Skin Rejuvenation: How Young Blood and Bone Marrow Influence It

Heterochronic parabiosis studies illuminated the potential for rejuvenation through blood-borne factors, yet the specific drivers including underlying mechanisms remain largely unknown and until today insights have not been successfully translated to humans.

A new study published as the cover of Aging (Aging-US) Volume 17, Issue 7, explores how factors in young human blood may affect the biological age of human skin. Researchers from Beiersdorf AG, Research and Development Hamburg in Germany, used a microphysiological co-culture system—a lab-based model simulating human circulation—to test the effects of young versus old blood serum on skin cells. The findings suggest that bone marrow-derived cells play a key role in converting blood-borne signals into effects that support skin rejuvenation.

Understanding Skin Aging and Systemic Influence

As we age, the skin’s ability to regenerate declines, while its biological age increases. This contributes to visible signs of aging and a weakened barrier function. While cosmetic treatments can improve appearance, they rarely target the cellular processes underlying skin aging.

Animal studies have shown that exposure to young blood can promote tissue repair and rejuvenation, likely due to molecules circulating in the bloodstream. However, reproducing these effects in human skin has proven difficult. Applying young serum directly to skin tissue has not produced significant results, indicating that additional cellular interactions may be required.

The Study: A Two-Step Regenerative Protocol

The research team, led by first author Johanna Ritter and corresponding author Elke Grönniger from Beiersdorf AG, developed an innovative in vitro system combining two engineered human tissue models: full-thickness skin and bone marrow. Using the HUMIMIC Chip3plus platform, they created a miniature circulatory system where these tissues could interact through shared culture media.

The study, titled “Systemic factors in young human serum influence in vitro responses of human skin and bone marrow-derived blood cells in a microphysiological co-culture system,” investigated how human serum from young (<30 years) and older (>60 years) donors influenced markers of skin aging over a 21-day period.

Results: Rejuvenation Dependent on Bone Marrow Interaction

The researchers observed that young serum alone had no effect on skin aging markers in either static or dynamic skin-only cultures. However, when skin tissue was co-cultured with bone marrow-derived cells, significant changes occurred.

Skin in the combined system treated with young serum showed increased cell proliferation, indicating improved regenerative potential, and a reduction in biological age as measured by DNA methylation clocks. Bone marrow cells also exhibited improved mitochondrial function and changes in cell composition, particularly an increase in early progenitor cells.

These findings suggest that bone marrow-derived cells respond to young serum by producing signaling proteins that influence skin behavior. Without these intermediary cells, the rejuvenating effects were not observed.

Further proteomic analysis identified 55 proteins that were differentially expressed in bone marrow cells exposed to young versus old serum. Of these, seven proteins were tested individually on aged skin cells. Several—including CHI3L1, CD55, and MMP-9—improved markers related to skin aging, such as collagen production, mitochondrial activity, and cellular plasticity.

The Impact: Identification of Key Rejuvenating Proteins

This discovery highlights specific proteins that may serve as future targets in skin regeneration research. While the results are promising, they were obtained in controlled lab conditions. These findings are not yet applicable to clinical treatments but offer a potential foundation for developing non-invasive skin therapies that mimic the effects of youthful blood composition.

Future Perspectives and Conclusion

The study underscores the importance of systemic and inter-organ communication in skin aging. By incorporating bone marrow-derived cells into the experimental model, the researchers created a more physiologically accurate system to study how circulating factors influence tissue aging.

Although the evidence supports the idea that bone marrow cells mediate the effects of young serum on skin, additional research is needed. Future studies using aged skin models, extended time frames, and clinical validation will be essential to explore therapeutic possibilities.

As an experimental approach, this research adds valuable knowledge to the biological mechanisms of skin aging and could inform future strategies in regenerative medicine and dermatology.

Click here to read the full research paper published in Aging (Aging-US).

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Aging is indexed by PubMed/Medline (abbreviated as “Aging (Albany NY)”), PubMed CentralWeb of Science: Science Citation Index Expanded (abbreviated as “Aging‐US” and listed in the Cell Biology and Geriatrics & Gerontology categories), Scopus (abbreviated as “Aging” and listed in the Cell Biology and Aging categories), Biological Abstracts, BIOSIS Previews, EMBASE, META (Chan Zuckerberg Initiative) (2018-2022), and Dimensions (Digital Science).

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Stem Cell Regenera: A Regenerative Approach to Activating Dormant Ovarian Follicles

“Women with conditions such as Poor Ovarian Response (POR) and Diminished Ovarian Reserve (DOR) face significant challenges in assisted reproduction.”

A new study published recently in Aging (Aging-US) Volume 17, Issue 6, examines a novel treatment for women with ovarian failure. Researchers from IVI Clinics Alicante in Spain investigated a procedure called Stem Cell Regenera, which uses the body’s own stem cells and platelet-rich plasma to activate dormant follicles in the ovaries. This innovative protocol could expand options for patients with ovarian failure who have not responded to conventional fertility therapies.

Understanding Ovarian Failure

Ovarian failure affects women’s ability to conceive by reducing the quantity and quality of eggs in the ovaries. Conditions like Poor Ovarian Response, Diminished Ovarian Reserve, and Premature Ovarian Insufficiency are key reasons for infertility and make it hard to use assisted reproduction methods like in vitro fertilization (IVF).

Standard fertility treatments often fail to improve outcomes for these patients, leaving donor eggs as the primary alternative. However, recent advances in regenerative medicine have raised the possibility of restoring ovarian function using cellular therapies. Emerging research suggests that the right biological conditions could reactivate dormant follicles within the ovaries, potentially helping patients to use their eggs.

The Study: A Two-Step Regenerative Protocol

Led by first author Amparo Santamaria and co-authors Ana Ballester and Manuel Muñoz, the study titled “Enhancing oocyte activation in women with ovarian failure: clinical outcomes of the Stem Cell Regenera study using G-CSF mobilization of peripheral blood stem cells and intraovarian injection of stem cell factor-enriched platelet rich plasma in real-world-practice,” examined the effectiveness of Stem Cell Regenera in a real-world clinical setting. The protocol combined two key steps. First, patients received granulocyte colony-stimulating factor (G-CSF), a substance that mobilizes hematopoietic stem cells from the bone marrow into the bloodstream. Second, clinicians performed an ultrasound-guided injection of platelet-rich plasma, enriched with stem cell growth factors, directly into the ovaries.

The retrospective observational study carried out from January 2023 to December 2024 analyzed data from 145 women aged 26 to 44 years who had previously exhausted conventional fertility options. Researchers evaluated whether this procedure could stimulate ovarian activity and improve pregnancy outcomes.

Results: Activation of Ovarian Function

The study found that nearly 70% of participants demonstrated ovarian activation, defined as either an increase in developing follicles or a rise in Anti-Müllerian Hormone levels. Among these women, approximately 7% achieved spontaneous pregnancies without further intervention, while 14% became pregnant following IVF treatment.

Importantly, the procedure was well tolerated. No severe adverse effects were reported, and most participants experienced only mild and transient symptoms such as headaches or fatigue. The use of the patient’s own cells minimized the risk of immune reactions and contributed to the overall safety profile.

The Impact: Expanding Fertility Options

The Stem Cell Regenera protocol represents a promising development in reproductive medicine by offering an alternative for women with ovarian failure who prefer to use their own eggs rather than donor eggs. Unlike traditional hormonal therapies, this approach focuses on rejuvenating the ovarian environment itself, which may enable natural follicular development.

While the findings are encouraging, the researchers caution that the study was observational in design and lacked a control group. These factors limit the ability to draw definitive conclusions about efficacy.

Future Perspectives and Conclusion

Stem Cell Regenera adds to a growing body of evidence supporting regenerative therapies in fertility care. However, large randomized controlled trials are needed to confirm its effectiveness, identify the patient populations most likely to benefit, and assess long-term outcomes.

As an experimental approach, it may be considered in select cases where conventional therapies have failed. To learn more about this research, readers can watch an interview with the study’s lead author, Dr. Amparo Santamaria, here.

Click here to read the full research paper published in Aging (Aging-US).

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Aging is indexed by PubMed/Medline (abbreviated as “Aging (Albany NY)”), PubMed CentralWeb of Science: Science Citation Index Expanded (abbreviated as “Aging‐US” and listed in the Cell Biology and Geriatrics & Gerontology categories), Scopus (abbreviated as “Aging” and listed in the Cell Biology and Aging categories), Biological Abstracts, BIOSIS Previews, EMBASE, META (Chan Zuckerberg Initiative) (2018-2022), and Dimensions (Digital Science).

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Now Accepting Submissions: Special Collection on Cognitive Aging

In this special collection, Aging seeks to bring together cutting-edge research that spans the cellular and molecular underpinnings of cognitive aging with insights into the psychosocial, behavioral, and environmental factors that modulate its course.

BUFFALO, NY — July 8, 2025 — As populations worldwide continue to age, understanding the mechanisms and manifestations of cognitive aging is increasingly urgent for science, medicine, and society. Age-related cognitive decline ranges from mild memory lapses to the onset of dementia, and is shaped by a complex interplay of molecular, cellular, systemic, and social determinants.

In this special collection, Aging (Aging-US) seeks to bring together cutting-edge research that spans the cellular and molecular underpinnings of cognitive aging with insights into the psychosocial, behavioral, and environmental factors that modulate its course. By integrating basic biology with translational and societal dimensions, this collection aims to foster a holistic understanding of how and why cognitive function changes with age—and what can be done to preserve it.

We welcome original research articles, reviews, and perspectives across model systems and human studies, particularly those that promote interdisciplinary insights and translational potential.

POTENTIAL TOPICS

Molecular and Cellular Mechanisms

  • Senescence, inflammation, and neurodegeneration in cognitive decline
  • Mitochondrial dysfunction and oxidative stress in aging neurons
  • Neurovascular aging and blood-brain barrier integrity
  • Single-cell and spatial transcriptomics of the aging brain
  • mTOR, autophagy, and proteostasis in age-related cognitive impairment
  • The role of glial cells (microglia, astrocytes) in brain aging

 Genetics and Biomarkers

  • Genetic risk factors and epigenetic modifications associated with cognitive aging
  • Biomarkers of cognitive resilience and vulnerability
  • Neuroimaging and fluid-based biomarkers in aging populations

Interventions and Lifestyle Factors

  • Cognitive benefits of caloric restriction, exercise, or senolytic therapies
  • Preclinical and clinical trials targeting aging pathways to prevent cognitive decline
  • Impact of sleep, nutrition, and metabolic health on cognition in older adults
  • Use of cognitive strategies and compensatory techniques to maintain or enhance function in aging

Environmental and Social Contexts

  • Impact of social isolation, education, and socioeconomic status on cognitive trajectories
  • Lifelong cognitive reserve and its determinants
  • Cross-cultural and demographic studies on aging and cognition
  • Digital health tools for monitoring or enhancing cognitive function in the elderly

SUBMISSION DETAILS:

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To learn more about the journal, please visit our website at www.Aging-US.com​​ and connect with us on social media at:

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DoliClock: A Lipid-Based Clock for Measuring Brain Aging

Aging is a multifaceted process influenced by intrinsic and extrinsic factors, with lipid alterations playing a critical role in brain aging and neurological disorders.”

A new study published recently as the cover of Aging Volume 17, Issue 6, describes a new method to estimate how fast the brain is aging. By analyzing lipids, or fat molecules, in brain tissue, researchers from the National University of Singapore and Hanze University of Applied Sciences created a biological “clock” called DoliClock. This innovation highlights how conditions such as autism, schizophrenia, and Down syndrome are associated with accelerated brain aging.

Understanding Brain Aging

As people grow older, their brains naturally change. However, in many neurological disorders, these changes seem to appear earlier and progress more rapidly. Disorders like autism, schizophrenia, and Down syndrome reduce quality of life and contribute to premature death. Scientists have long searched for better ways to measure biological age in the brain to understand these processes and develop strategies to slow them down.

Most existing methods for estimating biological age rely on genetic markers, such as DNA methylation, which are chemical modifications of DNA. While useful, these approaches may not fully capture the complexity of aging, especially in the brain. Lipids, which are essential components of brain cells and play important roles in energy storage and signaling, offer another perspective.

The Study: Building a Lipid-Based Aging Clock

A team led by first author Djakim Latumalea and corresponding author Brian K. Kennedy introduced DoliClock, a model that predicts brain age using lipid profiles from the prefrontal cortex. This region of the brain, located just behind the forehead, plays a key role in decision-making, memory, and emotional regulation.

The study titled “DoliClock: a lipid-based aging clock reveals accelerated aging in neurological disorders” analyzed post-mortem brain samples from individuals with and without neurological conditions such as autism, schizophrenia, and Down syndrome.

The researchers focused on a class of lipids called dolichols, which are involved in vital cellular processes such as protein transport and glycosylation. These lipids tend to accumulate in brain tissue as people age, making them promising markers for measuring biological aging.

Results: Lipids Reflect the Pace of Aging

The DoliClock model showed that dolichol levels in the brain increased gradually with age. This change became particularly noticeable around the age of 40, suggesting a shift in how the brain regulates lipid metabolism during midlife. In addition to dolichols, the researchers observed an increase in entropy, a measure of disorder in lipid composition, which also intensified around this age.

When applied to brain samples from individuals with neurological disorders, DoliClock revealed significant differences. Samples from people with autism, schizophrenia, and Down syndrome showed higher predicted biological ages compared to their actual ages. This finding indicates that these disorders are associated with accelerated brain aging. The results align with previous studies using other biological clocks but add a new layer of understanding by focusing on lipid metabolism.

The Impact: A New Window into Brain Aging

DoliClock represents an important step in aging research because it demonstrates how lipid profiles can serve as markers of biological age. Unlike genetic markers, which may not fully capture brain-specific changes, lipidomic data directly reflect the brain’s structure and metabolic state. Dolichols, in particular, emerged as strong indicators of aging and may also play a role in the development of neurological disorders. This lipid-based clock could help scientists better understand the brain aging process and identify individuals at risk of premature decline.

Future Perspectives and Conclusion

DoliClock opens new possibilities for studying the molecular basis of brain aging. Although the current study used post-mortem brain tissue, future research could adapt this approach for use with more accessible samples. Similar lipid signatures might eventually be detectable in blood or cerebrospinal fluid, offering a non-invasive way to monitor brain health. Such tools could support early diagnosis and help track the effectiveness of treatments designed to slow brain aging.

Investigating how interventions such as dietary changes or medications affect lipid-based aging markers could also lead to new strategies for promoting healthy brain aging, making DoliClock a promising foundation for further exploration in aging research and brain health.

Click here to read the full research paper published in Aging.

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Aging is indexed by PubMed/Medline (abbreviated as “Aging (Albany NY)”), PubMed CentralWeb of Science: Science Citation Index Expanded (abbreviated as “Aging‐US” and listed in the Cell Biology and Geriatrics & Gerontology categories), Scopus (abbreviated as “Aging” and listed in the Cell Biology and Aging categories), Biological Abstracts, BIOSIS Previews, EMBASE, META (Chan Zuckerberg Initiative) (2018-2022), and Dimensions (Digital Science).

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Oxygen Deprivation and the Aging Brain: A Hidden Trigger for Cognitive Decline

“As advanced age is associated with increased incidence of hypoxia-associated conditions such as asthma, emphysema, ischemic heart disease, heart failure, and apnea, our findings have important implications for many people.”

As we age, our brains become more sensitive to stress and disease. A recent study sheds light on a lesser-known risk: reduced oxygen levels. The study, titled Defining the hypoxic thresholds that trigger blood-brain barrier disruption: the effect of age and recently published as the cover for Volume 17, Issue 5 of Aging (Aging-US), found that low oxygen—also called hypoxia—can harm the aging brain by disrupting the blood-brain barrier (BBB). This damage may contribute to cognitive decline, memory problems, and an increased risk of dementia.

Understanding Hypoxia in the Brain

The brain relies on a steady supply of oxygen to stay healthy. When oxygen levels fall—a condition known as hypoxia—the brain undergoes changes to adapt. These changes include the remodeling of blood vessels and, importantly, a weakening of the blood-brain barrier. The BBB acts as a filter, protecting brain tissue from harmful substances. When it breaks down, it can lead to inflammation, brain cell damage, and cognitive issues.

Hypoxia is common in older adults, especially those with conditions like sleep apnea, chronic obstructive pulmonary disease (COPD), heart failure, and asthma. That is why understanding the connection between low oxygen and the aging brain is crucial for preventing long-term neurological damage.

The Study: Exploring Brain Vulnerability to Hypoxia

To investigate how age affects the brain’s response to low oxygen, researchers at the San Diego Biomedical Research Institute studied young and old mice. They exposed the mice to different levels of oxygen—from normal (21%) down to 8%—to see at what point the BBB  begins to fail. The study by Arjun Sapkota, Sebok K. Halder, Richard Milner, also tracked how sensitivity to hypoxia changes across the lifespan, examining mice from 2 to 23 months old.

The Results: Low Oxygen Damages the Blood-Brain Barrier in Older Brains

The results showed that older mice experienced blood-brain barrier disruption at higher oxygen levels—around 15%—compared to younger mice, which only showed damage at more severe hypoxia (13%). The damage in aged mice was also more severe: their BBB was four to six times leakier than in young mice under the same conditions.

Interestingly, the increased brain vulnerability began earlier than expected. Mice showed greater sensitivity to hypoxia between the ages of 2 and 6 months and again between 12 and 15 months. Additionally, microglia—immune cells in the brain—were more reactive in older mice, even at mild oxygen reductions. This suggests that as we age, the brain becomes not only more sensitive to hypoxia but also more prone to inflammation.

The Breakthrough: Understanding the Link Between Hypoxia and Cognitive Decline

This study is the first to clearly define how the threshold for oxygen-related brain damage changes with age. In simple terms, oxygen levels that are safe for young individuals can harm older adults. This discovery helps explain why conditions like sleep apnea, which reduce oxygen during sleep, are linked to higher dementia risk in older populations.

The Impact: A New Approach to Brain Health in Aging Populations

For older adults, keeping oxygen levels within a healthy range could be essential to protecting brain function. The study also has practical implications for people traveling to high altitudes. Oxygen levels similar to 15%, which were enough to cause BBB damage in aged mice, are found at elevations around 8,600 feet.

These findings highlight the importance of monitoring oxygen exposure, especially for those with chronic illnesses. Strategies to strengthen the blood-brain barrier may help reduce the risk of hypoxia-induced cognitive decline in aging individuals.

Future Perspectives and Conclusion

The aging brain is more vulnerable to low oxygen than previously believed. Even mild reductions in oxygen can lead to blood-brain barrier disruption, brain inflammation, and cognitive problems. This study offers valuable insights that can help guide future treatments aimed at protecting the brain in older adults.

For anyone living with respiratory or heart conditions, this research delivers an important message. Preventing hypoxia is just as crucial as treating illness. Monitoring and managing oxygen levels may not only extend lifespan but also help ensure better brain health and quality of life as we age.

Click here to read the full research paper in Aging.

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Aging is indexed by PubMed/Medline (abbreviated as “Aging (Albany NY)”), PubMed CentralWeb of Science: Science Citation Index Expanded (abbreviated as “Aging‐US” and listed in the Cell Biology and Geriatrics & Gerontology categories), Scopus (abbreviated as “Aging” and listed in the Cell Biology and Aging categories), Biological Abstracts, BIOSIS Previews, EMBASE, META (Chan Zuckerberg Initiative) (2018-2022), and Dimensions (Digital Science).

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Study Identifies Foods That May Reverse Biological Age and Promote Healthy Aging in Men

“At the end of the trial, the intervention group was, on average, 2.04 years younger than their baseline epigenetic age (p = 0.043).”

In a world where we are living longer but not always healthier, scientists are searching for ways to add life to our years, not just years to our lives. A recent study published in Aging (Aging-US), Volume 17, Issue 4, led by researchers at the National University of Natural Medicine, suggests that certain common foods, already known for their health benefits, might also help slow or even reverse epigenetic or biological aging. These foods, rich in specific plant compounds, appear to influence our DNA in ways that may slow down the body’s epigenetic clock.

Understanding Epigenetic Aging

While chronological age is simply the number of years we have lived, epigenetic or biological age reflects how fast our bodies are aging at the cellular level. This process is measured by patterns in DNA methylation—chemical changes that can alter gene activity without changing the DNA sequence itself. Over time, shifts in DNA methylation are linked to increased risks for conditions like cancer, heart disease, and dementia. Because lifestyle factors such as diet can influence DNA methylation, researchers are exploring whether healthy eating might actually help us age more slowly.

The Study: How Food Might Influence Epigenetic Aging

In an earlier trial called the Methylation Diet and Lifestyle study, 43 healthy men between the ages of 50 and 72 followed a comprehensive eight-week program involving diet, sleep, exercise, and meditation. Participants in the intervention group became, on average, more than two years “younger” in terms of their epigenetic age. The dietary component of the program emphasized whole, plant-based foods, lean meats, and a group of foods classified as “methyl adaptogens.”

In a follow-up study titled “Dietary associations with reduced epigenetic age: a secondary data analysis of the methylation diet and lifestyle study,” a research team led by Jamie L. Villanueva from the University of Washington and the National University of Natural Medicine, along with Ryan Bradley also from the National University of Natural Medicine and the University of California, San Diego, analyzed participants’ self-reported diets to understand why some experienced greater biological age reversal than others.

The Results:  A Diet That May Slow Epigenetic Aging

The study found that men who consumed more methyl adaptogen foods—such as green tea, turmeric, garlic, berries, rosemary, and oolong tea—showed the most substantial reductions in epigenetic age, up to 8 years. These associations remained strong even after accounting for weight loss, suggesting that the foods themselves played a central role in the observed biological changes.

Methyl adaptogens are rich in polyphenols, plant compounds known to influence DNA methylation by regulating enzymes that control gene expression. These polyphenols interact with cellular systems involved in DNA repair, inflammation, and metabolism—all key players in the aging process. Compounds like EGCG in green tea, curcumin in turmeric, and allicin in garlic are also known to influence the PI3K/AKT/mTOR pathway, a major regulator of cell survival and aging. 

The Impact: A Natural Way to Care for Our Health

These findings support the idea that food can be a powerful tool for promoting healthier aging. Unlike drugs or supplements, this approach is natural, non-invasive, and based on foods that are already accessible to many. The findings could lead the way for personalized nutrition strategies that go beyond disease prevention, aiming to influence the very pace of aging.

Future Perspectives and Conclusion

Although the study was relatively small and limited to middle-aged men, the results are promising. Larger, more diverse studies are needed to confirm these findings and assess their broader applicability, including for women and other age groups. The researchers also note that additional tools for measuring aging more accurately would be valuable in future investigations.

Nevertheless, this research provides a positive reminder: our daily choices, particularly the foods we consume, can significantly influence our aging process. Including foods such as green tea, garlic, berries, and turmeric in our diets may not only promote better health but also slow down the aging process.

Click here to read the full research paper in Aging.

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Aging is indexed by PubMed/Medline (abbreviated as “Aging (Albany NY)”), PubMed CentralWeb of Science: Science Citation Index Expanded (abbreviated as “Aging‐US” and listed in the Cell Biology and Geriatrics & Gerontology categories), Scopus (abbreviated as “Aging” and listed in the Cell Biology and Aging categories), Biological Abstracts, BIOSIS Previews, EMBASE, META (Chan Zuckerberg Initiative) (2018-2022), and Dimensions (Digital Science).

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Fighting Premature Aging: How NAD+ Could Help Treat Werner Syndrome

“Werner syndrome (WS), caused by mutations in the RecQ helicase WERNER (WRN) gene, is a classical accelerated aging disease with patients suffering from several metabolic dysfunctions without a cure.”

Werner syndrome is a rare condition marked by accelerated aging. A recent study, featured as the cover paper in Aging (Aging-US), Volume 17, Issue 4, led by researchers at the University of Oslo and international collaborators, suggests that nicotinamide adenine dinucleotide (NAD+), a vital molecule involved in cellular energy production, may be key to understanding this disease and developing future strategies to manage it.

Understanding Werner Syndrome

Werner syndrome (WS) is a rare genetic condition that causes people to age more quickly than normal. By their 20s or 30s, individuals with WS often show signs typically associated with older age, such as cataracts, hair loss, thinning skin, and heart disease. This premature aging is caused by mutations in the WRN gene, which normally helps repair DNA and protect cells from damage. While the WRN gene’s role in maintaining genetic stability is well understood, the reasons behind the rapid decline of cells in WS patients are still not fully clear.

The Study: Investigating NAD+ in Werner Syndrome

Nicotinamide adenine dinucleotide levels naturally decline with age. In the study titled Decreased mitochondrial NAD+ in WRN deficient cells links to dysfunctional proliferation,” researchers investigated whether this decline is more severe in people with WS and whether restoring NAD+ levels could help slow the aging process in these patients.

The research team, led by first author Sofie Lautrup and corresponding author Evandro F. Fang, used human stem and skin cells from WS patients, as well as gene-edited cells that mimic WS by lacking the WRN gene. These were always compared to control cells isolated from healthy individuals.

The researchers tracked how WRN deficiency affected NAD+ levels in mitochondria, the parts of the cell that generate energy. They then tested whether boosting NAD+ using a compound called nicotinamide riboside (NR)—a form of vitamin B3—could help restore normal cellular function. The team also used other strategies to raise mitochondrial NAD+ directly, including overexpressing a transporter protein known as SLC25A51. Their goal was to determine whether these approaches could reverse aging-related damage and restore cell growth affected by WRN mutations.

The Results: NAD+ Can Reduce Aging Signs

The findings confirmed that WRN-deficient cells had lower levels of mitochondrial NAD+ and showed signs of cellular aging, such as increased senescence and reduced proliferation. Treating these cells with NR significantly reduced aging markers and restored some normal functions in both stem and skin cells from WS patients. In healthy control cells, NR had no such effect, suggesting it works specifically in the context of NAD+ deficiency.

However, increasing NAD+ either through NR supplementation or by enhancing mitochondrial transport was not enough to fully restore cell division in lab-grown cells lacking WRN. This result suggests that while NAD+ supplementation is beneficial, the WRN gene itself plays a unique and irreplaceable role in supporting healthy cell growth.

The Breakthrough: Linking Mitochondrial NAD+ to Cell Aging

This study reveals a deeper role for the WRN gene beyond DNA repair. It shows that WRN also helps regulate how NAD+ is produced and used within cells, particularly in mitochondria. Without WRN, this system becomes unbalanced, accelerating cell aging. While boosting NAD+ helped reduce aging features in WS cells, the findings make clear that NAD+ therapy alone cannot replace the broader functions of WRN.

The Impact: A Step Toward Slowing Down Cellular Aging

This is the first study to directly show how low mitochondrial NAD+ contributes to premature aging in WS. Beyond its relevance to WS, the research highlights the broader potential of targeting NAD+ metabolism as a strategy for addressing age-related diseases. By increasing our understanding of how energy production affects aging, this study opens the door to future treatments aimed at promoting healthier aging across a wider population.

Future Perspectives and Conclusion

This study offers promising new insights but also demonstrates the complexity of cellular aging. The WRN gene plays a much broader role than DNA repair alone. It appears to regulate networks of genes linked to metabolism and genome organization. While boosting NAD+ can reduce some signs of cellular damage, it cannot fully compensate for the loss of WRN function.

Looking ahead, further research will be crucial to understanding how NAD+ operates in different parts of the cell and how it might work in combination with other treatments. For individuals with Werner syndrome, and potentially for the wider aging population, these findings bring us closer to future therapies aimed at improving health and longevity. 

Click here to read the full research paper in Aging.

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Aging is indexed by PubMed/Medline (abbreviated as “Aging (Albany NY)”), PubMed CentralWeb of Science: Science Citation Index Expanded (abbreviated as “Aging‐US” and listed in the Cell Biology and Geriatrics & Gerontology categories), Scopus (abbreviated as “Aging” and listed in the Cell Biology and Aging categories), Biological Abstracts, BIOSIS Previews, EMBASE, META (Chan Zuckerberg Initiative) (2018-2022), and Dimensions (Digital Science).

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Breast Cancer Treatment’s Hidden Impact: Accelerated Aging Among Survivors

“Breast cancer (BC) is the most commonly diagnosed cancer among women in the US and worldwide .”

Breast cancer survivors are living longer than ever, thanks to research and medical advances, but new studies suggest that some treatments may come with a hidden cost: accelerated aging. A recent study, titled “Accelerated aging associated with cancer characteristics and treatments among breast cancer survivors,” published in Aging (Aging-US), reveals that breast cancer and its treatments may speed up biological aging, with effects lasting up to a decade post-diagnosis.

Breast Cancer and Aging

Breast cancer is one of the most common cancers among women worldwide. Medical advancements have dramatically improved survival rates, making it one of the most treatable forms of cancer. Yet, many survivors report lasting symptoms like fatigue, memory issues, and reduced vitality that resemble accelerated aging. This pattern has led scientists to investigate whether treatments for breast cancer might be contributing to biological age acceleration.

The Study: Measuring Long-Term Aging in Breast Cancer Patients

Researchers at Vanderbilt University conducted a decade-long study involving 1,264 breast cancer patients and 429 cancer-free women. The research team, led by first author Cong Wang and corresponding author Xiao-Ou Shu, used a tool called Phenotypic Age Acceleration (PAA), which estimates biological age using standard blood test data. Unlike chronological age, biological age reveals how “old” the body functions, offering a clearer picture of a person’s overall health and aging rate. 

The Results: Long-Term Effects of Breast Cancer Treatments on Aging

At diagnosis, breast cancer patients already appeared nearly four years older biologically than their cancer-free counterparts. One year after treatment, they still seemed two years older. Even ten years later, signs of accelerated aging remained.

When it comes to treatments, not all had the same long-term impact on aging. Chemotherapy was linked to the most immediate spike in aging markers, with effects most noticeable in the first year. In contrast, endocrine therapy showed slower, long-term effects, becoming more apparent many years later. Surgery and radiation therapy were associated with lower levels of age acceleration over time, suggesting that localized treatments may carry fewer long-term aging effects than systemic therapies.

Tumor characteristics also influenced aging levels. Women diagnosed with advanced-stage cancer (Stage III or IV) or those with high-grade tumors experienced the most pronounced biological aging. These findings suggest that both the disease itself and the intensity of treatment contribute to how quickly a survivor may age.

The Breakthrough: Simple Blood Tests to Monitor Aging in Breast Cancer Survivors

This study provides valuable insight into how breast cancer and its treatments can impact survivors’ long-term health. One of its most important contributions is highlighting a simple, accessible way to track biological aging, the PAA test. This method is cost-effective, easy to use in regular medical care, and gives clinicians a powerful tool to identify high-risk patients and tailor long-term follow-up strategies.

The Impact: Rethinking Long-Term Breast Cancer Care

The paper offers valuable insights that could reshape how clinicians think about survivorship care. Breast cancer survivors already face increased risks for heart disease, osteoporosis, and cognitive decline. Accelerated aging may be a contributing factor. By identifying these effects early, healthcare providers can develop more personalized support strategies, potentially improving quality of life and long-term health outcomes.

Future Perspectives and Conclusion

The journey does not end with breast cancer remission. This study underscores that cancer and its treatments can leave lasting effects on the body’s aging process. Implementing appropriate strategies—whether medical, lifestyle-based, or a combination of both—may help survivors not only extend their lifespan but also increase their long-term health and quality of life.

Integrating biological age monitoring into routine follow-up care could enable healthcare providers to better understand each survivor’s health trajectory. For all the women navigating life after breast cancer, such information could translate into not just more years, but better years.

Click here to read the full research paper in Aging.

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Aging is indexed by PubMed/Medline (abbreviated as “Aging (Albany NY)”), PubMed CentralWeb of Science: Science Citation Index Expanded (abbreviated as “Aging‐US” and listed in the Cell Biology and Geriatrics & Gerontology categories), Scopus (abbreviated as “Aging” and listed in the Cell Biology and Aging categories), Biological Abstracts, BIOSIS Previews, EMBASE, META (Chan Zuckerberg Initiative) (2018-2022), and Dimensions (Digital Science).

Click here to subscribe to Aging publication updates.

For media inquiries, please contact [email protected].

Call for Papers: Special Collection Honoring Dr. Mikhail (Misha) Blagosklonny

Dr. Mikhail Blagosklonny
Dr. Mikhail Blagosklonny

“This special collection will explore key themes central to Dr. Blagosklonny’s scientific contributions, with a focus on mechanistic insights, translational approaches, and theoretical perspectives.”

BUFFALO, NY — April 3, 2025 — Aging (Aging-US) is pleased to announce a special Call for Papers for a commemorative collection honoring the legacy of Dr. Mikhail (Misha) Blagosklonny, the founding editor of the journal and a pioneer in aging biology. His groundbreaking work shaped fundamental concepts in the field, particularly regarding the role of mTOR in aging and cancer, the use of rapamycin, bypassing senescence during the process of transformation, personalized medicine, and theories on why we age.

This special collection will explore key themes central to Dr. Blagosklonny’s scientific contributions, with a focus on mechanistic insights, translational approaches, and theoretical perspectives. We invite original research, reviews, and perspective articles covering topics such as:

  • The role of mTOR in aging and age-related diseases
  • Rapamycin and other pharmacological strategies to extend lifespan
  • Senescence bypass and its implications for cancer and regenerative medicine
  • Personalized medicine approaches in aging and longevity research
  • Theoretical models and evolutionary perspectives on aging

The special issue will be guest-edited by leading scientist in the field, David Gems, who will oversee the selection of high-quality contributions that reflect the depth and impact of Dr. Blagosklonny’s work.

We encourage researchers working on these topics to submit their manuscripts and contribute to this tribute to one of the most influential figures in aging research.

SUBMISSION DETAILS:

We look forward to your contributions to this special issue and to honoring Dr. Blagosklonny’s enduring impact on the field of aging research.

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Senolytic Compounds Show Promise in Targeted Alzheimer’s Treatments

“Cellular senescence is a hallmark of aging and the age-related condition, Alzheimer’s disease (AD).”

Could a class of drugs that clear aging cells also help treat Alzheimer’s disease? A recent study, featured as the cover for Aging (Volume 17, Issue 3), titled “Differential senolytic inhibition of normal versus Aβ-associated cholinesterases: implications in aging and Alzheimer’s disease,” suggests they might—and with remarkable precision.

Understanding Alzheimer’s Disease

Alzheimer’s disease is a progressive neurological disorder that gradually steals memory, independence, and a person’s sense of identity. A defining feature of Alzheimer’s is the buildup of amyloid-β (Aβ) plaques—sticky protein clumps that interfere with communication between brain cells. This disruption is closely linked to changes in a group of enzymes called cholinesterases, especially acetylcholinesterase (AChE) and butyrylcholinesterase (BChE). These enzymes normally play a vital role in regulating neurotransmitters critical for memory, learning, and cognitive function. In Alzheimer’s, however, their behavior changes significantly, particularly when they interact with Aβ plaques.

The Study: Exploring Senolytics for Alzheimer’s Enzyme Inhibition

A research team from Dalhousie University in Canada looked into whether senolytic compounds—a class of drugs that eliminate damaged, aging cells often referred to as “zombie” cells—could also target the harmful forms of cholinesterase enzymes found in Alzheimer’s disease. Their goal was to see if these compounds could selectively inhibit the disease-associated versions of AChE and BChE, without affecting the healthy forms that are essential for normal brain function.

Led by Dr. Sultan Darvesh, the study tested six compounds: five senolytics—dasatinib, nintedanib, fisetin, quercetin, and GW2580—and one nootropic, meclofenoxate hydrochloride, known for its memory-enhancing potential. The researchers used post-mortem brain tissue from Alzheimer’s patients, enzyme activity assays, and computer modeling to examine how these compounds interact with the enzymes.

The Challenge: Targeting the Right Enzymes

One of the limitations of current Alzheimer’s treatments is that they do not distinguish between the normal and the altered forms of cholinesterases. While these drugs can raise levels of the memory-related chemical acetylcholine and improve cognitive function, they often come with side effects due to their broad activity. A more precise approach—targeting only the versions of AChE and BChE tied to Aβ plaques—could offer better outcomes with fewer drawbacks.

The Results: Senolytics Show Precision in Enzyme Targeting

The results were promising. Some of the senolytics tested, like dasatinib and nintedanib, effectively blocked the cholinesterases attached to Aβ plaques without affecting the normal versions of these enzymes in healthy brain tissue. Meclofenoxate also showed strong activity against the disease-associated forms. Interestingly, this selectivity was linked to how these compounds bind to the enzymes. Instead of locking onto the main active site, many of them attached to alternative regions, known as allosteric sites, which are only altered in the plaque-associated forms. This type of binding allowed the compounds to distinguish between harmful and healthy enzymes.

The Breakthrough: Targeting the Disease, Preserving the Brain

This study is the first to show that certain senolytic and cognitive-enhancing drugs can selectively inhibit the dysfunctional versions of cholinesterases found in Alzheimer’s without affecting their normal forms. This level of precision could mark a major step forward in Alzheimer’s therapy.

The Impact: A Dual-Action Path to Treating Alzheimer’s

By focusing on only the problematic forms of AChE and BChE, this approach could lead to Alzheimer’s treatments that better preserve cognitive function while avoiding side effects. The research also bridges two important areas of study: aging and neurodegeneration. It suggests that drugs developed to slow aging might also be used as targeted treatments for Alzheimer’s, offering a two-in-one therapeutic advantage. 

Future Perspectives and Conclusion

Although more research is needed, especially in living models and clinical trials, the potential of the findings is encouraging. They lead the way for a new generation of Alzheimer’s treatments that are more targeted and safer.

By understanding better how aging and brain disease intersect at the cellular level, scientists may be moving closer to developing more effective and personalized approaches to combat Alzheimer’s.

Click here to read the full research paper in Aging.

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Aging is indexed by PubMed/Medline (abbreviated as “Aging (Albany NY)”), PubMed CentralWeb of Science: Science Citation Index Expanded (abbreviated as “Aging‐US” and listed in the Cell Biology and Geriatrics & Gerontology categories), Scopus (abbreviated as “Aging” and listed in the Cell Biology and Aging categories), Biological Abstracts, BIOSIS Previews, EMBASE, META (Chan Zuckerberg Initiative) (2018-2022), and Dimensions (Digital Science).

Click here to subscribe to Aging publication updates.

For media inquiries, please contact [email protected].

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