their social support network, who’s going to be driving them [to and from appointments], where they go on vacation, their cat’s name, who their neighbors are.”

 

A ‘Special Relationship’

Ralph V. Boccia, MD, is often asked what he does.

The next question that often comes — “Why do I do what I do?” — is Boccia’s favorite.

“Someone needs to take these patients through their journey,” Boccia, the founder of The Center for Cancer and Blood Disorders, Bethesda, Maryland, typically responds. He also often notes that “it is a special relationship you develop with the patient and their families.”

Boccia thinks about one long-term patient who captures this bond.

Joan Pinson, 70, was diagnosed with multiple myeloma about 25 years ago, when patients’ average survival was about 4 years.

Over a quarter century, Pinson has pivoted to different treatments, amid multiple relapses and remissions. Throughout most of this cancer journey, Boccia has been her primary oncologist, performing a stem cell transplant in 2000 and steering her to six clinical trials.

Her last relapse was 2 years ago, and since then she has been doing well on oral chemotherapy.

“Every time I relapsed, by the next appointment, he’d say, ‘here is what we are going to do,’ ” Pinson recalled. “I never worried, I never panicked. I knew he would take care of me.”

Over the years, Pinson and Boccia have shared many personal moments, sometimes by accident. One special moment happened early on in Pinson’s cancer journey. During an appointment, Boccia had “one ear to the phone” as his wife was about to deliver their first baby, Pinson recalled.

Later, Pinson met that child as a young man working in Boccia’s lab. She has also met Boccia’s wife, a nurse, when she filled in one day in the chemotherapy room.

Boccia now also treats Pinson’s husband who has prostate cancer, and he ruled out cancer when Pinson’s son, now in his 40s, had some worrisome symptoms.

More than 2 decades ago, Pinson told Boccia her goal was to see her youngest child graduate from high school. Now, six grandsons later, she has lived far beyond that goal.

“He has kept me alive,” said Pinson.

 

The Dying Patient

Harsha Vyas, MD, FACP, remembers the first encounter his office had with a 29-year-old woman referred with a diagnosis of stage IV breast cancer.

After just 15 minutes in the waiting room, the woman announced she was leaving. Although office staff assured the woman that she was next, the patient walked out.

Several months later, Vyas was called for an inpatient consult. It was the same woman.

Her lungs were full of fluid, and she was struggling to breathe, said Vyas, president and CEO of the Cancer Center of Middle Georgia, Dublin, and assistant professor at Augusta University in Georgia.

The woman, a single mother, told Vyas about her three young kids at home and asked him, “Doc, do something, please help me,” he recalled.

“Absolutely,” Vyas told her. But he had to be brutally honest about her prognosis and firm that she needed to follow his instructions. “You have a breast cancer I cannot cure,” he said. “All I can do is control the disease.”

From that first day, until the day she died, she came to every appointment and followed the treatment plan Vyas laid out.

For about 2 years, she responded well to treatment. And as the time passed and the trust grew, she began to open up to him. She showed him pictures. She talked about her children and being a mother.

“I’ve got to get my kids in a better place. I’m going to be there for them,” he recalled her saying.

Vyas admired her resourcefulness. She held down a part-time job, working retail and at a local restaurant. She figured out childcare so she could get to her chemotherapy appointments every 3 weeks and manage the copays.

Several years later, when she knew she was approaching the end of her life, she asked Vyas a question that hit hard.

“Doc, I don’t want to die and my kids find me dead. What can we do about it?”

Vyas, who has three daughters, imagined how traumatic this would be for a child. She and Vyas made the shared decision to cease treatment and begin home hospice. When the end was approaching, a hospice worker took over, waiting for bodily functions to cease.

When news of a death comes, “I say a little prayer, it’s almost like a send-off for that soul. That helps me absorb the news ... and let it go.”

But when the bond grows strong over time, as with his patient with breast cancer, Vyas said, “a piece of her is still with me.”

Khan had no relevant disclosures. Boccia and Vyas had no disclosures.

A version of this article appeared on Medscape.com.

Rose Gerber was 39, mother to a third grader and a kindergartener, when the diagnosis came: Advanced HER2-positive breast cancer.

“On one of my first or second appointments, I took in a little picture of Alexander and Isabella,” Gerber said. Gerber showed her oncologist the picture and told her: “I’ll do anything. I just want to be there for them.”

That was 21 years ago. Today, her current cancer status is “no evidence of disease.”

Over the past 2 decades, Gerber has gotten to be there for her children. Her youngest is now a television producer and her oldest, a CPA.

In that time, Gerber has had one constant: Her oncologist, Kandhasamy Jagathambal, MD, or Dr. Jaga, as she’s often called. 

“I’ve seen multiple physicians over my 21 years, but my oncologist has always been the focal point, guiding me in the right direction,” Gerber said in an interview.

Over the years, Jaga guided Gerber through a range of treatment decisions, including a Herceptin clinical trial that the mom of two views as lifesaving. Jaga often took on the role of both doctor and therapist, even providing comfort in the smaller moments when Gerber would fret about her weight gain.

The oncologist-patient “bond is very, very, very special,” said Gerber, who now works as director of patient advocacy and education at the Community Oncology Alliance.

Gerber isn’t alone in calling out the depth of the oncologist-patient bond.

Over years, sometimes decades, patients and oncologists can experience a whole world together: The treatment successes, relapses, uncertainties, and tough calls. As a result, a deep therapeutic alliance often develops. And with each new hurdle or decision, that collaborative, human connection between doctor and patient continues to form new layers.

“It’s like a shared bonding experience over trauma, like strangers trapped on a subway and then we get out, and we’re now on the other side, celebrating together,” said Saad Khan, MD, an associate professor of medicine (oncology) at Stanford University in California.

 

Connecting Through Stress

Although studies exploring the oncologist-patient bond are limited, some research suggests that a strong therapeutic alliance between patients and oncologists not only provides a foundation for quality care but can also help improve patients’ quality of life, protect against suicidal ideation, and increase treatment adherence.

Because of how stressful and frightening a cancer diagnosis can be, creating “a trusting, uninterrupted, almost sacred environment for them” is paramount for Khan. “I have no doubt that the most important part of their treatment is that they find an oncologist in whom they have total confidence,” Khan wrote in a blog.

The stress that patients with cancer experience is well documented, but oncologists take on a lot themselves and can also experience intense stress (.

“I consider my patient’s battles to be my battles,” Khan wrote.

The stress can start with the daily schedule. Oncologists often have a high volume of patients and tend to spend more time with each individual than most.

According to a 2023 survey, oncologists see about 68 patients a week, on average, but some oncologists, like Khan, have many more. Khan typically sees 20-30 patients a day and continues to care for many over years.

The survey also found that oncologists tend to spend a lot of time with their patients. Compared with other physicians, oncologists are two times more likely to spend at least 25 minutes with each patient.

With this kind of patient volume and time, Khan said, “you’re going to be exhausted.”

What can compound the exhaustion are the occasions oncologists need to deliver bad news — this treatment isn’t working, your cancer has come roaring back and, perhaps the hardest, we have no therapeutic options left. The end-of-life conversations, in particular, can be heartbreaking, especially when a patient is young and not ready to stop trying.

“It can be hard for doctors to discuss the end of life,” Don Dizon, MD, director of the Pelvic Malignancies Program at Lifespan Cancer Institute and director of Medical Oncology at Rhode Island Hospital, Providence, wrote in a column in 2023. Instead, it can be tempting and is often easier to focus on the next treatment, “instilling hope that there’s more that can be done,” even if doing more will only do harm.

In the face of these challenging decisions, growing a personal connection with patients over time can help keep oncologists going.

“We’re not just chemotherapy salesmen,” Khan said in an interview. “We get to know their social support network, who’s going to be driving them [to and from appointments], where they go on vacation, their cat’s name, who their neighbors are.”

 

A ‘Special Relationship’

Ralph V. Boccia, MD, is often asked what he does.

The next question that often comes — “Why do I do what I do?” — is Boccia’s favorite.

“Someone needs to take these patients through their journey,” Boccia, the founder of The Center for Cancer and Blood Disorders, Bethesda, Maryland, typically responds. He also often notes that “it is a special relationship you develop with the patient and their families.”

Boccia thinks about one long-term patient who captures this bond.

Joan Pinson, 70, was diagnosed with multiple myeloma about 25 years ago, when patients’ average survival was about 4 years.

Over a quarter century, Pinson has pivoted to different treatments, amid multiple relapses and remissions. Throughout most of this cancer journey, Boccia has been her primary oncologist, performing a stem cell transplant in 2000 and steering her to six clinical trials.

Her last relapse was 2 years ago, and since then she has been doing well on oral chemotherapy.

“Every time I relapsed, by the next appointment, he’d say, ‘here is what we are going to do,’ ” Pinson recalled. “I never worried, I never panicked. I knew he would take care of me.”

Over the years, Pinson and Boccia have shared many personal moments, sometimes by accident. One special moment happened early on in Pinson’s cancer journey. During an appointment, Boccia had “one ear to the phone” as his wife was about to deliver their first baby, Pinson recalled.

Later, Pinson met that child as a young man working in Boccia’s lab. She has also met Boccia’s wife, a nurse, when she filled in one day in the chemotherapy room.

Boccia now also treats Pinson’s husband who has prostate cancer, and he ruled out cancer when Pinson’s son, now in his 40s, had some worrisome symptoms.

More than 2 decades ago, Pinson told Boccia her goal was to see her youngest child graduate from high school. Now, six grandsons later, she has lived far beyond that goal.

“He has kept me alive,” said Pinson.

 

The Dying Patient

Harsha Vyas, MD, FACP, remembers the first encounter his office had with a 29-year-old woman referred with a diagnosis of stage IV breast cancer.

After just 15 minutes in the waiting room, the woman announced she was leaving. Although office staff assured the woman that she was next, the patient walked out.

Several months later, Vyas was called for an inpatient consult. It was the same woman.

Her lungs were full of fluid, and she was struggling to breathe, said Vyas, president and CEO of the Cancer Center of Middle Georgia, Dublin, and assistant professor at Augusta University in Georgia.

The woman, a single mother, told Vyas about her three young kids at home and asked him, “Doc, do something, please help me,” he recalled.

“Absolutely,” Vyas told her. But he had to be brutally honest about her prognosis and firm that she needed to follow his instructions. “You have a breast cancer I cannot cure,” he said. “All I can do is control the disease.”

From that first day, until the day she died, she came to every appointment and followed the treatment plan Vyas laid out.

For about 2 years, she responded well to treatment. And as the time passed and the trust grew, she began to open up to him. She showed him pictures. She talked about her children and being a mother.

“I’ve got to get my kids in a better place. I’m going to be there for them,” he recalled her saying.

Vyas admired her resourcefulness. She held down a part-time job, working retail and at a local restaurant. She figured out childcare so she could get to her chemotherapy appointments every 3 weeks and manage the copays.

Several years later, when she knew she was approaching the end of her life, she asked Vyas a question that hit hard.

“Doc, I don’t want to die and my kids find me dead. What can we do about it?”

Vyas, who has three daughters, imagined how traumatic this would be for a child. She and Vyas made the shared decision to cease treatment and begin home hospice. When the end was approaching, a hospice worker took over, waiting for bodily functions to cease.

When news of a death comes, “I say a little prayer, it’s almost like a send-off for that soul. That helps me absorb the news ... and let it go.”

But when the bond grows strong over time, as with his patient with breast cancer, Vyas said, “a piece of her is still with me.”

Khan had no relevant disclosures. Boccia and Vyas had no disclosures.

A version of this article appeared on Medscape.com.

TOPLINE:

At 1 year, 82% of patients with breast cancer who received a 1-week ultrahypofractionated breast radiotherapy regimen reported no or mild toxicities. Most patients also reported that the reduced treatment time was a major benefit of the 1-week radiotherapy schedule.

METHODOLOGY:

• In March 2020, during the COVID-19 pandemic, international and national guidelines recommended adopting a 1-week ultrahypofractionated radiotherapy schedule for patients with node-negative breast cancer. Subsequently, a phase 3 trial demonstrated that a 1-week regimen of 26 Gy in five fractions led to similar breast cancer outcomes compared with a standard moderately hypofractionated regimen.
• In this study, researchers wanted to assess real world toxicities following ultrahypofractionated radiotherapy and enrolled 135 consecutive patients who received 1-week ultrahypofractionated adjuvant radiation of 26 Gy in five fractions from March to August 2020 at three centers in Ireland, with 33 patients (25%) receiving a sequential boost.
• Researchers recorded patient-reported outcomes on breast pain, swelling, firmness, and hypersensitivity at baseline, 3, 6, and 12 months. Virtual consultations without video occurred at baseline, 3 months, 6 months, and video consultations were offered at 1 year for a physician-led breast evaluation.
• Researchers assessed patient perspectives on this new schedule and telehealth workflows using questionnaires.
• Overall, 90% of patients completed the 1-year assessment plus another assessment. The primary endpoint was the worst toxicity reported at each time point.

TAKEAWAY:

• Overall, 76% of patients reported no or mild toxicities at 3 and 6 months, and 82% reported no or mild toxicities 12 months.
• At 1 year, 20 patients (17%) reported moderate toxicity, most commonly breast pain, and only two patients (2%) reported marked toxicities, including breast firmness and skin changes.
• Researchers found no difference in toxicities between patients who received only 26 Gy in five fractions and those who received an additional sequential boost.
• Most patients reported reduced treatment time (78.6%) and infection control (59%) as major benefits of the 1-week radiotherapy regimen. Patients also reported high satisfaction with the use of telehealth, with 97.3% feeling well-informed about their diagnosis, 88% feeling well-informed about treatment side effects, and 94% feeling supported by the medical team. However, only 27% agreed to video consultations for breast inspections at 1 year.

IN PRACTICE:

“Ultrahypofractionated whole breast radiotherapy leads to acceptable late toxicity rates at 1 year even when followed by a hypofractionated tumour bed boost,” the authors wrote. “Patient satisfaction with ultrahypofractionated treatment and virtual consultations without video was high.”

SOURCE:

The study, led by Jill Nicholson, MBBS, MRCP, FFFRRCSI, St Luke’s Radiation Oncology Network, St. Luke’s Hospital, Dublin, Ireland, was published online in Advances in Radiation Oncology.

LIMITATIONS:

The short follow-up period might not capture all late toxicities. Variability in patient-reported outcomes could affect consistency. The range in boost received (four to eight fractions) could have influenced patients’ experiences.

DISCLOSURES:

Nicholson received funding from the St. Luke’s Institute of Cancer Research, Dublin, Ireland. No other relevant conflicts of interest were disclosed by the authors.

 

This article was created using several editorial tools, including AI, as part of the process. Human editors reviewed this content before publication. A version of this article appeared on Medscape.com.

TOPLINE:

At 1 year, 82% of patients with breast cancer who received a 1-week ultrahypofractionated breast radiotherapy regimen reported no or mild toxicities. Most patients also reported that the reduced treatment time was a major benefit of the 1-week radiotherapy schedule.

METHODOLOGY:

• In March 2020, during the COVID-19 pandemic, international and national guidelines recommended adopting a 1-week ultrahypofractionated radiotherapy schedule for patients with node-negative breast cancer. Subsequently, a phase 3 trial demonstrated that a 1-week regimen of 26 Gy in five fractions led to similar breast cancer outcomes compared with a standard moderately hypofractionated regimen.
• In this study, researchers wanted to assess real world toxicities following ultrahypofractionated radiotherapy and enrolled 135 consecutive patients who received 1-week ultrahypofractionated adjuvant radiation of 26 Gy in five fractions from March to August 2020 at three centers in Ireland, with 33 patients (25%) receiving a sequential boost.
• Researchers recorded patient-reported outcomes on breast pain, swelling, firmness, and hypersensitivity at baseline, 3, 6, and 12 months. Virtual consultations without video occurred at baseline, 3 months, 6 months, and video consultations were offered at 1 year for a physician-led breast evaluation.
• Researchers assessed patient perspectives on this new schedule and telehealth workflows using questionnaires.
• Overall, 90% of patients completed the 1-year assessment plus another assessment. The primary endpoint was the worst toxicity reported at each time point.

TAKEAWAY:

• Overall, 76% of patients reported no or mild toxicities at 3 and 6 months, and 82% reported no or mild toxicities 12 months.
• At 1 year, 20 patients (17%) reported moderate toxicity, most commonly breast pain, and only two patients (2%) reported marked toxicities, including breast firmness and skin changes.
• Researchers found no difference in toxicities between patients who received only 26 Gy in five fractions and those who received an additional sequential boost.
• Most patients reported reduced treatment time (78.6%) and infection control (59%) as major benefits of the 1-week radiotherapy regimen. Patients also reported high satisfaction with the use of telehealth, with 97.3% feeling well-informed about their diagnosis, 88% feeling well-informed about treatment side effects, and 94% feeling supported by the medical team. However, only 27% agreed to video consultations for breast inspections at 1 year.

IN PRACTICE:

“Ultrahypofractionated whole breast radiotherapy leads to acceptable late toxicity rates at 1 year even when followed by a hypofractionated tumour bed boost,” the authors wrote. “Patient satisfaction with ultrahypofractionated treatment and virtual consultations without video was high.”

SOURCE:

The study, led by Jill Nicholson, MBBS, MRCP, FFFRRCSI, St Luke’s Radiation Oncology Network, St. Luke’s Hospital, Dublin, Ireland, was published online in Advances in Radiation Oncology.

LIMITATIONS:

The short follow-up period might not capture all late toxicities. Variability in patient-reported outcomes could affect consistency. The range in boost received (four to eight fractions) could have influenced patients’ experiences.

DISCLOSURES:

Nicholson received funding from the St. Luke’s Institute of Cancer Research, Dublin, Ireland. No other relevant conflicts of interest were disclosed by the authors.

 

This article was created using several editorial tools, including AI, as part of the process. Human editors reviewed this content before publication. A version of this article appeared on Medscape.com.

TOPLINE:

At 1 year, 82% of patients with breast cancer who received a 1-week ultrahypofractionated breast radiotherapy regimen reported no or mild toxicities. Most patients also reported that the reduced treatment time was a major benefit of the 1-week radiotherapy schedule.

METHODOLOGY:

• In March 2020, during the COVID-19 pandemic, international and national guidelines recommended adopting a 1-week ultrahypofractionated radiotherapy schedule for patients with node-negative breast cancer. Subsequently, a phase 3 trial demonstrated that a 1-week regimen of 26 Gy in five fractions led to similar breast cancer outcomes compared with a standard moderately hypofractionated regimen.
• In this study, researchers wanted to assess real world toxicities following ultrahypofractionated radiotherapy and enrolled 135 consecutive patients who received 1-week ultrahypofractionated adjuvant radiation of 26 Gy in five fractions from March to August 2020 at three centers in Ireland, with 33 patients (25%) receiving a sequential boost.
• Researchers recorded patient-reported outcomes on breast pain, swelling, firmness, and hypersensitivity at baseline, 3, 6, and 12 months. Virtual consultations without video occurred at baseline, 3 months, 6 months, and video consultations were offered at 1 year for a physician-led breast evaluation.
• Researchers assessed patient perspectives on this new schedule and telehealth workflows using questionnaires.
• Overall, 90% of patients completed the 1-year assessment plus another assessment. The primary endpoint was the worst toxicity reported at each time point.

TAKEAWAY:

• Overall, 76% of patients reported no or mild toxicities at 3 and 6 months, and 82% reported no or mild toxicities 12 months.
• At 1 year, 20 patients (17%) reported moderate toxicity, most commonly breast pain, and only two patients (2%) reported marked toxicities, including breast firmness and skin changes.
• Researchers found no difference in toxicities between patients who received only 26 Gy in five fractions and those who received an additional sequential boost.
• Most patients reported reduced treatment time (78.6%) and infection control (59%) as major benefits of the 1-week radiotherapy regimen. Patients also reported high satisfaction with the use of telehealth, with 97.3% feeling well-informed about their diagnosis, 88% feeling well-informed about treatment side effects, and 94% feeling supported by the medical team. However, only 27% agreed to video consultations for breast inspections at 1 year.

IN PRACTICE:

“Ultrahypofractionated whole breast radiotherapy leads to acceptable late toxicity rates at 1 year even when followed by a hypofractionated tumour bed boost,” the authors wrote. “Patient satisfaction with ultrahypofractionated treatment and virtual consultations without video was high.”

SOURCE:

The study, led by Jill Nicholson, MBBS, MRCP, FFFRRCSI, St Luke’s Radiation Oncology Network, St. Luke’s Hospital, Dublin, Ireland, was published online in Advances in Radiation Oncology.

LIMITATIONS:

The short follow-up period might not capture all late toxicities. Variability in patient-reported outcomes could affect consistency. The range in boost received (four to eight fractions) could have influenced patients’ experiences.

DISCLOSURES:

Nicholson received funding from the St. Luke’s Institute of Cancer Research, Dublin, Ireland. No other relevant conflicts of interest were disclosed by the authors.

 

This article was created using several editorial tools, including AI, as part of the process. Human editors reviewed this content before publication. A version of this article appeared on Medscape.com.

TOPLINE:

Individuals with normal body mass index (BMI) measurements may still face an increased risk for colorectal cancer if they have central obesity, characterized by excess fat around the abdomen.

METHODOLOGY:

• General obesity, often measured using BMI, is a recognized risk factor for colorectal cancer, but how much of this association is due to central obesity is unclear.
• Researchers assessed the associations between BMI, waist-to-hip ratio (WHR), and waist circumference (WC) with colorectal cancer risk and the degree of independence among these associations in patients aged 40-69 years recruited in the UK Biobank cohort study from 2006 to 2010.
• Anthropometric measurements were performed using standardized methods.
• Cancer registry and hospital data linkage identified colorectal cancer cases in the UK Biobank.

TAKEAWAY:

• Researchers included 460,784 participants (mean age, 56.3 years; 46.7% men), of whom 67.1% had either overweight or obesity, and 49.4% and 60.5% had high or very high WHR and WC, respectively.
• During the median 12.5-year follow-up period, 5977 participants developed colorectal cancer.
• Every SD increase in WHR (hazard ratio [HR], 1.18) showed a stronger association with colorectal cancer risk than in BMI (HR, 1.10).
• After adjustment for BMI, the association between WHR and colorectal cancer risk became slightly attenuated while still staying robust (HR, 1.15); however, after adjusting for WHR, the association between BMI and colorectal cancer risk became substantially weakened (HR, 1.04).
• WHR showed strongly significant associations with colorectal cancer risk across all BMI categories, whereas associations of BMI with colorectal cancer risk were weak and not statistically significant within all WHR categories.
• Central obesity demonstrated consistent associations with both colon and rectal cancer risks in both sexes before and after adjustment for BMI, whereas BMI showed no significant association with colorectal cancer risk in women or with rectal cancer risk after WHR adjustment.

IN PRACTICE:

“[The study] results also underline the importance of integrating additional anthropometric measures such as WHR alongside BMI into routine clinical practice for more effective prevention and management of obesity, whose prevalence is steadily increasing in many countries worldwide, in order to limit the global burden of colorectal cancer and many other obesity-related adverse health outcomes,” the authors wrote.

SOURCE:

The study was led by Fatemeh Safizadeh, German Cancer Research Center (DKFZ), Heidelberg. It was published online in The International Journal of Obesity.

LIMITATIONS:

This study relied on only one-time measurements of anthropometric measures at baseline, without considering previous lifetime history of overweight and obesity or changes during follow-up. Additionally, WHR and WC may not be the most accurate measures of central obesity, as WC includes both visceral and subcutaneous adipose tissue. The study population also showed evidence of healthy volunteer bias, with more health-conscious and socioeconomically advantaged participants being somewhat overrepresented.

DISCLOSURES:

The authors declared no competing interests.

This article was created using several editorial tools, including AI, as part of the process. Human editors reviewed this content before publication. A version of this article appeared on Medscape.com.

TOPLINE:

Individuals with normal body mass index (BMI) measurements may still face an increased risk for colorectal cancer if they have central obesity, characterized by excess fat around the abdomen.

METHODOLOGY:

• General obesity, often measured using BMI, is a recognized risk factor for colorectal cancer, but how much of this association is due to central obesity is unclear.
• Researchers assessed the associations between BMI, waist-to-hip ratio (WHR), and waist circumference (WC) with colorectal cancer risk and the degree of independence among these associations in patients aged 40-69 years recruited in the UK Biobank cohort study from 2006 to 2010.
• Anthropometric measurements were performed using standardized methods.
• Cancer registry and hospital data linkage identified colorectal cancer cases in the UK Biobank.

TAKEAWAY:

• Researchers included 460,784 participants (mean age, 56.3 years; 46.7% men), of whom 67.1% had either overweight or obesity, and 49.4% and 60.5% had high or very high WHR and WC, respectively.
• During the median 12.5-year follow-up period, 5977 participants developed colorectal cancer.
• Every SD increase in WHR (hazard ratio [HR], 1.18) showed a stronger association with colorectal cancer risk than in BMI (HR, 1.10).
• After adjustment for BMI, the association between WHR and colorectal cancer risk became slightly attenuated while still staying robust (HR, 1.15); however, after adjusting for WHR, the association between BMI and colorectal cancer risk became substantially weakened (HR, 1.04).
• WHR showed strongly significant associations with colorectal cancer risk across all BMI categories, whereas associations of BMI with colorectal cancer risk were weak and not statistically significant within all WHR categories.
• Central obesity demonstrated consistent associations with both colon and rectal cancer risks in both sexes before and after adjustment for BMI, whereas BMI showed no significant association with colorectal cancer risk in women or with rectal cancer risk after WHR adjustment.

IN PRACTICE:

“[The study] results also underline the importance of integrating additional anthropometric measures such as WHR alongside BMI into routine clinical practice for more effective prevention and management of obesity, whose prevalence is steadily increasing in many countries worldwide, in order to limit the global burden of colorectal cancer and many other obesity-related adverse health outcomes,” the authors wrote.

SOURCE:

The study was led by Fatemeh Safizadeh, German Cancer Research Center (DKFZ), Heidelberg. It was published online in The International Journal of Obesity.

LIMITATIONS:

This study relied on only one-time measurements of anthropometric measures at baseline, without considering previous lifetime history of overweight and obesity or changes during follow-up. Additionally, WHR and WC may not be the most accurate measures of central obesity, as WC includes both visceral and subcutaneous adipose tissue. The study population also showed evidence of healthy volunteer bias, with more health-conscious and socioeconomically advantaged participants being somewhat overrepresented.

DISCLOSURES:

The authors declared no competing interests.

This article was created using several editorial tools, including AI, as part of the process. Human editors reviewed this content before publication. A version of this article appeared on Medscape.com.

TOPLINE:

Individuals with normal body mass index (BMI) measurements may still face an increased risk for colorectal cancer if they have central obesity, characterized by excess fat around the abdomen.

METHODOLOGY:

• General obesity, often measured using BMI, is a recognized risk factor for colorectal cancer, but how much of this association is due to central obesity is unclear.
• Researchers assessed the associations between BMI, waist-to-hip ratio (WHR), and waist circumference (WC) with colorectal cancer risk and the degree of independence among these associations in patients aged 40-69 years recruited in the UK Biobank cohort study from 2006 to 2010.
• Anthropometric measurements were performed using standardized methods.
• Cancer registry and hospital data linkage identified colorectal cancer cases in the UK Biobank.

TAKEAWAY:

• Researchers included 460,784 participants (mean age, 56.3 years; 46.7% men), of whom 67.1% had either overweight or obesity, and 49.4% and 60.5% had high or very high WHR and WC, respectively.
• During the median 12.5-year follow-up period, 5977 participants developed colorectal cancer.
• Every SD increase in WHR (hazard ratio [HR], 1.18) showed a stronger association with colorectal cancer risk than in BMI (HR, 1.10).
• After adjustment for BMI, the association between WHR and colorectal cancer risk became slightly attenuated while still staying robust (HR, 1.15); however, after adjusting for WHR, the association between BMI and colorectal cancer risk became substantially weakened (HR, 1.04).
• WHR showed strongly significant associations with colorectal cancer risk across all BMI categories, whereas associations of BMI with colorectal cancer risk were weak and not statistically significant within all WHR categories.
• Central obesity demonstrated consistent associations with both colon and rectal cancer risks in both sexes before and after adjustment for BMI, whereas BMI showed no significant association with colorectal cancer risk in women or with rectal cancer risk after WHR adjustment.

IN PRACTICE:

“[The study] results also underline the importance of integrating additional anthropometric measures such as WHR alongside BMI into routine clinical practice for more effective prevention and management of obesity, whose prevalence is steadily increasing in many countries worldwide, in order to limit the global burden of colorectal cancer and many other obesity-related adverse health outcomes,” the authors wrote.

SOURCE:

The study was led by Fatemeh Safizadeh, German Cancer Research Center (DKFZ), Heidelberg. It was published online in The International Journal of Obesity.

LIMITATIONS:

This study relied on only one-time measurements of anthropometric measures at baseline, without considering previous lifetime history of overweight and obesity or changes during follow-up. Additionally, WHR and WC may not be the most accurate measures of central obesity, as WC includes both visceral and subcutaneous adipose tissue. The study population also showed evidence of healthy volunteer bias, with more health-conscious and socioeconomically advantaged participants being somewhat overrepresented.

DISCLOSURES:

The authors declared no competing interests.

This article was created using several editorial tools, including AI, as part of the process. Human editors reviewed this content before publication. A version of this article appeared on Medscape.com.

It has been three and a half years since the US Preventive Services Task Force (USPSTF) lowered the age to start colorectal cancer (CRC) screening from 50 to 45. As I mentioned in a previous commentary, two major medical groups — the American Academy of Family Physicians and the American College of Physicians — felt that the evidence was insufficient to support this change. 

Did doctors adjust their screening practices? A recent study suggests that they have. Comparing CRC screening rates in more than 10 million adults aged 45-49 during the 20 months preceding and 20 months following the USPSTF recommendation, researchers found significant increases during the latter time period, with the greatest increases among persons of high socioeconomic status or living in metropolitan areas.

Another study addressed concerns that younger adults may be less likely to follow up on positive screening results or more likely to have false positives on a fecal immunochemical test (FIT). Patients aged 45-49 years were slightly less likely to have a positive FIT result than 50-year-olds, but they had similar rates of colonoscopy completion and similar percentages of abnormal findings on colonoscopy.

Although the sensitivity and specificity of FIT varies quite a bit across different test brands, its overall effectiveness at reducing colorectal cancer deaths is well established. In 2024, the Food and Drug Administration approved three new screening options: a blood-based screening test (Shield), a next-generation multitarget stool DNA test (Cologuard Plus), and a multitarget stool RNA test (ColoSense) with similar performance characteristics as Cologuard Plus. The latter two tests will become available early next year.

This profusion of noninvasive options for CRC screening will challenge those tasked with developing the next iteration of the USPSTF recommendations. Not only must future guidelines establish what evidence threshold is sufficient to recommend a new screening strategy, but they also will need to consider the population-level consequences of relative utilization of different tests. For example, a cost-effectiveness analysis found that more CRC deaths would occur if people who would have otherwise accepted colonoscopy or fecal tests chose to be screened with Shield instead; however, this negative outcome could be offset if for every three of these test substitutions, two other people chose Shield who would otherwise have not been screened at all.

In the meantime, it is important for primary care clinicians to be familiar with evidence-based intervals for CRC screening tests and test eligibility criteria. A troubling study of patients who completed a multitarget stool DNA test in a Midwestern health system in 2021 found that more than one in five had the test ordered inappropriately, based on USPSTF guidelines. Reasons for inappropriate testing included having had a colonoscopy within the past 10 years, a family history of CRC, symptoms suggestive of possible CRC, age younger than 45, and a prior diagnosis of colonic adenomas. 

Just as a medication works best when the patient takes it as prescribed, a CRC screening test is most likely to yield more benefit than harm when it’s provided to the right patient at the right time.

Dr. Lin is Associate Director, Family Medicine Residency Program, at Lancaster General Hospital in Pennsylvania. He reported no relevant conflicts of interest.

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

It has been three and a half years since the US Preventive Services Task Force (USPSTF) lowered the age to start colorectal cancer (CRC) screening from 50 to 45. As I mentioned in a previous commentary, two major medical groups — the American Academy of Family Physicians and the American College of Physicians — felt that the evidence was insufficient to support this change. 

Did doctors adjust their screening practices? A recent study suggests that they have. Comparing CRC screening rates in more than 10 million adults aged 45-49 during the 20 months preceding and 20 months following the USPSTF recommendation, researchers found significant increases during the latter time period, with the greatest increases among persons of high socioeconomic status or living in metropolitan areas.

Another study addressed concerns that younger adults may be less likely to follow up on positive screening results or more likely to have false positives on a fecal immunochemical test (FIT). Patients aged 45-49 years were slightly less likely to have a positive FIT result than 50-year-olds, but they had similar rates of colonoscopy completion and similar percentages of abnormal findings on colonoscopy.

Although the sensitivity and specificity of FIT varies quite a bit across different test brands, its overall effectiveness at reducing colorectal cancer deaths is well established. In 2024, the Food and Drug Administration approved three new screening options: a blood-based screening test (Shield), a next-generation multitarget stool DNA test (Cologuard Plus), and a multitarget stool RNA test (ColoSense) with similar performance characteristics as Cologuard Plus. The latter two tests will become available early next year.

This profusion of noninvasive options for CRC screening will challenge those tasked with developing the next iteration of the USPSTF recommendations. Not only must future guidelines establish what evidence threshold is sufficient to recommend a new screening strategy, but they also will need to consider the population-level consequences of relative utilization of different tests. For example, a cost-effectiveness analysis found that more CRC deaths would occur if people who would have otherwise accepted colonoscopy or fecal tests chose to be screened with Shield instead; however, this negative outcome could be offset if for every three of these test substitutions, two other people chose Shield who would otherwise have not been screened at all.

In the meantime, it is important for primary care clinicians to be familiar with evidence-based intervals for CRC screening tests and test eligibility criteria. A troubling study of patients who completed a multitarget stool DNA test in a Midwestern health system in 2021 found that more than one in five had the test ordered inappropriately, based on USPSTF guidelines. Reasons for inappropriate testing included having had a colonoscopy within the past 10 years, a family history of CRC, symptoms suggestive of possible CRC, age younger than 45, and a prior diagnosis of colonic adenomas. 

Just as a medication works best when the patient takes it as prescribed, a CRC screening test is most likely to yield more benefit than harm when it’s provided to the right patient at the right time.

Dr. Lin is Associate Director, Family Medicine Residency Program, at Lancaster General Hospital in Pennsylvania. He reported no relevant conflicts of interest.

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

It has been three and a half years since the US Preventive Services Task Force (USPSTF) lowered the age to start colorectal cancer (CRC) screening from 50 to 45. As I mentioned in a previous commentary, two major medical groups — the American Academy of Family Physicians and the American College of Physicians — felt that the evidence was insufficient to support this change. 

Did doctors adjust their screening practices? A recent study suggests that they have. Comparing CRC screening rates in more than 10 million adults aged 45-49 during the 20 months preceding and 20 months following the USPSTF recommendation, researchers found significant increases during the latter time period, with the greatest increases among persons of high socioeconomic status or living in metropolitan areas.

Another study addressed concerns that younger adults may be less likely to follow up on positive screening results or more likely to have false positives on a fecal immunochemical test (FIT). Patients aged 45-49 years were slightly less likely to have a positive FIT result than 50-year-olds, but they had similar rates of colonoscopy completion and similar percentages of abnormal findings on colonoscopy.

Although the sensitivity and specificity of FIT varies quite a bit across different test brands, its overall effectiveness at reducing colorectal cancer deaths is well established. In 2024, the Food and Drug Administration approved three new screening options: a blood-based screening test (Shield), a next-generation multitarget stool DNA test (Cologuard Plus), and a multitarget stool RNA test (ColoSense) with similar performance characteristics as Cologuard Plus. The latter two tests will become available early next year.

This profusion of noninvasive options for CRC screening will challenge those tasked with developing the next iteration of the USPSTF recommendations. Not only must future guidelines establish what evidence threshold is sufficient to recommend a new screening strategy, but they also will need to consider the population-level consequences of relative utilization of different tests. For example, a cost-effectiveness analysis found that more CRC deaths would occur if people who would have otherwise accepted colonoscopy or fecal tests chose to be screened with Shield instead; however, this negative outcome could be offset if for every three of these test substitutions, two other people chose Shield who would otherwise have not been screened at all.

In the meantime, it is important for primary care clinicians to be familiar with evidence-based intervals for CRC screening tests and test eligibility criteria. A troubling study of patients who completed a multitarget stool DNA test in a Midwestern health system in 2021 found that more than one in five had the test ordered inappropriately, based on USPSTF guidelines. Reasons for inappropriate testing included having had a colonoscopy within the past 10 years, a family history of CRC, symptoms suggestive of possible CRC, age younger than 45, and a prior diagnosis of colonic adenomas. 

Just as a medication works best when the patient takes it as prescribed, a CRC screening test is most likely to yield more benefit than harm when it’s provided to the right patient at the right time.

Dr. Lin is Associate Director, Family Medicine Residency Program, at Lancaster General Hospital in Pennsylvania. He reported no relevant conflicts of interest.

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

TOPLINE:

After the US Preventive Services Task Force (USPSTF) in May 2021 lowered from 50 to 45 the recommended age to begin colorectal cancer (CRC) screening for average-risk adults, there was a threefold increase in screening rates among individuals aged 45-49, but disparities by socioeconomic status and locality occurred.

METHODOLOGY:

• Researchers compared absolute and relative changes in screening uptake among average-risk adults 45-49 years between a 20-month period before and a 20-month period after the USPSTF recommendation was issued (May 1, 2018, to December 31, 2019, and May 1, 2021, to December 31, 2022). Data was evaluated bimonthly.
• They analyzed claims data from more than 10.2 million people with private Blue Cross Blue Shield (BCBS) coverage, with about three million eligible for screening during each bimonthly period, both pre- and post-recommendation.
• They used interrupted time-series analysis and autoregressive integrated moving average models to gauge changes in screening rates.

TAKEAWAY:

• Mean CRC screening uptake in average-risk adults 45-49 years increased from 0.50% in the pre-recommendation period to 1.51% post-recommendation, reflecting a significant absolute change of 1.01 percentage points but no significant relative change.
• Adults 45-49 years living in areas with the highest socioeconomic status (SES) had the largest absolute change in screening uptake compared with peers in the lowest SES areas (1.25 vs 0.75 percentage points). Relative changes were not significant.
• The absolute change in screening uptake was higher among individuals in metropolitan areas than individuals in nonmetropolitan areas (1.06 vs 0.73 percentage points). Again, relative changes were not significant.
• The screening uptake rate increased the fastest among those living in the highest SES and metropolitan areas (0.24 and 0.20 percentage points every 2 months, respectively).
• By December 2022 (the end of the post-recommendation period), CRC screening uptake among adults 45-49 years were on par with those seen in adults 50-75 years (2.37% vs 2.4%). Nonetheless, only 11.5% of average-risk adults aged 45-49 years received CRC screening during the post-recommendation period.

IN PRACTICE:

“The threefold increase in screening uptake among average-risk individuals aged 45-49 years reflects an accomplishment, yet evidence of widening disparities based on SDI [Social Deprivation Index] and locality indicate that population subgroups may not be benefiting equally from this change in CRC screening recommendation. Furthermore, given that only 11.5% of average-risk individuals aged 45-49 years during the post-recommendation period received CRC screening before the age of 50 years, targeted initiatives to improve screening in this age group are warranted to reach the national goal of screening 80% of the population in every community,” the researchers wrote.

SOURCE:

The study, with first author Sunny Siddique, MPH, with Yale School of Public Health, New Haven, Connecticut, was published online in JAMA Network Open. 

LIMITATIONS:

Data on race and ethnicity were incomplete, which may have impacted the analysis of disparities. The study cohort may not be fully representative of the general US population because BCBS beneficiaries tend to be younger and more socioeconomically advantaged with employer-based insurance. Specific information on the type of coverage provided by each beneficiary’s insurance plan was not available.

DISCLOSURES:

The study was funded by the National Cancer Institute. The authors declared no relevant conflicts of interest.

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

TOPLINE:

After the US Preventive Services Task Force (USPSTF) in May 2021 lowered from 50 to 45 the recommended age to begin colorectal cancer (CRC) screening for average-risk adults, there was a threefold increase in screening rates among individuals aged 45-49, but disparities by socioeconomic status and locality occurred.

METHODOLOGY:

• Researchers compared absolute and relative changes in screening uptake among average-risk adults 45-49 years between a 20-month period before and a 20-month period after the USPSTF recommendation was issued (May 1, 2018, to December 31, 2019, and May 1, 2021, to December 31, 2022). Data was evaluated bimonthly.
• They analyzed claims data from more than 10.2 million people with private Blue Cross Blue Shield (BCBS) coverage, with about three million eligible for screening during each bimonthly period, both pre- and post-recommendation.
• They used interrupted time-series analysis and autoregressive integrated moving average models to gauge changes in screening rates.

TAKEAWAY:

• Mean CRC screening uptake in average-risk adults 45-49 years increased from 0.50% in the pre-recommendation period to 1.51% post-recommendation, reflecting a significant absolute change of 1.01 percentage points but no significant relative change.
• Adults 45-49 years living in areas with the highest socioeconomic status (SES) had the largest absolute change in screening uptake compared with peers in the lowest SES areas (1.25 vs 0.75 percentage points). Relative changes were not significant.
• The absolute change in screening uptake was higher among individuals in metropolitan areas than individuals in nonmetropolitan areas (1.06 vs 0.73 percentage points). Again, relative changes were not significant.
• The screening uptake rate increased the fastest among those living in the highest SES and metropolitan areas (0.24 and 0.20 percentage points every 2 months, respectively).
• By December 2022 (the end of the post-recommendation period), CRC screening uptake among adults 45-49 years were on par with those seen in adults 50-75 years (2.37% vs 2.4%). Nonetheless, only 11.5% of average-risk adults aged 45-49 years received CRC screening during the post-recommendation period.

IN PRACTICE:

“The threefold increase in screening uptake among average-risk individuals aged 45-49 years reflects an accomplishment, yet evidence of widening disparities based on SDI [Social Deprivation Index] and locality indicate that population subgroups may not be benefiting equally from this change in CRC screening recommendation. Furthermore, given that only 11.5% of average-risk individuals aged 45-49 years during the post-recommendation period received CRC screening before the age of 50 years, targeted initiatives to improve screening in this age group are warranted to reach the national goal of screening 80% of the population in every community,” the researchers wrote.

SOURCE:

The study, with first author Sunny Siddique, MPH, with Yale School of Public Health, New Haven, Connecticut, was published online in JAMA Network Open. 

LIMITATIONS:

Data on race and ethnicity were incomplete, which may have impacted the analysis of disparities. The study cohort may not be fully representative of the general US population because BCBS beneficiaries tend to be younger and more socioeconomically advantaged with employer-based insurance. Specific information on the type of coverage provided by each beneficiary’s insurance plan was not available.

DISCLOSURES:

The study was funded by the National Cancer Institute. The authors declared no relevant conflicts of interest.

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

TOPLINE:

After the US Preventive Services Task Force (USPSTF) in May 2021 lowered from 50 to 45 the recommended age to begin colorectal cancer (CRC) screening for average-risk adults, there was a threefold increase in screening rates among individuals aged 45-49, but disparities by socioeconomic status and locality occurred.

METHODOLOGY:

• Researchers compared absolute and relative changes in screening uptake among average-risk adults 45-49 years between a 20-month period before and a 20-month period after the USPSTF recommendation was issued (May 1, 2018, to December 31, 2019, and May 1, 2021, to December 31, 2022). Data was evaluated bimonthly.
• They analyzed claims data from more than 10.2 million people with private Blue Cross Blue Shield (BCBS) coverage, with about three million eligible for screening during each bimonthly period, both pre- and post-recommendation.
• They used interrupted time-series analysis and autoregressive integrated moving average models to gauge changes in screening rates.

TAKEAWAY:

• Mean CRC screening uptake in average-risk adults 45-49 years increased from 0.50% in the pre-recommendation period to 1.51% post-recommendation, reflecting a significant absolute change of 1.01 percentage points but no significant relative change.
• Adults 45-49 years living in areas with the highest socioeconomic status (SES) had the largest absolute change in screening uptake compared with peers in the lowest SES areas (1.25 vs 0.75 percentage points). Relative changes were not significant.
• The absolute change in screening uptake was higher among individuals in metropolitan areas than individuals in nonmetropolitan areas (1.06 vs 0.73 percentage points). Again, relative changes were not significant.
• The screening uptake rate increased the fastest among those living in the highest SES and metropolitan areas (0.24 and 0.20 percentage points every 2 months, respectively).
• By December 2022 (the end of the post-recommendation period), CRC screening uptake among adults 45-49 years were on par with those seen in adults 50-75 years (2.37% vs 2.4%). Nonetheless, only 11.5% of average-risk adults aged 45-49 years received CRC screening during the post-recommendation period.

IN PRACTICE:

“The threefold increase in screening uptake among average-risk individuals aged 45-49 years reflects an accomplishment, yet evidence of widening disparities based on SDI [Social Deprivation Index] and locality indicate that population subgroups may not be benefiting equally from this change in CRC screening recommendation. Furthermore, given that only 11.5% of average-risk individuals aged 45-49 years during the post-recommendation period received CRC screening before the age of 50 years, targeted initiatives to improve screening in this age group are warranted to reach the national goal of screening 80% of the population in every community,” the researchers wrote.

SOURCE:

The study, with first author Sunny Siddique, MPH, with Yale School of Public Health, New Haven, Connecticut, was published online in JAMA Network Open. 

LIMITATIONS:

Data on race and ethnicity were incomplete, which may have impacted the analysis of disparities. The study cohort may not be fully representative of the general US population because BCBS beneficiaries tend to be younger and more socioeconomically advantaged with employer-based insurance. Specific information on the type of coverage provided by each beneficiary’s insurance plan was not available.

DISCLOSURES:

The study was funded by the National Cancer Institute. The authors declared no relevant conflicts of interest.

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