News

TOPLINE:

A substantial proportion of older adults with early rheumatoid arthritis (RA) initiate glucocorticoids before receiving care from a rheumatologist. The early initiation of glucocorticoids in this group is associated with prolonged use.

METHODOLOGY:

• Researchers analyzed data from Medicare claims and Rheumatology Informatics System for Effectiveness registry of the American College of Rheumatology from 2016 to 2018 to assess the relationship between the timing of glucocorticoid initiation and the subsequent duration of glucocorticoid use in older adults with early RA in the United States.
• They included 1733 patients aged ≥ 65 years (mean age, 76 years; 67% women) with early RA.
• Glucocorticoid initiation was defined as the first use between 3 months before and 6 months after entrance into rheumatology care.
• The continuous administration of glucocorticoid therapy was monitored for all individuals who initiated glucocorticoid treatment for up to 12 months after entering rheumatology care.
• The primary outcome was the duration of continuous glucocorticoid use after entering rheumatology care.

TAKEAWAY:

• Glucocorticoids were initiated in 41% of patients, with 65% starting them before the initial RA diagnosis by a rheumatologist. The median duration of glucocorticoid use was 157 days.
• Patients with early RA who initiated glucocorticoids before entering rheumatology care showed a significantly longer duration of glucocorticoid use than those who initiated it later (median, 186 vs 97 days; P < .0001).
• Patients who initiated glucocorticoids before entering rheumatology care were 39% less likely to stop its use within 1 year (hazard ratio, 0.61; 95% CI, 0.51-0.74).
• The mean daily dose of glucocorticoids was < 5 mg/d for patients who received them for at least 3 months, indicating a trend toward low-dose, long-term use.

IN PRACTICE:

“Initiatives to reduce GC [glucocorticoid] exposure among patients with eRA [early RA] will likely require attention to rheumatology workforce shortages and close collaboration between rheumatologists and primary care clinicians to expedite referrals to rheumatology care,” the authors wrote.

SOURCE:

This study was led by Andriko Palmowski, MD, Department of Rheumatology and Clinical Immunology, Charité – Universitätsmedizin Berlin in Germany, and was published online in Seminars in Arthritis and Rheumatism.

LIMITATIONS:

The observational nature of this study limited the ability to establish causality between early glucocorticoid initiation and the prolonged use of glucocorticoids. Moreover, the study population was limited to older adults, which affected the generalizability of the findings to younger populations. It also did not account for the fact that patients with more severe early RA were more likely to start glucocorticoid therapy early and continue it for longer durations.

DISCLOSURES:

The study was supported by research grants from the Deutsche Autoimmun-Stiftung and other sources. Some authors declared receiving grant support, consultancy fees, honoraria, and travel expenses and had other ties with various pharmaceutical companies.

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:

A substantial proportion of older adults with early rheumatoid arthritis (RA) initiate glucocorticoids before receiving care from a rheumatologist. The early initiation of glucocorticoids in this group is associated with prolonged use.

METHODOLOGY:

• Researchers analyzed data from Medicare claims and Rheumatology Informatics System for Effectiveness registry of the American College of Rheumatology from 2016 to 2018 to assess the relationship between the timing of glucocorticoid initiation and the subsequent duration of glucocorticoid use in older adults with early RA in the United States.
• They included 1733 patients aged ≥ 65 years (mean age, 76 years; 67% women) with early RA.
• Glucocorticoid initiation was defined as the first use between 3 months before and 6 months after entrance into rheumatology care.
• The continuous administration of glucocorticoid therapy was monitored for all individuals who initiated glucocorticoid treatment for up to 12 months after entering rheumatology care.
• The primary outcome was the duration of continuous glucocorticoid use after entering rheumatology care.

TAKEAWAY:

• Glucocorticoids were initiated in 41% of patients, with 65% starting them before the initial RA diagnosis by a rheumatologist. The median duration of glucocorticoid use was 157 days.
• Patients with early RA who initiated glucocorticoids before entering rheumatology care showed a significantly longer duration of glucocorticoid use than those who initiated it later (median, 186 vs 97 days; P < .0001).
• Patients who initiated glucocorticoids before entering rheumatology care were 39% less likely to stop its use within 1 year (hazard ratio, 0.61; 95% CI, 0.51-0.74).
• The mean daily dose of glucocorticoids was < 5 mg/d for patients who received them for at least 3 months, indicating a trend toward low-dose, long-term use.

IN PRACTICE:

“Initiatives to reduce GC [glucocorticoid] exposure among patients with eRA [early RA] will likely require attention to rheumatology workforce shortages and close collaboration between rheumatologists and primary care clinicians to expedite referrals to rheumatology care,” the authors wrote.

SOURCE:

This study was led by Andriko Palmowski, MD, Department of Rheumatology and Clinical Immunology, Charité – Universitätsmedizin Berlin in Germany, and was published online in Seminars in Arthritis and Rheumatism.

LIMITATIONS:

The observational nature of this study limited the ability to establish causality between early glucocorticoid initiation and the prolonged use of glucocorticoids. Moreover, the study population was limited to older adults, which affected the generalizability of the findings to younger populations. It also did not account for the fact that patients with more severe early RA were more likely to start glucocorticoid therapy early and continue it for longer durations.

DISCLOSURES:

The study was supported by research grants from the Deutsche Autoimmun-Stiftung and other sources. Some authors declared receiving grant support, consultancy fees, honoraria, and travel expenses and had other ties with various pharmaceutical companies.

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:

A substantial proportion of older adults with early rheumatoid arthritis (RA) initiate glucocorticoids before receiving care from a rheumatologist. The early initiation of glucocorticoids in this group is associated with prolonged use.

METHODOLOGY:

• Researchers analyzed data from Medicare claims and Rheumatology Informatics System for Effectiveness registry of the American College of Rheumatology from 2016 to 2018 to assess the relationship between the timing of glucocorticoid initiation and the subsequent duration of glucocorticoid use in older adults with early RA in the United States.
• They included 1733 patients aged ≥ 65 years (mean age, 76 years; 67% women) with early RA.
• Glucocorticoid initiation was defined as the first use between 3 months before and 6 months after entrance into rheumatology care.
• The continuous administration of glucocorticoid therapy was monitored for all individuals who initiated glucocorticoid treatment for up to 12 months after entering rheumatology care.
• The primary outcome was the duration of continuous glucocorticoid use after entering rheumatology care.

TAKEAWAY:

• Glucocorticoids were initiated in 41% of patients, with 65% starting them before the initial RA diagnosis by a rheumatologist. The median duration of glucocorticoid use was 157 days.
• Patients with early RA who initiated glucocorticoids before entering rheumatology care showed a significantly longer duration of glucocorticoid use than those who initiated it later (median, 186 vs 97 days; P < .0001).
• Patients who initiated glucocorticoids before entering rheumatology care were 39% less likely to stop its use within 1 year (hazard ratio, 0.61; 95% CI, 0.51-0.74).
• The mean daily dose of glucocorticoids was < 5 mg/d for patients who received them for at least 3 months, indicating a trend toward low-dose, long-term use.

IN PRACTICE:

“Initiatives to reduce GC [glucocorticoid] exposure among patients with eRA [early RA] will likely require attention to rheumatology workforce shortages and close collaboration between rheumatologists and primary care clinicians to expedite referrals to rheumatology care,” the authors wrote.

SOURCE:

This study was led by Andriko Palmowski, MD, Department of Rheumatology and Clinical Immunology, Charité – Universitätsmedizin Berlin in Germany, and was published online in Seminars in Arthritis and Rheumatism.

LIMITATIONS:

The observational nature of this study limited the ability to establish causality between early glucocorticoid initiation and the prolonged use of glucocorticoids. Moreover, the study population was limited to older adults, which affected the generalizability of the findings to younger populations. It also did not account for the fact that patients with more severe early RA were more likely to start glucocorticoid therapy early and continue it for longer durations.

DISCLOSURES:

The study was supported by research grants from the Deutsche Autoimmun-Stiftung and other sources. Some authors declared receiving grant support, consultancy fees, honoraria, and travel expenses and had other ties with various pharmaceutical companies.

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.

The AGA editorial fellowship program, currently in its seventh year, selects several outstanding individuals who are interested in scientific publishing to take part in the year-long program. We are excited to announce the 2024-25 participants, who will gain hands-on experience and mentorship working closely with the editors and staff at the AGA journals over the next year.

The 10 editorial fellows (2 per journal) will learn about the entire editorial process, from manuscript submission to peer review to acceptance. They will participate in discussions and conferences with the boards of editors, assist with manuscript review, and help disseminate articles via their social media platforms.

AGA

Clinical Gastroenterology and Hepatology

Robyn Jordan, MD, MPH

Johns Hopkins Hospital, Baltimore | USA

Daryl Ramai, MD, MPH, MSc

Brigham and Women’s Hospital, Boston | USA
 

Cellular and Molecular Gastroenterology and Hepatology

Kole H. Buckley, PhD

University of Pennsylvania Perelman School of Medicine, Philadelphia | USA

Lin Y. Hung, PhD

New York University | USA
 

Gastroenterology

Corey J. Ketchem, MD

University of Pennsylvania, Philadelphia | USA

Rishad Khan, MD

University of Toronto | Canada
 

Gastro Hep Advances

Sasha Kapil, MD

UT Southwestern Medical Center, Dallas | USA

June Tome, MD

Mayo Clinic, Rochester, Minnesota | USA
 

Techniques and Innovations in Gastrointestinal Endoscopy

Thomas Enke, MD

University of Colorado, Aurora | USA

Sami Elamin, MD

Harvard, Beth Israel Deaconess Medical Center, Boston | USA

The AGA editorial fellowship program, currently in its seventh year, selects several outstanding individuals who are interested in scientific publishing to take part in the year-long program. We are excited to announce the 2024-25 participants, who will gain hands-on experience and mentorship working closely with the editors and staff at the AGA journals over the next year.

The 10 editorial fellows (2 per journal) will learn about the entire editorial process, from manuscript submission to peer review to acceptance. They will participate in discussions and conferences with the boards of editors, assist with manuscript review, and help disseminate articles via their social media platforms.

AGA

Clinical Gastroenterology and Hepatology

Robyn Jordan, MD, MPH

Johns Hopkins Hospital, Baltimore | USA

Daryl Ramai, MD, MPH, MSc

Brigham and Women’s Hospital, Boston | USA
 

Cellular and Molecular Gastroenterology and Hepatology

Kole H. Buckley, PhD

University of Pennsylvania Perelman School of Medicine, Philadelphia | USA

Lin Y. Hung, PhD

New York University | USA
 

Gastroenterology

Corey J. Ketchem, MD

University of Pennsylvania, Philadelphia | USA

Rishad Khan, MD

University of Toronto | Canada
 

Gastro Hep Advances

Sasha Kapil, MD

UT Southwestern Medical Center, Dallas | USA

June Tome, MD

Mayo Clinic, Rochester, Minnesota | USA
 

Techniques and Innovations in Gastrointestinal Endoscopy

Thomas Enke, MD

University of Colorado, Aurora | USA

Sami Elamin, MD

Harvard, Beth Israel Deaconess Medical Center, Boston | USA

The AGA editorial fellowship program, currently in its seventh year, selects several outstanding individuals who are interested in scientific publishing to take part in the year-long program. We are excited to announce the 2024-25 participants, who will gain hands-on experience and mentorship working closely with the editors and staff at the AGA journals over the next year.

The 10 editorial fellows (2 per journal) will learn about the entire editorial process, from manuscript submission to peer review to acceptance. They will participate in discussions and conferences with the boards of editors, assist with manuscript review, and help disseminate articles via their social media platforms.

AGA

Clinical Gastroenterology and Hepatology

Robyn Jordan, MD, MPH

Johns Hopkins Hospital, Baltimore | USA

Daryl Ramai, MD, MPH, MSc

Brigham and Women’s Hospital, Boston | USA
 

Cellular and Molecular Gastroenterology and Hepatology

Kole H. Buckley, PhD

University of Pennsylvania Perelman School of Medicine, Philadelphia | USA

Lin Y. Hung, PhD

New York University | USA
 

Gastroenterology

Corey J. Ketchem, MD

University of Pennsylvania, Philadelphia | USA

Rishad Khan, MD

University of Toronto | Canada
 

Gastro Hep Advances

Sasha Kapil, MD

UT Southwestern Medical Center, Dallas | USA

June Tome, MD

Mayo Clinic, Rochester, Minnesota | USA
 

Techniques and Innovations in Gastrointestinal Endoscopy

Thomas Enke, MD

University of Colorado, Aurora | USA

Sami Elamin, MD

Harvard, Beth Israel Deaconess Medical Center, Boston | USA

As an AGA member, you can help fund discoveries that will continue to improve GI practice and better patient care.

The AGA Research Foundation has helped make significant strides in advancing the treatment and cure of digestive diseases by funding talented investigators.

Planning your gift to benefit AGA Research Foundation in the future is an opportunity to express what matters to you. As an AGA member, you can work with the AGA Research Foundation to ensure that your planned gift is designated for a purpose that meets your goals for leaving a legacy—such as research awards, support for specific programs, or unrestricted gifts to help meet the Foundation’s mission.

In as little as one sentence in your will and/or trust, you can complete your gift: “I give to AGA Research Foundation, a nonprofit corporation currently located at 4930 Del Ray Avenue, Bethesda, MD 20814, or its successor thereto, _________ [written amount or percentage of the estate or description of property] for its unrestricted charitable use and purpose.”

If you have named the AGA Research Foundation in your will or trust, please let us know so we can ensure that your gift is used according to your wishes. Notifying us of your plans will enable us to plan for the use of your future gift. However, if you prefer to remain anonymous, we will keep your name and gift in strict confidence.

Please contact foundation@gastro.org for more information. If you are considering a planned gift, consult with your own legal and tax advisors.

As an AGA member, you can help fund discoveries that will continue to improve GI practice and better patient care.

The AGA Research Foundation has helped make significant strides in advancing the treatment and cure of digestive diseases by funding talented investigators.

Planning your gift to benefit AGA Research Foundation in the future is an opportunity to express what matters to you. As an AGA member, you can work with the AGA Research Foundation to ensure that your planned gift is designated for a purpose that meets your goals for leaving a legacy—such as research awards, support for specific programs, or unrestricted gifts to help meet the Foundation’s mission.

In as little as one sentence in your will and/or trust, you can complete your gift: “I give to AGA Research Foundation, a nonprofit corporation currently located at 4930 Del Ray Avenue, Bethesda, MD 20814, or its successor thereto, _________ [written amount or percentage of the estate or description of property] for its unrestricted charitable use and purpose.”

If you have named the AGA Research Foundation in your will or trust, please let us know so we can ensure that your gift is used according to your wishes. Notifying us of your plans will enable us to plan for the use of your future gift. However, if you prefer to remain anonymous, we will keep your name and gift in strict confidence.

Please contact foundation@gastro.org for more information. If you are considering a planned gift, consult with your own legal and tax advisors.

As an AGA member, you can help fund discoveries that will continue to improve GI practice and better patient care.

The AGA Research Foundation has helped make significant strides in advancing the treatment and cure of digestive diseases by funding talented investigators.

Planning your gift to benefit AGA Research Foundation in the future is an opportunity to express what matters to you. As an AGA member, you can work with the AGA Research Foundation to ensure that your planned gift is designated for a purpose that meets your goals for leaving a legacy—such as research awards, support for specific programs, or unrestricted gifts to help meet the Foundation’s mission.

In as little as one sentence in your will and/or trust, you can complete your gift: “I give to AGA Research Foundation, a nonprofit corporation currently located at 4930 Del Ray Avenue, Bethesda, MD 20814, or its successor thereto, _________ [written amount or percentage of the estate or description of property] for its unrestricted charitable use and purpose.”

If you have named the AGA Research Foundation in your will or trust, please let us know so we can ensure that your gift is used according to your wishes. Notifying us of your plans will enable us to plan for the use of your future gift. However, if you prefer to remain anonymous, we will keep your name and gift in strict confidence.

Please contact foundation@gastro.org for more information. If you are considering a planned gift, consult with your own legal and tax advisors.

Colonic strictures in patients with Crohn’s disease (CD) may not increase long-term risk of colorectal cancer (CRC), offering support for a conservative approach to stricture management, according to investigators.

Although 8% of patients with strictures in a multicenter study were diagnosed with CRC, this diagnosis was made either simultaneously or within 1 year of stricture diagnosis, suggesting that cancer may have driven stricture development, and not the other way around, lead author Thomas Hunaut, MD, of Université de Champagne-Ardenne, Reims, France, and colleagues reported.

“The occurrence of colonic stricture in CD always raises concerns about the risk for dysplasia/cancer,” the investigators wrote in Gastro Hep Advances, noting that no consensus approach is currently available to guide stricture management. “Few studies with conflicting results have evaluated the frequency of CRC associated with colonic stricture in CD, and the natural history of colonic stricture in CD is poorly known.”The present retrospective study included 88 consecutive CD patients with 96 colorectal strictures who were managed at three French referral centers between 1993 and 2022.

Strictures were symptomatic in 62.5% of cases, not passable by scope in 61.4% of cases, and ulcerated in 70.5% of cases. Colonic resection was needed in 47.7% of patients, while endoscopic balloon dilation was performed in 13.6% of patients.

After a median follow-up of 21.5 months, seven patients (8%) were diagnosed with malignant stricture, including five cases of colonic adenocarcinoma, one case of neuroendocrine carcinoma, and one case of B-cell lymphoproliferative neoplasia.

Malignant strictures were more common among older patients with longer disease duration and frequent obstructive symptoms; however, these factors were not supported by multivariate analyses, likely due to sample size, according to the investigators.

Instead, Dr. Hunaut and colleagues highlighted the timing of the diagnoses. In four out of seven patients with malignant stricture, both stricture and cancer were diagnosed at the same time. In the remaining three patients, cancer was diagnosed at 3 months, 8 months, and 12 months after stricture diagnosis. No cases of cancer were diagnosed later than 1 year after the stricture diagnosis.

“We believe that this result is important for the management of colonic strictures complicating CD in clinical practice,” Dr. Hunaut and colleagues wrote.

The simultaneity or proximity of the diagnoses suggests that the “strictures observed are already a neoplastic complication of the colonic inflammatory disease,” they explained.

In other words, common concerns about strictures causing cancer at the same site could be unfounded.

This conclusion echoes a recent administrative database study that reported no independent association between colorectal stricture and CRC, the investigators noted.

“Given the recent evidence on the risk of cancer associated with colonic strictures in CD, systematic colectomy is probably no longer justified,” they wrote. “Factors such as a long disease duration, primary sclerosing cholangitis, a history of dysplasia, and nonpassable and/or symptomatic stricture despite endoscopic dilation tend to argue in favor of surgery — especially if limited resection is possible.”

In contrast, patients with strictures who have low risk of CRC may be better served by a conservative approach, including endoscopy and systematic biopsies, followed by close endoscopic surveillance, according to the investigators. If the stricture is impassable, they recommended endoscopic balloon dilation, followed by intensification of medical therapy if ulceration is observed.

The investigators disclosed relationships with MSD, Ferring, Biogen, and others.

Colonic strictures in patients with Crohn’s disease (CD) may not increase long-term risk of colorectal cancer (CRC), offering support for a conservative approach to stricture management, according to investigators.

Although 8% of patients with strictures in a multicenter study were diagnosed with CRC, this diagnosis was made either simultaneously or within 1 year of stricture diagnosis, suggesting that cancer may have driven stricture development, and not the other way around, lead author Thomas Hunaut, MD, of Université de Champagne-Ardenne, Reims, France, and colleagues reported.

“The occurrence of colonic stricture in CD always raises concerns about the risk for dysplasia/cancer,” the investigators wrote in Gastro Hep Advances, noting that no consensus approach is currently available to guide stricture management. “Few studies with conflicting results have evaluated the frequency of CRC associated with colonic stricture in CD, and the natural history of colonic stricture in CD is poorly known.”The present retrospective study included 88 consecutive CD patients with 96 colorectal strictures who were managed at three French referral centers between 1993 and 2022.

Strictures were symptomatic in 62.5% of cases, not passable by scope in 61.4% of cases, and ulcerated in 70.5% of cases. Colonic resection was needed in 47.7% of patients, while endoscopic balloon dilation was performed in 13.6% of patients.

After a median follow-up of 21.5 months, seven patients (8%) were diagnosed with malignant stricture, including five cases of colonic adenocarcinoma, one case of neuroendocrine carcinoma, and one case of B-cell lymphoproliferative neoplasia.

Malignant strictures were more common among older patients with longer disease duration and frequent obstructive symptoms; however, these factors were not supported by multivariate analyses, likely due to sample size, according to the investigators.

Instead, Dr. Hunaut and colleagues highlighted the timing of the diagnoses. In four out of seven patients with malignant stricture, both stricture and cancer were diagnosed at the same time. In the remaining three patients, cancer was diagnosed at 3 months, 8 months, and 12 months after stricture diagnosis. No cases of cancer were diagnosed later than 1 year after the stricture diagnosis.

“We believe that this result is important for the management of colonic strictures complicating CD in clinical practice,” Dr. Hunaut and colleagues wrote.

The simultaneity or proximity of the diagnoses suggests that the “strictures observed are already a neoplastic complication of the colonic inflammatory disease,” they explained.

In other words, common concerns about strictures causing cancer at the same site could be unfounded.

This conclusion echoes a recent administrative database study that reported no independent association between colorectal stricture and CRC, the investigators noted.

“Given the recent evidence on the risk of cancer associated with colonic strictures in CD, systematic colectomy is probably no longer justified,” they wrote. “Factors such as a long disease duration, primary sclerosing cholangitis, a history of dysplasia, and nonpassable and/or symptomatic stricture despite endoscopic dilation tend to argue in favor of surgery — especially if limited resection is possible.”

In contrast, patients with strictures who have low risk of CRC may be better served by a conservative approach, including endoscopy and systematic biopsies, followed by close endoscopic surveillance, according to the investigators. If the stricture is impassable, they recommended endoscopic balloon dilation, followed by intensification of medical therapy if ulceration is observed.

The investigators disclosed relationships with MSD, Ferring, Biogen, and others.

Colonic strictures in patients with Crohn’s disease (CD) may not increase long-term risk of colorectal cancer (CRC), offering support for a conservative approach to stricture management, according to investigators.

Although 8% of patients with strictures in a multicenter study were diagnosed with CRC, this diagnosis was made either simultaneously or within 1 year of stricture diagnosis, suggesting that cancer may have driven stricture development, and not the other way around, lead author Thomas Hunaut, MD, of Université de Champagne-Ardenne, Reims, France, and colleagues reported.

“The occurrence of colonic stricture in CD always raises concerns about the risk for dysplasia/cancer,” the investigators wrote in Gastro Hep Advances, noting that no consensus approach is currently available to guide stricture management. “Few studies with conflicting results have evaluated the frequency of CRC associated with colonic stricture in CD, and the natural history of colonic stricture in CD is poorly known.”The present retrospective study included 88 consecutive CD patients with 96 colorectal strictures who were managed at three French referral centers between 1993 and 2022.

Strictures were symptomatic in 62.5% of cases, not passable by scope in 61.4% of cases, and ulcerated in 70.5% of cases. Colonic resection was needed in 47.7% of patients, while endoscopic balloon dilation was performed in 13.6% of patients.

After a median follow-up of 21.5 months, seven patients (8%) were diagnosed with malignant stricture, including five cases of colonic adenocarcinoma, one case of neuroendocrine carcinoma, and one case of B-cell lymphoproliferative neoplasia.

Malignant strictures were more common among older patients with longer disease duration and frequent obstructive symptoms; however, these factors were not supported by multivariate analyses, likely due to sample size, according to the investigators.

Instead, Dr. Hunaut and colleagues highlighted the timing of the diagnoses. In four out of seven patients with malignant stricture, both stricture and cancer were diagnosed at the same time. In the remaining three patients, cancer was diagnosed at 3 months, 8 months, and 12 months after stricture diagnosis. No cases of cancer were diagnosed later than 1 year after the stricture diagnosis.

“We believe that this result is important for the management of colonic strictures complicating CD in clinical practice,” Dr. Hunaut and colleagues wrote.

The simultaneity or proximity of the diagnoses suggests that the “strictures observed are already a neoplastic complication of the colonic inflammatory disease,” they explained.

In other words, common concerns about strictures causing cancer at the same site could be unfounded.

This conclusion echoes a recent administrative database study that reported no independent association between colorectal stricture and CRC, the investigators noted.

“Given the recent evidence on the risk of cancer associated with colonic strictures in CD, systematic colectomy is probably no longer justified,” they wrote. “Factors such as a long disease duration, primary sclerosing cholangitis, a history of dysplasia, and nonpassable and/or symptomatic stricture despite endoscopic dilation tend to argue in favor of surgery — especially if limited resection is possible.”

In contrast, patients with strictures who have low risk of CRC may be better served by a conservative approach, including endoscopy and systematic biopsies, followed by close endoscopic surveillance, according to the investigators. If the stricture is impassable, they recommended endoscopic balloon dilation, followed by intensification of medical therapy if ulceration is observed.

The investigators disclosed relationships with MSD, Ferring, Biogen, and others.

Postoperative cognitive dysfunction (POCD) is a form of cognitive decline that involves a functional deterioration of activities of the nervous system, such as selective attention, vigilance, perception, learning, memory, executive function, verbal and language abilities, emotion, visuospatial and visuomotor skills. It occurs in the absence of cranial trauma or other brain injuries, and prevalence rates range from 36.6% in young adults to 42.4% in older adults, as a consequence of significant invasive procedures such as cardiac, noncardiac, and carotid surgeries that are lengthy and intensive.

Alzheimer’s disease (AD), the most common form of dementia, accounts for about two thirds of all cases of dementia globally. It is estimated that 41 million patients with dementia remain undiagnosed worldwide, and 25% of patients are diagnosed only when they are fully symptomatic. AD is a neurodegenerative disorder defined by neuropathologic changes, including beta-amyloid (Abeta) plaques composed of aggregated Abeta and neurofibrillary tangles containing aggregated tau proteins.

Patients with AD are unaware of their condition. Dementia, especially in its early stages, is often a hidden disease. Even when suspected, patients and families may believe that the symptoms are part of normal aging and may not report them to the doctor. In these patients, surgery may unmask subclinical dementia.

The complex correlation between POCD and AD has sparked debate following numerous anecdotal reports of how older adults undergoing surgical procedures may experience long-term cognitive decline with clinical characteristics such as those of patients with dementia. Despite advances in knowledge, it is still difficult to establish a priori how much surgery and anesthesia can increase the risk or accelerate the progression of a prodromal and asymptomatic AD condition (stages I-II) to clinically evident stage III AD. The current trend of an aging population poses a challenge for anesthesiology surgery because as the age of patients undergoing surgery increases, so does the likelihood of developing POCD.

Recent research in these fields has improved knowledge of the characteristics, epidemiology, risk factors, pathogenesis, and potential prevention strategies associated with POCD. It has improved the perspectives of future prevention and treatment.
 

Definition and Diagnostic Criteria

POCD, according to the cognitive impairment classification in the Diagnostic and Statistical Manual of Mental Disorders, Fifth Edition, is characterized by mild neurologic disturbance resulting from routine surgical procedures, excluding conditions such as deafness, dementia, or amnesia. The definition of POCD involves prolonged cognitive decline that can last for weeks, months, or even years. POCD may be confused with postoperative delirium, an acute and fluctuating disorder of consciousness that typically occurs within 3 days of surgery.

The diagnosis of POCD is based primarily on neurocognitive function scales. Widely used assessments include the Montreal Cognitive Assessment, the Wechsler Memory Scale, and the Mini-Mental State Examination.
 

Epidemiology

POCD is prevalent among patients undergoing cardiac or orthopedic surgery. In patients undergoing aortic-coronary bypass and cardiopulmonary bypass, 50%-70% develop POCD 1 week after surgery. In addition, 10%-30% experience long-term effects on cognitive function at 6 months after the procedure. In patients undergoing hip arthroplasty, 20%-50% exhibit POCD within 1 week of surgery, with 10%-14% still presenting it after 3 months.

Risk Factors

Age

POCD is typically observed in patients older than 65 years. However, after surgery, around 30% of younger patients and about 40% of older patients develop POCD at the time of hospital discharge. Specifically, 12.7% of older patients continue to have POCD 3 months after surgery, compared with 5% of younger patients.

Type of Surgery 

Hip and knee arthroplasty procedures entail a higher risk for POCD than general surgery. The same is true of cardiac surgery, especially aortic-coronary bypass and cardiopulmonary bypass.

Types of Anesthesia 

Initial assessments of postoperative cognitive function in cardiac surgery did not provide significant correlations between observed changes and the type of anesthesia because of the high number of confounding factors involved. A more recent meta-analysis of 28 randomized clinical trials concluded that the incidence of POCD is lower in surgeries using intravenous anesthesia with propofol than in those using inhalation anesthesia with isoflurane or sevoflurane.

Pain

Postoperative pain is a common issue, mainly resulting from substantial surgical trauma or potential wound infection. Patient-controlled postoperative analgesia independently increases the risk for POCD, compared with oral postoperative analgesia. Meta-analyses indicate that persistent pain can lead to a decline in patients’ cognitive abilities, attention, memory, and information processing.

Evolving Scenarios

Current research on POCD has deepened our understanding of its pathogenesis, implicating factors such as central nervous system inflammation, neuronal apoptosis, synaptic plasticity damage, abnormal tau protein modification, chronic pain, and mitochondrial metabolic disorders. Several neuroprotective drugs are currently under study, but none have shown consistent benefits for the prevention and treatment of POCD. The available evidence on the subject does not unambiguously guide the practicing physician. But neither does it exclude the importance of a careful assessment of POCD risk factors and the cognitive status of an older patient before surgery to provide useful information to the patient, family, and doctors when deciding on appropriate and shared procedures.

This story was translated from Univadis Italy, which is part of the Medscape professional network, 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.

Postoperative cognitive dysfunction (POCD) is a form of cognitive decline that involves a functional deterioration of activities of the nervous system, such as selective attention, vigilance, perception, learning, memory, executive function, verbal and language abilities, emotion, visuospatial and visuomotor skills. It occurs in the absence of cranial trauma or other brain injuries, and prevalence rates range from 36.6% in young adults to 42.4% in older adults, as a consequence of significant invasive procedures such as cardiac, noncardiac, and carotid surgeries that are lengthy and intensive.

Alzheimer’s disease (AD), the most common form of dementia, accounts for about two thirds of all cases of dementia globally. It is estimated that 41 million patients with dementia remain undiagnosed worldwide, and 25% of patients are diagnosed only when they are fully symptomatic. AD is a neurodegenerative disorder defined by neuropathologic changes, including beta-amyloid (Abeta) plaques composed of aggregated Abeta and neurofibrillary tangles containing aggregated tau proteins.

Patients with AD are unaware of their condition. Dementia, especially in its early stages, is often a hidden disease. Even when suspected, patients and families may believe that the symptoms are part of normal aging and may not report them to the doctor. In these patients, surgery may unmask subclinical dementia.

The complex correlation between POCD and AD has sparked debate following numerous anecdotal reports of how older adults undergoing surgical procedures may experience long-term cognitive decline with clinical characteristics such as those of patients with dementia. Despite advances in knowledge, it is still difficult to establish a priori how much surgery and anesthesia can increase the risk or accelerate the progression of a prodromal and asymptomatic AD condition (stages I-II) to clinically evident stage III AD. The current trend of an aging population poses a challenge for anesthesiology surgery because as the age of patients undergoing surgery increases, so does the likelihood of developing POCD.

Recent research in these fields has improved knowledge of the characteristics, epidemiology, risk factors, pathogenesis, and potential prevention strategies associated with POCD. It has improved the perspectives of future prevention and treatment.
 

Definition and Diagnostic Criteria

POCD, according to the cognitive impairment classification in the Diagnostic and Statistical Manual of Mental Disorders, Fifth Edition, is characterized by mild neurologic disturbance resulting from routine surgical procedures, excluding conditions such as deafness, dementia, or amnesia. The definition of POCD involves prolonged cognitive decline that can last for weeks, months, or even years. POCD may be confused with postoperative delirium, an acute and fluctuating disorder of consciousness that typically occurs within 3 days of surgery.

The diagnosis of POCD is based primarily on neurocognitive function scales. Widely used assessments include the Montreal Cognitive Assessment, the Wechsler Memory Scale, and the Mini-Mental State Examination.
 

Epidemiology

POCD is prevalent among patients undergoing cardiac or orthopedic surgery. In patients undergoing aortic-coronary bypass and cardiopulmonary bypass, 50%-70% develop POCD 1 week after surgery. In addition, 10%-30% experience long-term effects on cognitive function at 6 months after the procedure. In patients undergoing hip arthroplasty, 20%-50% exhibit POCD within 1 week of surgery, with 10%-14% still presenting it after 3 months.

Risk Factors

Age

POCD is typically observed in patients older than 65 years. However, after surgery, around 30% of younger patients and about 40% of older patients develop POCD at the time of hospital discharge. Specifically, 12.7% of older patients continue to have POCD 3 months after surgery, compared with 5% of younger patients.

Type of Surgery 

Hip and knee arthroplasty procedures entail a higher risk for POCD than general surgery. The same is true of cardiac surgery, especially aortic-coronary bypass and cardiopulmonary bypass.

Types of Anesthesia 

Initial assessments of postoperative cognitive function in cardiac surgery did not provide significant correlations between observed changes and the type of anesthesia because of the high number of confounding factors involved. A more recent meta-analysis of 28 randomized clinical trials concluded that the incidence of POCD is lower in surgeries using intravenous anesthesia with propofol than in those using inhalation anesthesia with isoflurane or sevoflurane.

Pain

Postoperative pain is a common issue, mainly resulting from substantial surgical trauma or potential wound infection. Patient-controlled postoperative analgesia independently increases the risk for POCD, compared with oral postoperative analgesia. Meta-analyses indicate that persistent pain can lead to a decline in patients’ cognitive abilities, attention, memory, and information processing.

Evolving Scenarios

Current research on POCD has deepened our understanding of its pathogenesis, implicating factors such as central nervous system inflammation, neuronal apoptosis, synaptic plasticity damage, abnormal tau protein modification, chronic pain, and mitochondrial metabolic disorders. Several neuroprotective drugs are currently under study, but none have shown consistent benefits for the prevention and treatment of POCD. The available evidence on the subject does not unambiguously guide the practicing physician. But neither does it exclude the importance of a careful assessment of POCD risk factors and the cognitive status of an older patient before surgery to provide useful information to the patient, family, and doctors when deciding on appropriate and shared procedures.

This story was translated from Univadis Italy, which is part of the Medscape professional network, 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.

Postoperative cognitive dysfunction (POCD) is a form of cognitive decline that involves a functional deterioration of activities of the nervous system, such as selective attention, vigilance, perception, learning, memory, executive function, verbal and language abilities, emotion, visuospatial and visuomotor skills. It occurs in the absence of cranial trauma or other brain injuries, and prevalence rates range from 36.6% in young adults to 42.4% in older adults, as a consequence of significant invasive procedures such as cardiac, noncardiac, and carotid surgeries that are lengthy and intensive.

Alzheimer’s disease (AD), the most common form of dementia, accounts for about two thirds of all cases of dementia globally. It is estimated that 41 million patients with dementia remain undiagnosed worldwide, and 25% of patients are diagnosed only when they are fully symptomatic. AD is a neurodegenerative disorder defined by neuropathologic changes, including beta-amyloid (Abeta) plaques composed of aggregated Abeta and neurofibrillary tangles containing aggregated tau proteins.

Patients with AD are unaware of their condition. Dementia, especially in its early stages, is often a hidden disease. Even when suspected, patients and families may believe that the symptoms are part of normal aging and may not report them to the doctor. In these patients, surgery may unmask subclinical dementia.

The complex correlation between POCD and AD has sparked debate following numerous anecdotal reports of how older adults undergoing surgical procedures may experience long-term cognitive decline with clinical characteristics such as those of patients with dementia. Despite advances in knowledge, it is still difficult to establish a priori how much surgery and anesthesia can increase the risk or accelerate the progression of a prodromal and asymptomatic AD condition (stages I-II) to clinically evident stage III AD. The current trend of an aging population poses a challenge for anesthesiology surgery because as the age of patients undergoing surgery increases, so does the likelihood of developing POCD.

Recent research in these fields has improved knowledge of the characteristics, epidemiology, risk factors, pathogenesis, and potential prevention strategies associated with POCD. It has improved the perspectives of future prevention and treatment.
 

Definition and Diagnostic Criteria

POCD, according to the cognitive impairment classification in the Diagnostic and Statistical Manual of Mental Disorders, Fifth Edition, is characterized by mild neurologic disturbance resulting from routine surgical procedures, excluding conditions such as deafness, dementia, or amnesia. The definition of POCD involves prolonged cognitive decline that can last for weeks, months, or even years. POCD may be confused with postoperative delirium, an acute and fluctuating disorder of consciousness that typically occurs within 3 days of surgery.

The diagnosis of POCD is based primarily on neurocognitive function scales. Widely used assessments include the Montreal Cognitive Assessment, the Wechsler Memory Scale, and the Mini-Mental State Examination.
 

Epidemiology

POCD is prevalent among patients undergoing cardiac or orthopedic surgery. In patients undergoing aortic-coronary bypass and cardiopulmonary bypass, 50%-70% develop POCD 1 week after surgery. In addition, 10%-30% experience long-term effects on cognitive function at 6 months after the procedure. In patients undergoing hip arthroplasty, 20%-50% exhibit POCD within 1 week of surgery, with 10%-14% still presenting it after 3 months.

Risk Factors

Age

POCD is typically observed in patients older than 65 years. However, after surgery, around 30% of younger patients and about 40% of older patients develop POCD at the time of hospital discharge. Specifically, 12.7% of older patients continue to have POCD 3 months after surgery, compared with 5% of younger patients.

Type of Surgery 

Hip and knee arthroplasty procedures entail a higher risk for POCD than general surgery. The same is true of cardiac surgery, especially aortic-coronary bypass and cardiopulmonary bypass.

Types of Anesthesia 

Initial assessments of postoperative cognitive function in cardiac surgery did not provide significant correlations between observed changes and the type of anesthesia because of the high number of confounding factors involved. A more recent meta-analysis of 28 randomized clinical trials concluded that the incidence of POCD is lower in surgeries using intravenous anesthesia with propofol than in those using inhalation anesthesia with isoflurane or sevoflurane.

Pain

Postoperative pain is a common issue, mainly resulting from substantial surgical trauma or potential wound infection. Patient-controlled postoperative analgesia independently increases the risk for POCD, compared with oral postoperative analgesia. Meta-analyses indicate that persistent pain can lead to a decline in patients’ cognitive abilities, attention, memory, and information processing.

Evolving Scenarios

Current research on POCD has deepened our understanding of its pathogenesis, implicating factors such as central nervous system inflammation, neuronal apoptosis, synaptic plasticity damage, abnormal tau protein modification, chronic pain, and mitochondrial metabolic disorders. Several neuroprotective drugs are currently under study, but none have shown consistent benefits for the prevention and treatment of POCD. The available evidence on the subject does not unambiguously guide the practicing physician. But neither does it exclude the importance of a careful assessment of POCD risk factors and the cognitive status of an older patient before surgery to provide useful information to the patient, family, and doctors when deciding on appropriate and shared procedures.

This story was translated from Univadis Italy, which is part of the Medscape professional network, 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.

As child psychiatrists and pediatricians, our mission extends beyond treating the physical health of children; it encompasses understanding the intricate web of factors that influence a child’s overall well-being. A recent advisory from U.S. Surgeon General Dr. Vivek Murthy has brought to light a critical issue that demands our attention: the declining mental health of parents and its profound impact on children. As providers who depend heavily on parental involvement to manage the needs of our pediatric patients, addressing parental mental health can be a crucial step in safeguarding the mental health of children.

The Surgeon General’s Advisory: A Call to Action

On August 28, 2024, the U.S. Surgeon General issued an advisory highlighting the significant stressors impacting parents and caregivers, and the broader implications for children’s mental health. The advisory emphasizes the bidirectional relationship between parental and child mental health, urging healthcare providers, policymakers, and communities to prioritize support for parents. It stresses that the mental health of parents is not only vital for their well-being but also plays a critical role in shaping the emotional and psychological development of their children.¹

The Link Between Parental and Child Mental Health

Research shows that a parent’s mental health directly influences the child’s emotional and behavioral outcomes. Children of parents with untreated mental health conditions, such as depression, anxiety, trauma, or chronic stress, are at a significantly higher risk of developing similar conditions. This risk is mediated through various mechanisms, including genetic predisposition, compromised parent-child interactions, and exposure to adverse environments.

1. Parental Depression and Child Outcomes: Parental depression, particularly maternal depression, has been extensively studied and is strongly associated with emotional and behavioral problems in children. Children of depressed parents are more likely to experience anxiety, depression, and resulting academic difficulties. Depressed parents may struggle with consistent and positive parenting, which can disrupt the development of secure attachments and emotional regulation in children.^2-4

2. Anxiety and Parenting Styles: Parental anxiety can influence parenting styles, often leading to overprotectiveness, inconsistency, or heightened criticism. These behaviors, in turn, can cultivate anxiety in children, creating a cycle that perpetuates mental health challenges across generations. Children raised in environments where anxiety is pervasive may learn to view the world as threatening, contributing to hypervigilance and stress.⁵

3. Impact of Chronic Stress on Parenting: Chronic stress experienced by parents, often due to financial hardship, lack of social support, or work-life imbalance, can impair their ability to engage in responsive and nurturing parenting. This, in turn, can affect children’s ability to meaningfully engage with parents to form secure attachments. Further, chronic stress can negatively impact the quality of parent-child interactions and fuel the cycle of rupture with limited opportunity for repair. The advisory stresses the need to address these systemic stressors as part of a broader public health strategy to support families.¹

Implications for Pediatric Practice

Pediatricians are often the first point of contact for families navigating mental health challenges. The Surgeon General’s advisory highlights the need for pediatricians to adopt a holistic approach that considers the mental health of the entire family, not just the child. This can be challenging with the average follow-up appointment time of 16 minutes, though many of the recommendations take this logistical hurdle into consideration:

1. Screening for Parental Mental Health: Incorporating routine screening for parental mental health into pediatric visits can be a powerful tool. Questions about parental stress, depression (especially postpartum depression), and anxiety should be integrated into well-child visits, especially in families where children present with emotional or behavioral difficulties. By identifying at-risk parents early, timely referrals to mental health services can be secured.

2. Providing Resources and Referrals: Offering resources and referrals to parents who may be struggling can positively impact the entire family. This includes connecting families with mental health professionals, parenting support groups, or community resources that can alleviate stressors such as food insecurity or lack of childcare. Having a list of local mental health resources available in your practice can empower parents to seek the help they need.

3. Promoting Positive Parenting Practices: Guidance on positive parenting practices, stress management, and self-care can make a significant difference in the mental health of parents and their children. Workshops or educational materials on topics like mindfulness, managing work-life balance, and fostering healthy communication within the family can be valuable and high-yield additions to pediatric care.

4. Collaborative Care Models: Collaborative care models, where pediatricians work closely with child psychiatrists, psychologists, and social workers, can provide comprehensive support to families. This integrated approach ensures that both children and their parents receive the care they need, promoting better outcomes for the entire family unit.
 

Addressing Broader Systemic Issues

The advisory also calls for systemic changes that extend beyond the clinic. Policy changes such as expanding access to paid family leave, affordable childcare, and mental health services are essential to creating an environment where parents can thrive. As pediatricians, advocating for these changes at the local and national level can amplify the overall impact on families.

1. Advocating for Paid Family Leave: Paid family leave allows parents to bond with their children and attend to their own mental health needs without the added pressure of financial instability. Supporting policies that provide adequate paid leave can pave the way for a successful and healthy return to work and have long-term benefits for family health.

2. Expanding Mental Health Services: Increasing access to mental health services, especially in underserved communities, is crucial. Pediatricians can play a role by partnering with local mental health providers to offer integrated care within their practices or community settings.

3. Community Support Programs: The creation of community support programs that offer parenting classes, stress management workshops, and peer support groups can help reduce the isolation and stress that many parents feel. Pediatricians can collaborate with community organizations to promote these resources to families.
 

Conclusion

The Surgeon General’s advisory serves as a timely reminder of the interconnectedness of parental and child mental health. Pediatricians have a unique opportunity to influence not only the health of their pediatric patients, but also the well-being of their families. By recognizing and addressing the mental health needs of parents, we can break the cycle of stress and mental illness that affects so many families, ensuring a healthier future for the next generation.

Let us embrace this call to action and work together to create a supportive environment where all parents and children can thrive.

Dr. Richards is assistant clinical professor in the department of psychiatry and biobehavioral sciences; program director of the child and adolescent psychiatry fellowship; and associate medical director of the perinatal program at the UCLA Semel Institute for Neuroscience and Human Behavior, Los Angeles.

References

1. American Hospital Association. Surgeon General Issues Advisory on Mental Health and Well-Being of Parents. American Hospital Association. 2024 Sep 4.

2. Goodman SH, Gotlib IH. Risk for Psychopathology in the Children of Depressed Mothers: A Developmental Model for Understanding Mechanisms of Transmission. Psychol Rev. 1999;106(3):458-490. doi: 10.1037/0033-295X.106.3.458.

3. Lovejoy MC et al. Maternal Depression and Parenting Behavior: A Meta-Analytic Review. Clin Psychol Rev. 2000;20(5):561-592. doi: 10.1016/s0272-7358(98)00100-7.

4. Weissman MM et al. Offspring of Depressed Parents: 20 Years Later. Am J Psychiatry. 2006;163(6):1001-1008. doi: 10.1176/ajp.2006.163.6.1001.

5. Smith KE, Pollak SD. Early Life Stress and Development: Potential Mechanisms for Adverse Outcomes. J Neurodev Disord. 2020;12(1):3-14. doi: 10.1186/s11689-020-09337-y.

As child psychiatrists and pediatricians, our mission extends beyond treating the physical health of children; it encompasses understanding the intricate web of factors that influence a child’s overall well-being. A recent advisory from U.S. Surgeon General Dr. Vivek Murthy has brought to light a critical issue that demands our attention: the declining mental health of parents and its profound impact on children. As providers who depend heavily on parental involvement to manage the needs of our pediatric patients, addressing parental mental health can be a crucial step in safeguarding the mental health of children.

The Surgeon General’s Advisory: A Call to Action

On August 28, 2024, the U.S. Surgeon General issued an advisory highlighting the significant stressors impacting parents and caregivers, and the broader implications for children’s mental health. The advisory emphasizes the bidirectional relationship between parental and child mental health, urging healthcare providers, policymakers, and communities to prioritize support for parents. It stresses that the mental health of parents is not only vital for their well-being but also plays a critical role in shaping the emotional and psychological development of their children.¹

The Link Between Parental and Child Mental Health

Research shows that a parent’s mental health directly influences the child’s emotional and behavioral outcomes. Children of parents with untreated mental health conditions, such as depression, anxiety, trauma, or chronic stress, are at a significantly higher risk of developing similar conditions. This risk is mediated through various mechanisms, including genetic predisposition, compromised parent-child interactions, and exposure to adverse environments.

1. Parental Depression and Child Outcomes: Parental depression, particularly maternal depression, has been extensively studied and is strongly associated with emotional and behavioral problems in children. Children of depressed parents are more likely to experience anxiety, depression, and resulting academic difficulties. Depressed parents may struggle with consistent and positive parenting, which can disrupt the development of secure attachments and emotional regulation in children.^2-4

2. Anxiety and Parenting Styles: Parental anxiety can influence parenting styles, often leading to overprotectiveness, inconsistency, or heightened criticism. These behaviors, in turn, can cultivate anxiety in children, creating a cycle that perpetuates mental health challenges across generations. Children raised in environments where anxiety is pervasive may learn to view the world as threatening, contributing to hypervigilance and stress.⁵

3. Impact of Chronic Stress on Parenting: Chronic stress experienced by parents, often due to financial hardship, lack of social support, or work-life imbalance, can impair their ability to engage in responsive and nurturing parenting. This, in turn, can affect children’s ability to meaningfully engage with parents to form secure attachments. Further, chronic stress can negatively impact the quality of parent-child interactions and fuel the cycle of rupture with limited opportunity for repair. The advisory stresses the need to address these systemic stressors as part of a broader public health strategy to support families.¹

Implications for Pediatric Practice

Pediatricians are often the first point of contact for families navigating mental health challenges. The Surgeon General’s advisory highlights the need for pediatricians to adopt a holistic approach that considers the mental health of the entire family, not just the child. This can be challenging with the average follow-up appointment time of 16 minutes, though many of the recommendations take this logistical hurdle into consideration:

1. Screening for Parental Mental Health: Incorporating routine screening for parental mental health into pediatric visits can be a powerful tool. Questions about parental stress, depression (especially postpartum depression), and anxiety should be integrated into well-child visits, especially in families where children present with emotional or behavioral difficulties. By identifying at-risk parents early, timely referrals to mental health services can be secured.

2. Providing Resources and Referrals: Offering resources and referrals to parents who may be struggling can positively impact the entire family. This includes connecting families with mental health professionals, parenting support groups, or community resources that can alleviate stressors such as food insecurity or lack of childcare. Having a list of local mental health resources available in your practice can empower parents to seek the help they need.

3. Promoting Positive Parenting Practices: Guidance on positive parenting practices, stress management, and self-care can make a significant difference in the mental health of parents and their children. Workshops or educational materials on topics like mindfulness, managing work-life balance, and fostering healthy communication within the family can be valuable and high-yield additions to pediatric care.

4. Collaborative Care Models: Collaborative care models, where pediatricians work closely with child psychiatrists, psychologists, and social workers, can provide comprehensive support to families. This integrated approach ensures that both children and their parents receive the care they need, promoting better outcomes for the entire family unit.
 

Addressing Broader Systemic Issues

The advisory also calls for systemic changes that extend beyond the clinic. Policy changes such as expanding access to paid family leave, affordable childcare, and mental health services are essential to creating an environment where parents can thrive. As pediatricians, advocating for these changes at the local and national level can amplify the overall impact on families.

1. Advocating for Paid Family Leave: Paid family leave allows parents to bond with their children and attend to their own mental health needs without the added pressure of financial instability. Supporting policies that provide adequate paid leave can pave the way for a successful and healthy return to work and have long-term benefits for family health.

2. Expanding Mental Health Services: Increasing access to mental health services, especially in underserved communities, is crucial. Pediatricians can play a role by partnering with local mental health providers to offer integrated care within their practices or community settings.

3. Community Support Programs: The creation of community support programs that offer parenting classes, stress management workshops, and peer support groups can help reduce the isolation and stress that many parents feel. Pediatricians can collaborate with community organizations to promote these resources to families.
 

Conclusion

The Surgeon General’s advisory serves as a timely reminder of the interconnectedness of parental and child mental health. Pediatricians have a unique opportunity to influence not only the health of their pediatric patients, but also the well-being of their families. By recognizing and addressing the mental health needs of parents, we can break the cycle of stress and mental illness that affects so many families, ensuring a healthier future for the next generation.

Let us embrace this call to action and work together to create a supportive environment where all parents and children can thrive.

Dr. Richards is assistant clinical professor in the department of psychiatry and biobehavioral sciences; program director of the child and adolescent psychiatry fellowship; and associate medical director of the perinatal program at the UCLA Semel Institute for Neuroscience and Human Behavior, Los Angeles.

References

1. American Hospital Association. Surgeon General Issues Advisory on Mental Health and Well-Being of Parents. American Hospital Association. 2024 Sep 4.

2. Goodman SH, Gotlib IH. Risk for Psychopathology in the Children of Depressed Mothers: A Developmental Model for Understanding Mechanisms of Transmission. Psychol Rev. 1999;106(3):458-490. doi: 10.1037/0033-295X.106.3.458.

3. Lovejoy MC et al. Maternal Depression and Parenting Behavior: A Meta-Analytic Review. Clin Psychol Rev. 2000;20(5):561-592. doi: 10.1016/s0272-7358(98)00100-7.

4. Weissman MM et al. Offspring of Depressed Parents: 20 Years Later. Am J Psychiatry. 2006;163(6):1001-1008. doi: 10.1176/ajp.2006.163.6.1001.

5. Smith KE, Pollak SD. Early Life Stress and Development: Potential Mechanisms for Adverse Outcomes. J Neurodev Disord. 2020;12(1):3-14. doi: 10.1186/s11689-020-09337-y.

As child psychiatrists and pediatricians, our mission extends beyond treating the physical health of children; it encompasses understanding the intricate web of factors that influence a child’s overall well-being. A recent advisory from U.S. Surgeon General Dr. Vivek Murthy has brought to light a critical issue that demands our attention: the declining mental health of parents and its profound impact on children. As providers who depend heavily on parental involvement to manage the needs of our pediatric patients, addressing parental mental health can be a crucial step in safeguarding the mental health of children.

The Surgeon General’s Advisory: A Call to Action

On August 28, 2024, the U.S. Surgeon General issued an advisory highlighting the significant stressors impacting parents and caregivers, and the broader implications for children’s mental health. The advisory emphasizes the bidirectional relationship between parental and child mental health, urging healthcare providers, policymakers, and communities to prioritize support for parents. It stresses that the mental health of parents is not only vital for their well-being but also plays a critical role in shaping the emotional and psychological development of their children.¹

The Link Between Parental and Child Mental Health

Research shows that a parent’s mental health directly influences the child’s emotional and behavioral outcomes. Children of parents with untreated mental health conditions, such as depression, anxiety, trauma, or chronic stress, are at a significantly higher risk of developing similar conditions. This risk is mediated through various mechanisms, including genetic predisposition, compromised parent-child interactions, and exposure to adverse environments.

1. Parental Depression and Child Outcomes: Parental depression, particularly maternal depression, has been extensively studied and is strongly associated with emotional and behavioral problems in children. Children of depressed parents are more likely to experience anxiety, depression, and resulting academic difficulties. Depressed parents may struggle with consistent and positive parenting, which can disrupt the development of secure attachments and emotional regulation in children.^2-4

2. Anxiety and Parenting Styles: Parental anxiety can influence parenting styles, often leading to overprotectiveness, inconsistency, or heightened criticism. These behaviors, in turn, can cultivate anxiety in children, creating a cycle that perpetuates mental health challenges across generations. Children raised in environments where anxiety is pervasive may learn to view the world as threatening, contributing to hypervigilance and stress.⁵

3. Impact of Chronic Stress on Parenting: Chronic stress experienced by parents, often due to financial hardship, lack of social support, or work-life imbalance, can impair their ability to engage in responsive and nurturing parenting. This, in turn, can affect children’s ability to meaningfully engage with parents to form secure attachments. Further, chronic stress can negatively impact the quality of parent-child interactions and fuel the cycle of rupture with limited opportunity for repair. The advisory stresses the need to address these systemic stressors as part of a broader public health strategy to support families.¹

Implications for Pediatric Practice

Pediatricians are often the first point of contact for families navigating mental health challenges. The Surgeon General’s advisory highlights the need for pediatricians to adopt a holistic approach that considers the mental health of the entire family, not just the child. This can be challenging with the average follow-up appointment time of 16 minutes, though many of the recommendations take this logistical hurdle into consideration:

1. Screening for Parental Mental Health: Incorporating routine screening for parental mental health into pediatric visits can be a powerful tool. Questions about parental stress, depression (especially postpartum depression), and anxiety should be integrated into well-child visits, especially in families where children present with emotional or behavioral difficulties. By identifying at-risk parents early, timely referrals to mental health services can be secured.

2. Providing Resources and Referrals: Offering resources and referrals to parents who may be struggling can positively impact the entire family. This includes connecting families with mental health professionals, parenting support groups, or community resources that can alleviate stressors such as food insecurity or lack of childcare. Having a list of local mental health resources available in your practice can empower parents to seek the help they need.

3. Promoting Positive Parenting Practices: Guidance on positive parenting practices, stress management, and self-care can make a significant difference in the mental health of parents and their children. Workshops or educational materials on topics like mindfulness, managing work-life balance, and fostering healthy communication within the family can be valuable and high-yield additions to pediatric care.

4. Collaborative Care Models: Collaborative care models, where pediatricians work closely with child psychiatrists, psychologists, and social workers, can provide comprehensive support to families. This integrated approach ensures that both children and their parents receive the care they need, promoting better outcomes for the entire family unit.
 

Addressing Broader Systemic Issues

The advisory also calls for systemic changes that extend beyond the clinic. Policy changes such as expanding access to paid family leave, affordable childcare, and mental health services are essential to creating an environment where parents can thrive. As pediatricians, advocating for these changes at the local and national level can amplify the overall impact on families.

1. Advocating for Paid Family Leave: Paid family leave allows parents to bond with their children and attend to their own mental health needs without the added pressure of financial instability. Supporting policies that provide adequate paid leave can pave the way for a successful and healthy return to work and have long-term benefits for family health.

2. Expanding Mental Health Services: Increasing access to mental health services, especially in underserved communities, is crucial. Pediatricians can play a role by partnering with local mental health providers to offer integrated care within their practices or community settings.

3. Community Support Programs: The creation of community support programs that offer parenting classes, stress management workshops, and peer support groups can help reduce the isolation and stress that many parents feel. Pediatricians can collaborate with community organizations to promote these resources to families.
 

Conclusion

The Surgeon General’s advisory serves as a timely reminder of the interconnectedness of parental and child mental health. Pediatricians have a unique opportunity to influence not only the health of their pediatric patients, but also the well-being of their families. By recognizing and addressing the mental health needs of parents, we can break the cycle of stress and mental illness that affects so many families, ensuring a healthier future for the next generation.

Let us embrace this call to action and work together to create a supportive environment where all parents and children can thrive.

Dr. Richards is assistant clinical professor in the department of psychiatry and biobehavioral sciences; program director of the child and adolescent psychiatry fellowship; and associate medical director of the perinatal program at the UCLA Semel Institute for Neuroscience and Human Behavior, Los Angeles.

References

1. American Hospital Association. Surgeon General Issues Advisory on Mental Health and Well-Being of Parents. American Hospital Association. 2024 Sep 4.

2. Goodman SH, Gotlib IH. Risk for Psychopathology in the Children of Depressed Mothers: A Developmental Model for Understanding Mechanisms of Transmission. Psychol Rev. 1999;106(3):458-490. doi: 10.1037/0033-295X.106.3.458.

3. Lovejoy MC et al. Maternal Depression and Parenting Behavior: A Meta-Analytic Review. Clin Psychol Rev. 2000;20(5):561-592. doi: 10.1016/s0272-7358(98)00100-7.

4. Weissman MM et al. Offspring of Depressed Parents: 20 Years Later. Am J Psychiatry. 2006;163(6):1001-1008. doi: 10.1176/ajp.2006.163.6.1001.

5. Smith KE, Pollak SD. Early Life Stress and Development: Potential Mechanisms for Adverse Outcomes. J Neurodev Disord. 2020;12(1):3-14. doi: 10.1186/s11689-020-09337-y.

While she cared deeply about her work, Melissa Adams*, a family nurse practitioner (NP) in Madison, Alabama, was being frequently triple-booked, didn’t feel respected by her office manager, and started to worry about becoming burned out. When she sought help, “the administration was tone-deaf,” she said. “When I asked about what I could do to prevent burnout, they sent me an article about it. It was clear to me that asking for respite from triple-booking and asking to be respected by my office manager wasn’t being heard ... so I thought, ‘how do I fly under the radar and get by with what I can?’ ” That meant focusing on patient care and refusing to take on additional responsibilities, like training new hires or working with students.

“You’re overworked and underpaid, and you start giving less and less of yourself,” Ms. Adams said in an interview.

Quiet quitting, defined as performing only the assigned tasks of the job without making any extra effort or going the proverbial extra mile, has gained attention in the press in recent years. A Gallup poll found that about 50% of the workforce were “quiet quitters” or disengaged.

It may be even more prevalent in healthcare, where a recent survey found that 57% of frontline medical staff, including NPs and physician assistants (PAs), report being disengaged at work.
 

The Causes of Quiet Quitting

Potential causes of quiet quitting among PAs and NPs include:

• Unrealistic care expectations. They ask you to give your all to patients, handle everything, and do it all in under 15 minutes since that’s how much time the appointment allows, Ms. Adams said.
• Lack of trust or respect. Physicians don’t always respect the role that PAs and NPs play in a practice.
• Dissatisfaction with leadership or administration. There’s often a feeling that the PA or NP isn’t “heard” or appreciated.
• Dissatisfaction with pay or working conditions.
• Moral injury. “There’s no way to escape being morally injured when you work with an at-risk population,” said Ms. Adams. “You may see someone who has 20-24 determinants of health, and you’re expected to schlep them through in 8 minutes — you know you’re not able to do what they need.”

What Quiet Quitting Looks Like

Terri Smith*, an NP at an academic medical center outpatient clinic in rural Vermont, said that, while she feels appreciated by her patients and her team, there’s poor communication from the administration, which has caused her to quietly quit.

“I stopped saying ‘yes’ to all the normal committee work and the extra stuff that used to add a lot to my professional enjoyment,” she said. “The last couple of years, my whole motto is to nod and smile when administration says to do something — to put your head down and take care of your patients.”

While the term “quiet quitting” may be new, the issue is not, said Bridget Roberts, PhD, a healthcare executive who ran a large physician’s group of 100 healthcare providers in Jacksonville, Florida, for a decade. “Quiet quitting is a fancy title for employees who are completely disengaged,” said Dr. Roberts. “When they’re on the way out, they ‘check the box’. That’s not a new thing.”

“Typically, the first thing you see is a lot of frustration in that they aren’t able to complete the tasks they have at hand,” said Rebecca Day, PMNHP, a doctoral-educated NP and director of nursing practice at a Federally Qualified Health Center in Corbin, Kentucky. “Staff may be overworked and not have enough time to do what’s required of them with patient care as well as the paperwork required behind the scenes. It [quiet quitting] is doing just enough to get by, but shortcutting as much as they can to try to save some time.”
 

Addressing Quiet Quitting

Those kinds of shortcuts may affect patients, admits Ms. Smith. “I do think it starts to seep into patient care,” she said. “And that really doesn’t feel good ... at our institution, I’m not just an NP — I’m the nurse, the doctor, the secretary — I’m everybody, and for the last year, almost every single day in clinic, I’m apologizing [to a patient] because we can’t do something.”

Watching for this frustration can help alert administrators to NPs and PAs who may be “checking out” at work. Open lines of communication can help you address the issue. “Ask questions like ‘What could we do differently to make your day easier?’” said Dr. Roberts. Understanding the day-to-day issues NPs and PAs face at work can help in developing a plan to address disengagement.

When Dr. Day sees quiet quitting at her practice, she talks with the advance practice provider about what’s causing the issue. “’Are you overworked? Are you understaffed? Are there problems at home? Do you feel you’re receiving inadequate pay?’ ” she said. “The first thing to do is address that and find mutual ground on the issues…deal with the person as a person and then go back and deal with the person as an employee. If your staff isn’t happy, your clinic isn’t going to be productive.”

Finally, while reasons for quiet quitting may vary, cultivating a collaborative atmosphere where NPs and PAs feel appreciated and valued can help reduce the risk for quiet quitting. “Get to know your advanced practice providers,” said Ms. Adams. “Understand their strengths and what they’re about. It’s not an ‘us vs them’ ... there is a lot more commonality when we approach it that way.” Respect for the integral role that NPs and PAs play in your practice can help reduce the risk for quiet quitting — and help provide better patient care.

*Names have been changed.

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

While she cared deeply about her work, Melissa Adams*, a family nurse practitioner (NP) in Madison, Alabama, was being frequently triple-booked, didn’t feel respected by her office manager, and started to worry about becoming burned out. When she sought help, “the administration was tone-deaf,” she said. “When I asked about what I could do to prevent burnout, they sent me an article about it. It was clear to me that asking for respite from triple-booking and asking to be respected by my office manager wasn’t being heard ... so I thought, ‘how do I fly under the radar and get by with what I can?’ ” That meant focusing on patient care and refusing to take on additional responsibilities, like training new hires or working with students.

“You’re overworked and underpaid, and you start giving less and less of yourself,” Ms. Adams said in an interview.

Quiet quitting, defined as performing only the assigned tasks of the job without making any extra effort or going the proverbial extra mile, has gained attention in the press in recent years. A Gallup poll found that about 50% of the workforce were “quiet quitters” or disengaged.

It may be even more prevalent in healthcare, where a recent survey found that 57% of frontline medical staff, including NPs and physician assistants (PAs), report being disengaged at work.
 

The Causes of Quiet Quitting

Potential causes of quiet quitting among PAs and NPs include:

• Unrealistic care expectations. They ask you to give your all to patients, handle everything, and do it all in under 15 minutes since that’s how much time the appointment allows, Ms. Adams said.
• Lack of trust or respect. Physicians don’t always respect the role that PAs and NPs play in a practice.
• Dissatisfaction with leadership or administration. There’s often a feeling that the PA or NP isn’t “heard” or appreciated.
• Dissatisfaction with pay or working conditions.
• Moral injury. “There’s no way to escape being morally injured when you work with an at-risk population,” said Ms. Adams. “You may see someone who has 20-24 determinants of health, and you’re expected to schlep them through in 8 minutes — you know you’re not able to do what they need.”

What Quiet Quitting Looks Like

Terri Smith*, an NP at an academic medical center outpatient clinic in rural Vermont, said that, while she feels appreciated by her patients and her team, there’s poor communication from the administration, which has caused her to quietly quit.

“I stopped saying ‘yes’ to all the normal committee work and the extra stuff that used to add a lot to my professional enjoyment,” she said. “The last couple of years, my whole motto is to nod and smile when administration says to do something — to put your head down and take care of your patients.”

While the term “quiet quitting” may be new, the issue is not, said Bridget Roberts, PhD, a healthcare executive who ran a large physician’s group of 100 healthcare providers in Jacksonville, Florida, for a decade. “Quiet quitting is a fancy title for employees who are completely disengaged,” said Dr. Roberts. “When they’re on the way out, they ‘check the box’. That’s not a new thing.”

“Typically, the first thing you see is a lot of frustration in that they aren’t able to complete the tasks they have at hand,” said Rebecca Day, PMNHP, a doctoral-educated NP and director of nursing practice at a Federally Qualified Health Center in Corbin, Kentucky. “Staff may be overworked and not have enough time to do what’s required of them with patient care as well as the paperwork required behind the scenes. It [quiet quitting] is doing just enough to get by, but shortcutting as much as they can to try to save some time.”
 

Addressing Quiet Quitting

Those kinds of shortcuts may affect patients, admits Ms. Smith. “I do think it starts to seep into patient care,” she said. “And that really doesn’t feel good ... at our institution, I’m not just an NP — I’m the nurse, the doctor, the secretary — I’m everybody, and for the last year, almost every single day in clinic, I’m apologizing [to a patient] because we can’t do something.”

Watching for this frustration can help alert administrators to NPs and PAs who may be “checking out” at work. Open lines of communication can help you address the issue. “Ask questions like ‘What could we do differently to make your day easier?’” said Dr. Roberts. Understanding the day-to-day issues NPs and PAs face at work can help in developing a plan to address disengagement.

When Dr. Day sees quiet quitting at her practice, she talks with the advance practice provider about what’s causing the issue. “’Are you overworked? Are you understaffed? Are there problems at home? Do you feel you’re receiving inadequate pay?’ ” she said. “The first thing to do is address that and find mutual ground on the issues…deal with the person as a person and then go back and deal with the person as an employee. If your staff isn’t happy, your clinic isn’t going to be productive.”

Finally, while reasons for quiet quitting may vary, cultivating a collaborative atmosphere where NPs and PAs feel appreciated and valued can help reduce the risk for quiet quitting. “Get to know your advanced practice providers,” said Ms. Adams. “Understand their strengths and what they’re about. It’s not an ‘us vs them’ ... there is a lot more commonality when we approach it that way.” Respect for the integral role that NPs and PAs play in your practice can help reduce the risk for quiet quitting — and help provide better patient care.

*Names have been changed.

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

While she cared deeply about her work, Melissa Adams*, a family nurse practitioner (NP) in Madison, Alabama, was being frequently triple-booked, didn’t feel respected by her office manager, and started to worry about becoming burned out. When she sought help, “the administration was tone-deaf,” she said. “When I asked about what I could do to prevent burnout, they sent me an article about it. It was clear to me that asking for respite from triple-booking and asking to be respected by my office manager wasn’t being heard ... so I thought, ‘how do I fly under the radar and get by with what I can?’ ” That meant focusing on patient care and refusing to take on additional responsibilities, like training new hires or working with students.

“You’re overworked and underpaid, and you start giving less and less of yourself,” Ms. Adams said in an interview.

Quiet quitting, defined as performing only the assigned tasks of the job without making any extra effort or going the proverbial extra mile, has gained attention in the press in recent years. A Gallup poll found that about 50% of the workforce were “quiet quitters” or disengaged.

It may be even more prevalent in healthcare, where a recent survey found that 57% of frontline medical staff, including NPs and physician assistants (PAs), report being disengaged at work.
 

The Causes of Quiet Quitting

Potential causes of quiet quitting among PAs and NPs include:

• Unrealistic care expectations. They ask you to give your all to patients, handle everything, and do it all in under 15 minutes since that’s how much time the appointment allows, Ms. Adams said.
• Lack of trust or respect. Physicians don’t always respect the role that PAs and NPs play in a practice.
• Dissatisfaction with leadership or administration. There’s often a feeling that the PA or NP isn’t “heard” or appreciated.
• Dissatisfaction with pay or working conditions.
• Moral injury. “There’s no way to escape being morally injured when you work with an at-risk population,” said Ms. Adams. “You may see someone who has 20-24 determinants of health, and you’re expected to schlep them through in 8 minutes — you know you’re not able to do what they need.”

What Quiet Quitting Looks Like

Terri Smith*, an NP at an academic medical center outpatient clinic in rural Vermont, said that, while she feels appreciated by her patients and her team, there’s poor communication from the administration, which has caused her to quietly quit.

“I stopped saying ‘yes’ to all the normal committee work and the extra stuff that used to add a lot to my professional enjoyment,” she said. “The last couple of years, my whole motto is to nod and smile when administration says to do something — to put your head down and take care of your patients.”

While the term “quiet quitting” may be new, the issue is not, said Bridget Roberts, PhD, a healthcare executive who ran a large physician’s group of 100 healthcare providers in Jacksonville, Florida, for a decade. “Quiet quitting is a fancy title for employees who are completely disengaged,” said Dr. Roberts. “When they’re on the way out, they ‘check the box’. That’s not a new thing.”

“Typically, the first thing you see is a lot of frustration in that they aren’t able to complete the tasks they have at hand,” said Rebecca Day, PMNHP, a doctoral-educated NP and director of nursing practice at a Federally Qualified Health Center in Corbin, Kentucky. “Staff may be overworked and not have enough time to do what’s required of them with patient care as well as the paperwork required behind the scenes. It [quiet quitting] is doing just enough to get by, but shortcutting as much as they can to try to save some time.”
 

Addressing Quiet Quitting

Those kinds of shortcuts may affect patients, admits Ms. Smith. “I do think it starts to seep into patient care,” she said. “And that really doesn’t feel good ... at our institution, I’m not just an NP — I’m the nurse, the doctor, the secretary — I’m everybody, and for the last year, almost every single day in clinic, I’m apologizing [to a patient] because we can’t do something.”

Watching for this frustration can help alert administrators to NPs and PAs who may be “checking out” at work. Open lines of communication can help you address the issue. “Ask questions like ‘What could we do differently to make your day easier?’” said Dr. Roberts. Understanding the day-to-day issues NPs and PAs face at work can help in developing a plan to address disengagement.

When Dr. Day sees quiet quitting at her practice, she talks with the advance practice provider about what’s causing the issue. “’Are you overworked? Are you understaffed? Are there problems at home? Do you feel you’re receiving inadequate pay?’ ” she said. “The first thing to do is address that and find mutual ground on the issues…deal with the person as a person and then go back and deal with the person as an employee. If your staff isn’t happy, your clinic isn’t going to be productive.”

Finally, while reasons for quiet quitting may vary, cultivating a collaborative atmosphere where NPs and PAs feel appreciated and valued can help reduce the risk for quiet quitting. “Get to know your advanced practice providers,” said Ms. Adams. “Understand their strengths and what they’re about. It’s not an ‘us vs them’ ... there is a lot more commonality when we approach it that way.” Respect for the integral role that NPs and PAs play in your practice can help reduce the risk for quiet quitting — and help provide better patient care.

*Names have been changed.

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

TOPLINE:

Current use of hydroxychloroquine is associated with a lower risk for myocardial infarction (MI), stroke, and other thromboembolic events in patients with systemic lupus erythematosus (SLE). This protective effect diminishes after discontinuation of hydroxychloroquine treatment.

METHODOLOGY:

• Researchers used a nested case-control design to evaluate the association between exposure to hydroxychloroquine and the risk for cardiovascular events in patients with SLE.
• They included 52,883 adults with SLE (mean age, 44.23 years; 86.6% women) identified from the National System of Health Databases, which includes 99% of the French population.
• Among these, 1981 individuals with composite cardiovascular conditions were matched with 16,892 control individuals without cardiovascular conditions.
• Patients were categorized on the basis of hydroxychloroquine exposure into current users (last exposure within 90 days before a cardiovascular event), remote users (91-365 days before), and nonusers (no exposure within 365 days).
• The study outcomes included a composite of cardiovascular events, including MI, stroke (including transient ischemic attack), and other thromboembolic events such as phlebitis, thrombophlebitis, venous thrombosis, venous thromboembolism, and pulmonary embolism.

TAKEAWAY:

• Current hydroxychloroquine users had lower odds of experiencing a composite cardiovascular outcome than nonusers (adjusted odds ratio [aOR], 0.63; 95% CI, 0.57-0.70).
• The odds of MI (aOR, 0.72; 95% CI, 0.60-0.87), stroke (aOR, 0.71; 95% CI, 0.61-0.83), and other thromboembolic events (aOR, 0.58; 95% CI, 0.48-0.69) were also lower among current users than among nonusers.
• No significant association was found for remote hydroxychloroquine exposure and the risk for composite cardiovascular events, MI, stroke, and other thromboembolic events.

IN PRACTICE:

“These findings support the protective association of hydroxychloroquine against CV [cardiovascular] events and underscore the importance of continuous hydroxychloroquine therapy for patients diagnosed with SLE,” the authors wrote.

SOURCE:

The study was led by Lamiae Grimaldi-Bensouda, PharmD, PhD, Department of Pharmacology, Hospital Group Paris-Saclay, Assistance Publique-Hôpitaux de Paris, France. It was published online on August 30, 2024, in JAMA Network Open.

LIMITATIONS:

The observational nature of the study may have introduced confounding. Current hydroxychloroquine users were younger than nonusers, with an average age difference of almost 5 years. Current hydroxychloroquine users had a twofold longer duration of onset of SLE and had a higher prevalence of chronic kidney disease compared with nonusers.

DISCLOSURES:

This study was funded by the Banque pour l’Investissement, Deeptech. Some authors declared having financial ties with various institutions and companies outside of the current study.
 

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:

Current use of hydroxychloroquine is associated with a lower risk for myocardial infarction (MI), stroke, and other thromboembolic events in patients with systemic lupus erythematosus (SLE). This protective effect diminishes after discontinuation of hydroxychloroquine treatment.

METHODOLOGY:

• Researchers used a nested case-control design to evaluate the association between exposure to hydroxychloroquine and the risk for cardiovascular events in patients with SLE.
• They included 52,883 adults with SLE (mean age, 44.23 years; 86.6% women) identified from the National System of Health Databases, which includes 99% of the French population.
• Among these, 1981 individuals with composite cardiovascular conditions were matched with 16,892 control individuals without cardiovascular conditions.
• Patients were categorized on the basis of hydroxychloroquine exposure into current users (last exposure within 90 days before a cardiovascular event), remote users (91-365 days before), and nonusers (no exposure within 365 days).
• The study outcomes included a composite of cardiovascular events, including MI, stroke (including transient ischemic attack), and other thromboembolic events such as phlebitis, thrombophlebitis, venous thrombosis, venous thromboembolism, and pulmonary embolism.

TAKEAWAY:

• Current hydroxychloroquine users had lower odds of experiencing a composite cardiovascular outcome than nonusers (adjusted odds ratio [aOR], 0.63; 95% CI, 0.57-0.70).
• The odds of MI (aOR, 0.72; 95% CI, 0.60-0.87), stroke (aOR, 0.71; 95% CI, 0.61-0.83), and other thromboembolic events (aOR, 0.58; 95% CI, 0.48-0.69) were also lower among current users than among nonusers.
• No significant association was found for remote hydroxychloroquine exposure and the risk for composite cardiovascular events, MI, stroke, and other thromboembolic events.

IN PRACTICE:

“These findings support the protective association of hydroxychloroquine against CV [cardiovascular] events and underscore the importance of continuous hydroxychloroquine therapy for patients diagnosed with SLE,” the authors wrote.

SOURCE:

The study was led by Lamiae Grimaldi-Bensouda, PharmD, PhD, Department of Pharmacology, Hospital Group Paris-Saclay, Assistance Publique-Hôpitaux de Paris, France. It was published online on August 30, 2024, in JAMA Network Open.

LIMITATIONS:

The observational nature of the study may have introduced confounding. Current hydroxychloroquine users were younger than nonusers, with an average age difference of almost 5 years. Current hydroxychloroquine users had a twofold longer duration of onset of SLE and had a higher prevalence of chronic kidney disease compared with nonusers.

DISCLOSURES:

This study was funded by the Banque pour l’Investissement, Deeptech. Some authors declared having financial ties with various institutions and companies outside of the current study.
 

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:

Current use of hydroxychloroquine is associated with a lower risk for myocardial infarction (MI), stroke, and other thromboembolic events in patients with systemic lupus erythematosus (SLE). This protective effect diminishes after discontinuation of hydroxychloroquine treatment.

METHODOLOGY:

• Researchers used a nested case-control design to evaluate the association between exposure to hydroxychloroquine and the risk for cardiovascular events in patients with SLE.
• They included 52,883 adults with SLE (mean age, 44.23 years; 86.6% women) identified from the National System of Health Databases, which includes 99% of the French population.
• Among these, 1981 individuals with composite cardiovascular conditions were matched with 16,892 control individuals without cardiovascular conditions.
• Patients were categorized on the basis of hydroxychloroquine exposure into current users (last exposure within 90 days before a cardiovascular event), remote users (91-365 days before), and nonusers (no exposure within 365 days).
• The study outcomes included a composite of cardiovascular events, including MI, stroke (including transient ischemic attack), and other thromboembolic events such as phlebitis, thrombophlebitis, venous thrombosis, venous thromboembolism, and pulmonary embolism.

TAKEAWAY:

• Current hydroxychloroquine users had lower odds of experiencing a composite cardiovascular outcome than nonusers (adjusted odds ratio [aOR], 0.63; 95% CI, 0.57-0.70).
• The odds of MI (aOR, 0.72; 95% CI, 0.60-0.87), stroke (aOR, 0.71; 95% CI, 0.61-0.83), and other thromboembolic events (aOR, 0.58; 95% CI, 0.48-0.69) were also lower among current users than among nonusers.
• No significant association was found for remote hydroxychloroquine exposure and the risk for composite cardiovascular events, MI, stroke, and other thromboembolic events.

IN PRACTICE:

“These findings support the protective association of hydroxychloroquine against CV [cardiovascular] events and underscore the importance of continuous hydroxychloroquine therapy for patients diagnosed with SLE,” the authors wrote.

SOURCE:

The study was led by Lamiae Grimaldi-Bensouda, PharmD, PhD, Department of Pharmacology, Hospital Group Paris-Saclay, Assistance Publique-Hôpitaux de Paris, France. It was published online on August 30, 2024, in JAMA Network Open.

LIMITATIONS:

The observational nature of the study may have introduced confounding. Current hydroxychloroquine users were younger than nonusers, with an average age difference of almost 5 years. Current hydroxychloroquine users had a twofold longer duration of onset of SLE and had a higher prevalence of chronic kidney disease compared with nonusers.

DISCLOSURES:

This study was funded by the Banque pour l’Investissement, Deeptech. Some authors declared having financial ties with various institutions and companies outside of the current study.
 

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.

A diet in which the primary source of fat is plant sources is associated with decreased mortality. Animal fat, on the other hand, is associated with an increased risk for death. These are the results of a study published in JAMA Internal Medicine that followed more than 600,000 participants over 2 decades.

Bin Zhao, PhD, of the National Clinical Research Center for Metabolic Diseases at the Key Laboratory of Diabetes Immunology in Changsha, China, and colleagues concluded from these data that consuming plant-based fats instead of animal fats could be beneficial for health and improve survival.

It may not be so simple, however. “We are one step ahead of the publication: We no longer just distinguish between animal and plant fats but mainly consider the composition,” said Stefan Lorkowski, PhD, chair of biochemistry and physiology of nutrition at the Institute of Nutritional Sciences at the University of Jena in Germany, in response to inquiries from this news organization.
 

What’s in a Fat?

Although Dr. Zhao and colleagues studied the effect of different plant and animal fat sources (eg, grains, nuts, legumes, plant oils, red and white meat, dairy, eggs, and fish), they did not consider the composition of the fatty acids that they contained. “It matters which dairy products, which plant oils, and which fish are consumed,” said Dr. Lorkowski.

The data analyzed in the Chinese study come from a prospective cohort study (NIH-AARP Diet and Health Study) conducted in the United States from 1995 to 2019. At the beginning, the 407,531 study participants (average age, 61 years) filled out dietary questionnaires once. They were then followed for up to 24 years for total and cardiovascular mortality.

During this period, 185,111 study participants died, including 58,526 from cardiovascular diseases. Participants who consumed the most plant-based fats, according to the dietary questionnaires filled out in 1995, had a lower risk for death than those who consumed the least plant-based fats. Their overall mortality risk was 9% lower, and their cardiovascular mortality risk was 14% lower. This finding was especially noticeable when it came to plant fats from grains or plant oils.
 

Animal Fat and Mortality

In contrast, a higher intake of animal fat was associated with both a higher overall mortality risk (16%) and a higher cardiovascular mortality risk (14%). This was especially true for fat from dairy products and eggs.

A trend towards a reduced overall and cardiovascular mortality risk was observed for fat from fish. “The fact that only a trend towards fish consumption was observed may be due to the study having many more meat eaters than fish eaters,” said Dr. Lorkowski.

Another imbalance limits the significance of the study, he added. The two groups, those who primarily consumed plant fats and those who primarily consumed animal fats, were already distinct at the beginning of the study. Those who consumed more plant fats were more likely to have diabetes, a higher body mass index (BMI), higher energy intake, and higher alcohol consumption but consumed more fiber, fruits, and vegetables and were more physically active. “They may have been trying to live healthier because they were sicker,” said Dr. Lorkowski.
 

Potential Confounding

Dr. Zhao and his team adjusted the results for various potential confounding factors, including age, gender, BMI, ethnicity, smoking, physical activity, education, marital status, diabetes, health status, vitamin intake, protein, carbohydrates, fiber, trans fats, cholesterol intake, and alcohol consumption. However, according to Dr. Lorkowski, “statistical adjustment is always incomplete, and confounding cannot be completely ruled out.”

Nevertheless, these results provide relevant insights for dietary recommendations that could help improve health and related outcomes, according to the authors. “Replacement of 5% energy from animal fat with 5% energy from plant fat, particularly fat from grains or vegetable oils, was associated with a lower risk for mortality: 4%-24% reduction in overall mortality and 5%-30% reduction in cardiovascular disease mortality.”
 

Fat Composition Matters

Animal fat, however, should not simply be replaced with plant fat, said Dr. Lorkowski. “Cold-water fish, which provides important long-chain omega-3 fatty acids, is also considered animal fat. And palm and coconut fat, while plant-based, contain unhealthy long-chain saturated fats. And the type of plant oils also makes a difference, whether one uses corn germ or sunflower oil rich in omega-6 fatty acids or flaxseed or rapeseed oil rich in omega-3 fatty acids.

“A diet rich in unsaturated fats, with sufficient and balanced intake of omega-3 and omega-6 fatty acids, that is also abundant in fiber-rich carbohydrate sources and plant-based protein, is always better than too much fat from animal sources.”

This story was translated from the Medscape German edition 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.

A diet in which the primary source of fat is plant sources is associated with decreased mortality. Animal fat, on the other hand, is associated with an increased risk for death. These are the results of a study published in JAMA Internal Medicine that followed more than 600,000 participants over 2 decades.

Bin Zhao, PhD, of the National Clinical Research Center for Metabolic Diseases at the Key Laboratory of Diabetes Immunology in Changsha, China, and colleagues concluded from these data that consuming plant-based fats instead of animal fats could be beneficial for health and improve survival.

It may not be so simple, however. “We are one step ahead of the publication: We no longer just distinguish between animal and plant fats but mainly consider the composition,” said Stefan Lorkowski, PhD, chair of biochemistry and physiology of nutrition at the Institute of Nutritional Sciences at the University of Jena in Germany, in response to inquiries from this news organization.
 

What’s in a Fat?

Although Dr. Zhao and colleagues studied the effect of different plant and animal fat sources (eg, grains, nuts, legumes, plant oils, red and white meat, dairy, eggs, and fish), they did not consider the composition of the fatty acids that they contained. “It matters which dairy products, which plant oils, and which fish are consumed,” said Dr. Lorkowski.

The data analyzed in the Chinese study come from a prospective cohort study (NIH-AARP Diet and Health Study) conducted in the United States from 1995 to 2019. At the beginning, the 407,531 study participants (average age, 61 years) filled out dietary questionnaires once. They were then followed for up to 24 years for total and cardiovascular mortality.

During this period, 185,111 study participants died, including 58,526 from cardiovascular diseases. Participants who consumed the most plant-based fats, according to the dietary questionnaires filled out in 1995, had a lower risk for death than those who consumed the least plant-based fats. Their overall mortality risk was 9% lower, and their cardiovascular mortality risk was 14% lower. This finding was especially noticeable when it came to plant fats from grains or plant oils.
 

Animal Fat and Mortality

In contrast, a higher intake of animal fat was associated with both a higher overall mortality risk (16%) and a higher cardiovascular mortality risk (14%). This was especially true for fat from dairy products and eggs.

A trend towards a reduced overall and cardiovascular mortality risk was observed for fat from fish. “The fact that only a trend towards fish consumption was observed may be due to the study having many more meat eaters than fish eaters,” said Dr. Lorkowski.

Another imbalance limits the significance of the study, he added. The two groups, those who primarily consumed plant fats and those who primarily consumed animal fats, were already distinct at the beginning of the study. Those who consumed more plant fats were more likely to have diabetes, a higher body mass index (BMI), higher energy intake, and higher alcohol consumption but consumed more fiber, fruits, and vegetables and were more physically active. “They may have been trying to live healthier because they were sicker,” said Dr. Lorkowski.
 

Potential Confounding

Dr. Zhao and his team adjusted the results for various potential confounding factors, including age, gender, BMI, ethnicity, smoking, physical activity, education, marital status, diabetes, health status, vitamin intake, protein, carbohydrates, fiber, trans fats, cholesterol intake, and alcohol consumption. However, according to Dr. Lorkowski, “statistical adjustment is always incomplete, and confounding cannot be completely ruled out.”

Nevertheless, these results provide relevant insights for dietary recommendations that could help improve health and related outcomes, according to the authors. “Replacement of 5% energy from animal fat with 5% energy from plant fat, particularly fat from grains or vegetable oils, was associated with a lower risk for mortality: 4%-24% reduction in overall mortality and 5%-30% reduction in cardiovascular disease mortality.”
 

Fat Composition Matters

Animal fat, however, should not simply be replaced with plant fat, said Dr. Lorkowski. “Cold-water fish, which provides important long-chain omega-3 fatty acids, is also considered animal fat. And palm and coconut fat, while plant-based, contain unhealthy long-chain saturated fats. And the type of plant oils also makes a difference, whether one uses corn germ or sunflower oil rich in omega-6 fatty acids or flaxseed or rapeseed oil rich in omega-3 fatty acids.

“A diet rich in unsaturated fats, with sufficient and balanced intake of omega-3 and omega-6 fatty acids, that is also abundant in fiber-rich carbohydrate sources and plant-based protein, is always better than too much fat from animal sources.”

This story was translated from the Medscape German edition 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.

A diet in which the primary source of fat is plant sources is associated with decreased mortality. Animal fat, on the other hand, is associated with an increased risk for death. These are the results of a study published in JAMA Internal Medicine that followed more than 600,000 participants over 2 decades.

Bin Zhao, PhD, of the National Clinical Research Center for Metabolic Diseases at the Key Laboratory of Diabetes Immunology in Changsha, China, and colleagues concluded from these data that consuming plant-based fats instead of animal fats could be beneficial for health and improve survival.

It may not be so simple, however. “We are one step ahead of the publication: We no longer just distinguish between animal and plant fats but mainly consider the composition,” said Stefan Lorkowski, PhD, chair of biochemistry and physiology of nutrition at the Institute of Nutritional Sciences at the University of Jena in Germany, in response to inquiries from this news organization.
 

What’s in a Fat?

Although Dr. Zhao and colleagues studied the effect of different plant and animal fat sources (eg, grains, nuts, legumes, plant oils, red and white meat, dairy, eggs, and fish), they did not consider the composition of the fatty acids that they contained. “It matters which dairy products, which plant oils, and which fish are consumed,” said Dr. Lorkowski.

The data analyzed in the Chinese study come from a prospective cohort study (NIH-AARP Diet and Health Study) conducted in the United States from 1995 to 2019. At the beginning, the 407,531 study participants (average age, 61 years) filled out dietary questionnaires once. They were then followed for up to 24 years for total and cardiovascular mortality.

During this period, 185,111 study participants died, including 58,526 from cardiovascular diseases. Participants who consumed the most plant-based fats, according to the dietary questionnaires filled out in 1995, had a lower risk for death than those who consumed the least plant-based fats. Their overall mortality risk was 9% lower, and their cardiovascular mortality risk was 14% lower. This finding was especially noticeable when it came to plant fats from grains or plant oils.
 

Animal Fat and Mortality

In contrast, a higher intake of animal fat was associated with both a higher overall mortality risk (16%) and a higher cardiovascular mortality risk (14%). This was especially true for fat from dairy products and eggs.

A trend towards a reduced overall and cardiovascular mortality risk was observed for fat from fish. “The fact that only a trend towards fish consumption was observed may be due to the study having many more meat eaters than fish eaters,” said Dr. Lorkowski.

Another imbalance limits the significance of the study, he added. The two groups, those who primarily consumed plant fats and those who primarily consumed animal fats, were already distinct at the beginning of the study. Those who consumed more plant fats were more likely to have diabetes, a higher body mass index (BMI), higher energy intake, and higher alcohol consumption but consumed more fiber, fruits, and vegetables and were more physically active. “They may have been trying to live healthier because they were sicker,” said Dr. Lorkowski.
 

Potential Confounding

Dr. Zhao and his team adjusted the results for various potential confounding factors, including age, gender, BMI, ethnicity, smoking, physical activity, education, marital status, diabetes, health status, vitamin intake, protein, carbohydrates, fiber, trans fats, cholesterol intake, and alcohol consumption. However, according to Dr. Lorkowski, “statistical adjustment is always incomplete, and confounding cannot be completely ruled out.”

Nevertheless, these results provide relevant insights for dietary recommendations that could help improve health and related outcomes, according to the authors. “Replacement of 5% energy from animal fat with 5% energy from plant fat, particularly fat from grains or vegetable oils, was associated with a lower risk for mortality: 4%-24% reduction in overall mortality and 5%-30% reduction in cardiovascular disease mortality.”
 

Fat Composition Matters

Animal fat, however, should not simply be replaced with plant fat, said Dr. Lorkowski. “Cold-water fish, which provides important long-chain omega-3 fatty acids, is also considered animal fat. And palm and coconut fat, while plant-based, contain unhealthy long-chain saturated fats. And the type of plant oils also makes a difference, whether one uses corn germ or sunflower oil rich in omega-6 fatty acids or flaxseed or rapeseed oil rich in omega-3 fatty acids.

“A diet rich in unsaturated fats, with sufficient and balanced intake of omega-3 and omega-6 fatty acids, that is also abundant in fiber-rich carbohydrate sources and plant-based protein, is always better than too much fat from animal sources.”

This story was translated from the Medscape German edition 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.