Tuesday, January 16, 2024

Stress, via inflammation, is linked to metabolic syndrome

Study suggests stress management could reduce biological risk

OHIO STATE UNIVERSITY

COLUMBUS, Ohio – Lifestyle and genetics, and a range of other factors within and outside our control, are known to contribute to development of metabolic syndrome, a cluster of conditions that add up to increased risk for serious health problems.

A new study has found that stress, through its propensity to drive up inflammation in the body, is also linked to metabolic syndrome – leading researchers to suggest that cheap and relatively easy stress-management techniques may be one way to help improve biological health outcomes.

“We were specifically examining people in midlife – a time that is critical to determine those who will experience accelerated aging. Stress is an important contributor to several negative health outcomes as we age,” said senior author Jasmeet Hayes, associate professor of psychology at The Ohio State University.

“There are many variables that influence metabolic syndrome, some we can’t modify, but others that we can. Everybody experiences stress,” Hayes said. “And stress management is one modifiable factor that’s cost-effective as well as something people can do in their daily lives without having to get medical professionals involved.”

The research was published recently in Brain, Behavior, & Immunity – Health.

Links between stress and biological health are established, but few previous studies had looked specifically at the involvement of inflammation in stress’s connection to metabolic syndrome.

People with metabolic syndrome are diagnosed with at least three of five factors that increase the risk for heart disease, diabetes and other health issues – excess belly fat, high blood pressure, low HDL (good) cholesterol, and high levels of fasting blood glucose and triglycerides, a type of fat in the blood. The condition is also referred to as insulin resistance syndrome.

Using data from a sample of 648 participants (average age 52) in a national survey titled Midlife in the United States, first author Savana Jurgens built a statistical model to gauge how inflammation may fit into the relationship between stress and metabolic syndrome. Information from respondents’ reported perceived stress, blood biomarkers for inflammation, and physical exam results indicating risk factors for metabolic syndrome was used for the analysis.

“There’s not much research that has looked at all three variables at one time,” said Jurgens, a psychology graduate student in Hayes’ lab. “There’s a lot of work that suggests stress is associated with inflammation, inflammation is associated with metabolic syndrome, and stress is associated with metabolic syndrome. But putting all those pieces together is rare.”

Inflammation composite scores were calculated using biomarkers that included the better-known IL-6 and C-reactive protein as well as E-selectin and ICAM-1, which help recruit white blood cells during inflammation, and fibrinogen, a protein essential to blood clot formation.

The statistical modeling showed that stress does indeed have a relationship with metabolic syndrome, and inflammation explained over half of that connection – 61.5%, to be exact.

“There is a small effect of perceived stress on metabolic syndrome, but inflammation explained a large proportion of that,” Jurgens said.

The results made sense – stress is just one of many factors that can launch health markers into a state of disarray. Other factors include a range of behaviors including inactivity, unhealthy eating habits, smoking and poor sleep, as well as low socioeconomic status, advanced age and being female.

But considering that an estimated 1 in 3 American adults has metabolic syndrome, knowing how to lower risk or prevent it altogether is important, Hayes said. The findings also add to evidence that stress, and its connection to inflammation, can have a big impact on biological health in general.

“People think of stress as mental health, that it’s all psychological. It is not. There are real physical effects to having chronic stress,” Hayes said. “It could be inflammation, it could be metabolic syndrome, or a number of things. This is another reminder of that.”

Future work will include a closer look at whether stress has a causal effect on metabolic syndrome and assessing stress management techniques that may be best for helping reduce inflammation.

This research was supported by the National Institute on Aging and Ohio State’s Discovery Themes Chronic Brain Injury Program, where Hayes is an investigator. Co-author Sarah Prieto of Ohio State also contributed to the study.

JOURNAL

Brain Behavior & Immunity - Health

DOI

10.1016/j.bbih.2023.100696

METHOD OF RESEARCH

Data/statistical analysis

SUBJECT OF RESEARCH

People

ARTICLE TITLE

Inflammatory biomarkers link perceived stress with metabolic dysregulation

Kessler Foundation scientist awarded prestigious federal grant for novel, mixed-method study on Latinos with multiple sclerosis

Researcher Cristina A. F. Román, PhD, to examine barriers to healthcare, cardiovascular risk factors, and accelerated brain aging in minoritized group

Grant and Award Announcement

KESSLER FOUNDATION

Cristina A. F. Román, PhD — IMAGE:
CRISTINA A. F. ROMAN, PHD, RESEARCH SCIENTIST IN THE ROCCO ORTENZIO NEUROIMAGING CENTER AT KESSLER FOUNDATION, RECEIVED A FEDERAL GRANT FOR ONE OF THE FIRST MIXED-METHODS STUDIES TO EXAMINE BARRIERS TO HEALTHCARE, MEDICAL COMORBIDITIES, AND ACCELERATED BRAIN AGING IN LATINO PERSONS WITH MULTIPLE SCLEROSIS.
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CREDIT: N/A

East Hanover, NJ – January 12, 2024 – A research scientist at Kessler Foundation has been awarded a highly competitive Mentored Patient-Oriented Research Career Development Award (K23) from the National Institute on Minority Health and Health Disparities, a part of the National Institutes of Health (NIH).

This $704,054, five-year grant will support one of the first mixed-methods studies aimed at examining barriers to healthcare, cardiovascular risk factors, and accelerated brain aging in Latinos with multiple sclerosis (MS). The Principal Investigator and grant recipient, Cristina A. F. Román, PhD, is currently a research scientist in the Foundation’s Rocco Ortenzio Neuroimaging Center.

Though there is a paucity of research focusing on Latinos with MS, there is evidence that this group experiences more severe disease trajectories and worse functional outcomes than their non-Latino counterparts. “These disparities are believed to be strongly influenced by social determinants of health, particularly factors related to healthcare access,” explained Dr. Román, adding, “Timely intervention and consistent, ongoing medical care are crucial for improving MS prognosis, especially in historically minoritized groups that face greater health disparities.”

Studies show that Latinos encounter greater obstacles in accessing equitable healthcare, which not only contributes to poorer MS outcomes, but also increases the risk of comorbid medical conditions such as cardiovascular risk factors. These risk factors disproportionately impact both individuals with MS and Latino populations residing in the United States and can contribute to neurodegeneration (e.g., advanced brain aging). “This means that Latinos with MS are at especially high risk for the compounding effects of barriers to healthcare, cardiovascular risk factors, and MS, yet the extent to which these factors interact to impact MS-related outcomes, especially brain aging, remains unknown,” noted Dr. Román.

“The findings from our work will have direct implications for early intervention strategies, focusing on improving healthcare access and quality. Additionally, our research will significantly contribute to filling a substantial gap in our understanding of how societal and systemic factors (i.e., social determinants of health) influence brain health and health disparities in neurological disorders,” she concluded.

Funding: National Center on Minority Health and Health Disparities (NIH) 1K23MDO19232-01A0.

About the National Institute on Minority Health and Health Disparities (NIMHD)
The National Institute on Minority Health and Health Disparities (NIMHD) is one of the 27 Institutes and Centers of the National Institutes of Health (NIH), the nation's premiere medical research agency. NIMHD's work touches the lives of millions of Americans burdened by disparities in health status and health care delivery, including racial and ethnic minority groups, rural populations, populations with low socioeconomic status, and other population groups. For more information, visit NIMHD.gov.

About Kessler Foundation
Kessler Foundation, a major nonprofit organization in the field of disability, is a global leader in rehabilitation research. Our scientists seek to improve cognition, mobility, and long-term outcomes, including employment, for adults and children with neurological and developmental disabilities of the brain and spinal cord including traumatic brain injury, spinal cord injury, stroke, multiple sclerosis, and autism. Kessler Foundation also leads the nation in funding innovative programs that expand opportunities for employment for people with disabilities. For more information, visit KesslerFoundation.org.

Press Contacts at Kessler Foundation:
Deborah Hauss, DHauss@kesslerfoundation.org
Carolann Murphy, CMurphy@KesslerFoundation.org

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Using chatbots to advance Spanish-speaking patient outreach

Grant and Award Announcement

HUNTSMAN CANCER INSTITUTE

In her latest study, Kim Kaphingst, ScD, director of cancer communication research at Huntsman Cancer Institute and professor of communications at the University of Utah, is using chatbots to reach Spanish-speaking patients and teach them about genetic testing.

The chatbots, computer programs that simulate conversation, give patients the same information they would get in an appointment with a genetic counselor to learn about genetic testing. This is done by using texted prompts, allowing for more flexibility and accessibility since patients can use this tool anywhere. If a patient meets the criteria for genetic testing, they can be offered testing through the genetic counseling team.

And now, Kaphingst and her team have received additional funding from the National Cancer Institute for this specific project. “Our initial trial allowed us to develop and test the chatbot,” says Kaphingst. “This funding allows our team to reach a new population.”

Kaphingst’s background in genetics and health communication has motivated her to find new ways to reach and educate patients. Her team of researchers include Crystal Lumpkins, Whitney Espinel, CGC, Wendy Kohlmann, MS, Guilherme Del Fiol, MD, PhD, FACMI, as well as Pete Taber, MSCI, PhD, from Biomedical Informatics.

“It is important for people to know about their risk of cancer,” says Kaphingst. “As a cancer center, our goal is to effectively communicate this information to the public. There are many things individuals can do to reduce their risk, like early screening or preventative surgery. Our goal is to empower patients, ensuring they have the information necessary to make informed decisions about their health.”

The new phase of this research will focus on Spanish-speaking women. According to Kaphingst, Spanish-speaking women are less likely to receive genetic testing services when compared to English-speaking patients. This means that patients with hereditary cancer risks, like hereditary breast and ovarian cancer, are less likely to be identified, which can lead to poorer health outcomes.

“Our previous work has shown that about 25% to 30% of people who are eligible for genetic testing receive it,” says Kaphingst. “It is so important to address some of the inequities we see in the area we serve. It is really an important issue: making sure that everybody can access the services they need.”

Huntsman Cancer Institute is home to many resources, including a patient navigation program specifically tailored for people who speak Spanish.

The study was supported by the National Institutes of Health/National Cancer Institute including P30 CA042014 and Huntsman Cancer Foundation. The chatbots were developed in a recently completed trial funded by the Inherited Cancer Syndrome Collaborative of the Beau Biden Cancer Moonshot Initiative.

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About Huntsman Cancer Institute at the University of Utah

Huntsman Cancer Institute at the University of Utah (the U) is the National Cancer Institute-designated Comprehensive Cancer Center for Utah, Idaho, Montana, Nevada, and Wyoming. With a legacy of innovative cancer research, groundbreaking discoveries, and world-class patient care, we are transforming the way cancer is understood, prevented, diagnosed, treated, and survived. Huntsman Cancer Institute focuses on delivering a cancer-free frontier to all communities in the area we serve. We have more than 300 open clinical trials and 250 research teams studying cancer at any given time. More genes for inherited cancers have been discovered at Huntsman Cancer Institute than at any other cancer center. Our scientists are world-renowned for understanding how cancer begins and using that knowledge to develop innovative approaches to treat each patient’s unique disease. Huntsman Cancer Institute was founded by Jon M. and Karen Huntsman. 

Study uncovers potential origins of life in ancient hot springs

Peer-Reviewed Publication

NEWCASTLE UNIVERSITY

Newcastle University research turns to ancient hot springs to explore the origins of life on Earth.

The research team, funded by the UK’s Natural Environmental Research Council, investigated how the emergence of the first living systems from inert geological materials happened on the Earth, more than 3.5 billion years ago. Scientists at Newcastle University found that by mixing hydrogen, bicarbonate, and iron-rich magnetite under conditions mimicking relatively mild hydrothermal vent results in the formation of a spectrum of organic molecules, most notably including fatty acids stretching up to 18 carbon atoms in length.

Published in the journal Communications Earth & Environment, their findings potentially reveal how some key molecules needed to produce life are made from inorganic chemicals, which is essential to understanding a key step in how life formed on the Earth billions of years ago. Their results may provide a plausible genesis of the organic molecules that form ancient cell membranes, that were perhaps selectively chosen by early biochemical processes on primordial Earth.

Fatty acids in the early stages of life

Fatty acids are long organic molecules that have regions that both attract and repel water that will automatically form cell-like compartments in water naturally and it is these types of molecules that could have made the first cell membranes. Yet, despite their importance, it was uncertain where these fatty acids came from in the early stages of life. One idea is that they might have formed in the hydrothermal vents where hot water, mixed with hydrogen-rich fluids coming from underwater vents mixed with seawater containing CO2.

The group replicated crucial aspects of the chemical environment found in early Earth's oceans and the mixing of the hot alkaline water from around certain types of hydrothermal vents in their laboratory. They found that when hot hydrogen-rich fluids were mixed with carbon dioxide-rich water in the presence of iron-based minerals that were present on the early Earth it created the types of molecules needed to form primitive cell membranes.

Lead author, Dr Graham Purvis, conducted the study at Newcastle University and is currently a Postdoctoral Research Associate at Durham University.

He said: “Central to life's inception are cellular compartments, crucial for isolating internal chemistry from the external environment. These compartments were instrumental in fostering life-sustaining reactions by concentrating chemicals and facilitating energy production, potentially serving as the cornerstone of life's earliest moments.

The results suggest that the convergence of hydrogen-rich fluids from alkaline hydrothermal vents with bicarbonate-rich waters on iron-based minerals could have precipitated the rudimentary membranes of early cells at the very beginning of life. This process might have engendered a diversity of membrane types, some potentially serving as life's cradle when life first started. Moreover, this transformative process might have contributed to the genesis of specific acids found in the elemental composition of meteorites.”

Principal Investigator Dr Jon Telling, Reader in Biogeochemistry, at School of Natural Environmental Sciences, added:

“We think that this research may provide the first step in how life originated on our planet. Research in our laboratory now continues on determining the second key step; how these organic molecules which are initially ‘stuck’ to the mineral surfaces can lift off to form spherical membrane-bounded cell-like compartments; the first potential ‘protocells’ that went on to form the first cellular life.”

Intriguingly, the researchers also suggest that membrane-creating reactions similar reactions, could still be happening in the oceans under the surfaces of icy moons in our solar system today. This raises the possibility of alternative life origins in these distant worlds.

Reference

Purvis, G., Šiller, L., Crosskey, A. et al. Generation of long-chain fatty acids by hydrogen-driven bicarbonate reduction in ancient alkaline hydrothermal vents. Commun Earth Environ 5, 30 (2024). https://doi.org/10.1038/s43247-023-01196-4

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