Aging-US

Aging-US Podcast
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Aging-US is dedicated to advancing our understanding of the biological mechanisms that drive aging and the development of age-related diseases. Our mission is to serve as a platform for high-quality research that uncovers the cellular, molecular, and systemic processes underlying aging, and translates these insights into strategies to extend healthspan and delay the onset of chronic disease. Read about the Aging-US Scientific Integrity Process: https://aging-us.com/scientific-integrity

  1. P38 MAPK Linked to Epigenetic Activation of Fibrotic Genes in Senescent Lung Fibroblasts

    8 HR AGO

    P38 MAPK Linked to Epigenetic Activation of Fibrotic Genes in Senescent Lung Fibroblasts

    BUFFALO, NY — March 10, 2026 — A new #research paper was #published in Volume 18 of Aging-US on March 3, 2026, titled “P38 MAPK is involved in epigenetic regulation of fibrotic genes in replication induced senescence in lung fibroblasts.” Led by Shan Zhu — with corresponding author Yan Y Sanders from the Department of Biomedical and Translational Sciences, Eastern Virginia Medical School (Macon & Joan Brock Virginia Health Sciences at Old Dominion University) — the study examines how the stress-activated kinase p38 MAPK contributes to persistent profibrotic gene expression in replicative (passage-driven) senescence of human lung fibroblasts and in primary fibroblasts from patients with idiopathic pulmonary fibrosis (IPF). Using IMR90 lung fibroblasts at low and high population-doubling levels and primary IPF fibroblasts, the authors show that TGF-β1 upregulates profibrotic genes (α-SMA and Col3A1) in both young and near-senescent cells, but that high-PDL (near-senescent/senescent) fibroblasts exhibit a delayed but sustained p38 MAPK response to TGF-β1. Pharmacological inhibition of p38 MAPK (SB202190) blunted profibrotic transcription and reduced H4K16 acetylation (H4K16ac) enrichment at α-SMA and Col3A1 promoters, indicating an epigenetic mechanism linking p38 signaling to fibrotic gene activation. “These findings suggest that a p38 MAPK–dependent epigenetic mechanism is involved in fibroblast activation, supporting the therapeutic potential of p38 MAPK inhibition for treating age-related fibrotic diseases such as IPF.” The authors place these molecular results in a clinical context: persistent fibroblast activation and senescence are features of IPF and other age-associated fibrotic disorders, and the data here support targeting p38 MAPK to interrupt an epigenetically reinforced profibrotic program. The study used multiple readouts (western blot, RT-qPCR, ChIP for H4K16ac) and included primary IPF cells to strengthen translational relevance, while also noting that further work is required to test safety and efficacy in vivo. The paper outlines clear next steps: determine the upstream triggers that sustain p38 signaling in near-senescent fibroblasts, map the chromatin-level events downstream of p38 that maintain H4K16ac at profibrotic promoters, and evaluate p38 inhibition in animal models of age-related pulmonary fibrosis. The authors also recommend exploring whether epigenetic modulators that reverse H4K16ac enrichment can synergize with kinase inhibition to restore repair capacity without impairing normal tissue healing. DOI - https://doi.org/10.18632/aging.206357 Corresponding author - Yan Y Sanders - sandery@odu.edu Abstract video - https://www.youtube.com/watch?v=yP0CwWMUhnY Sign up for free Altmetric alerts about this article - https://aging.altmetric.com/details/email_updates?id=10.18632%2Faging.206357 Subscribe for free publication alerts from Aging - https://www.aging-us.com/subscribe-to-toc-alerts Keywords - aging, senescence, fibroblast activation, p38 MAPK, lung fibrosis, H4K16Ac To learn more about the journal, please visit https://www.Aging-US.com​​ and connect with us on social media at: Bluesky - https://bsky.app/profile/aging-us.bsky.social ResearchGate - https://www.researchgate.net/journal/Aging-1945-4589 X - https://twitter.com/AgingJrnl Facebook - https://www.facebook.com/AgingUS/ Instagram - https://www.instagram.com/agingjrnl/ LinkedIn - https://www.linkedin.com/company/aging/ Reddit - https://www.reddit.com/user/AgingUS/ Pinterest - https://www.pinterest.com/AgingUS/ YouTube - https://www.youtube.com/@Aging-US Spotify - https://open.spotify.com/show/1X4HQQgegjReaf6Mozn6Mc MEDIA@IMPACTJOURNALS.COM

    4 min
  2. Aging-US Editors' Choice (March, 2026)

    4 DAYS AGO

    Aging-US Editors' Choice (March, 2026)

    Biomarkers of aging help researchers understand how diseases influence the body over time. However, most current biomarkers rely on measurements from mixed cell populations, making it difficult to distinguish between changes caused by shifts in cell types and aging processes occurring within individual cells. In this study, titled “Single-cell transcriptomics reveal intrinsic and systemic T cell aging in COVID-19 and HIV” and published in Volume 18 of Aging-US, researchers used single-cell RNA sequencing to analyze aging-related changes in human T cells. They developed Tictock, a single-cell transcriptomic clock that predicts both cellular age and T cell type across six human T cell subsets. Applying this tool, the researchers found that acute COVID-19 was associated with increased proportions of CD8⁺ cytotoxic T cells, while T cell composition remained relatively stable in individuals with HIV receiving antiretroviral therapy (HIV+ART). Despite these differences, both conditions showed signs of accelerated transcriptomic aging, particularly in naïve CD8⁺ T cells. Further analysis identified shared aging-related genes and biological pathways linked to ribosomal components and TNF receptor binding. These findings demonstrate how single-cell transcriptomic biomarkers can help separate systemic immune changes from cell-intrinsic aging processes, providing new tools to measure immune aging in disease. DOI - https://doi.org/10.18632/aging.206353 Corresponding author - Eric Verdin - EVerdin@buckinstitute.org Abstract video - https://www.youtube.com/watch?v=_r3AF7OrgKY Sign up for free Altmetric alerts about this article - https://aging.altmetric.com/details/email_updates?id=10.18632%2Faging.206353 Subscribe for free publication alerts from Aging - https://www.aging-us.com/subscribe-to-toc-alerts Keywords - aging, transcriptomic clock, aging biomarkers, systemic aging, intrinsic aging To learn more about the journal, please visit https://www.Aging-US.com​​ and connect with us on social media at: Bluesky - https://bsky.app/profile/aging-us.bsky.social ResearchGate - https://www.researchgate.net/journal/Aging-1945-4589 X - https://twitter.com/AgingJrnl Facebook - https://www.facebook.com/AgingUS/ Instagram - https://www.instagram.com/agingjrnl/ LinkedIn - https://www.linkedin.com/company/aging/ Reddit - https://www.reddit.com/user/AgingUS/ Pinterest - https://www.pinterest.com/AgingUS/ YouTube - https://www.youtube.com/@Aging-US Spotify - https://open.spotify.com/show/1X4HQQgegjReaf6Mozn6Mc MEDIA@IMPACTJOURNALS.COM

    2 min
  3. Tictock: A Single-Cell Clock Measures Immune Aging in Viral Infections

    6 DAYS AGO

    Tictock: A Single-Cell Clock Measures Immune Aging in Viral Infections

    Aging reshapes the immune system in two fundamental ways: it alters the proportions of different immune cell types circulating in the blood, and it induces molecular changes within each individual cell. For years, researchers have struggled to disentangle these two intertwined processes using standard “bulk” measurements, which average signals across millions of cells and obscure what is happening at the single-cell level. A new research paper, titled “Single-cell transcriptomics reveal intrinsic and systemic T cell aging in COVID-19 and HIV” published in Volume 18 of Aging-US by researchers at the Buck Institute for Research on Aging in California, the University of Southern California, and the University of Copenhagen, introduces an innovative solution. The team of Alan Tomusiak, Sierra Lore, Morten Scheibye-Knudsen, and corresponding author Eric Verdin, developed a novel tool called Tictock (T immune cell transcriptomic clock) that uses single-cell RNA sequencing to separately measure systemic and cell-intrinsic components of immune aging, and then applied it to understand how COVID-19 and HIV affect T cells. Full blog - https://aging-us.org/2026/03/tictock-a-single-cell-clock-measures-immune-aging-in-viral-infections/ Paper DOI - https://doi.org/10.18632/aging.206353 Corresponding author - Eric Verdin - EVerdin@buckinstitute.org Abstract video - https://www.youtube.com/watch?v=_r3AF7OrgKY Sign up for free Altmetric alerts about this article - https://aging.altmetric.com/details/email_updates?id=10.18632%2Faging.206353 Subscribe for free publication alerts from Aging - https://www.aging-us.com/subscribe-to-toc-alerts Keywords - aging, transcriptomic clock, aging biomarkers, systemic aging, intrinsic aging To learn more about the journal, please visit https://www.Aging-US.com​​ and connect with us on social media at: Bluesky - https://bsky.app/profile/aging-us.bsky.social ResearchGate - https://www.researchgate.net/journal/Aging-1945-4589 X - https://twitter.com/AgingJrnl Facebook - https://www.facebook.com/AgingUS/ Instagram - https://www.instagram.com/agingjrnl/ LinkedIn - https://www.linkedin.com/company/aging/ Reddit - https://www.reddit.com/user/AgingUS/ Pinterest - https://www.pinterest.com/AgingUS/ YouTube - https://www.youtube.com/@Aging-US Spotify - https://open.spotify.com/show/1X4HQQgegjReaf6Mozn6Mc MEDIA@IMPACTJOURNALS.COM

    7 min
  4. Next-Generation Metabolic Theory Suggests Glycolytic ATP Decline May Limit Lifespan

    3 MAR

    Next-Generation Metabolic Theory Suggests Glycolytic ATP Decline May Limit Lifespan

    BUFFALO, NY — March 3, 2026 — A new #research perspective was #published in Volume 18 of Aging-US on February 24, 2026, titled “A decline in glycolytic ATP production is the fundamental mechanism limiting lifespan; species with an optimal rate of decline over time survived.” Led by Akihiko Taguchi — who is also the corresponding author and is affiliated with the Department of Regenerative Medicine Research, Foundation for Biomedical Research and Innovation at Kobe — the perspective advances a unifying conceptual framework in which a programmed or selected decline in glycolytic ATP production over the lifespan underlies aging phenotypes across species. The authors argue that glycolysis supplies the rapid ATP required for cell division and DNA/mitochondrial repair, and that a progressive reduction in glycolytic ATP with age can explain reduced cell proliferation, impaired repair, and other hallmark features of aging. “The simple explanation is that only species that happened to have an optimal rate of reduction in glycolytic ATP production over time were selected and survived through generational changes.” The perspective synthesizes evidence from comparative biology, cellular metabolism, and translational studies to link glycolytic decline with lifespan variation among species — for example, contrasting short-lived rodents with long-lived species such as the naked mole rat, which maintain high glycolytic flux in low-oxygen niches. The authors also highlight mechanisms connecting glycolysis to mitophagy, telomere dynamics, and proteostasis, arguing that maintaining glycolytic ATP supports repair processes while a shift toward oxidative metabolism improves energy efficiency under resource limitation but reduces rapid-repair capacity. The authors propose several concrete next steps to test the hypothesis. These include in vivo and in vitro interventions that modulate glycolysis (for example, gene transfer of glycolysis-related enzymes or pharmacologic activators such as terazosin), longitudinal measurements of glycolytic ATP production across aging cohorts, and comparative studies across species with differing lifespans to define the “optimal rate” of decline. They also suggest mechanistic studies of gap-junction–mediated metabolic coupling (for example, between hematopoietic stem cells and endothelium) and experiments to determine whether restoring glycolytic flux can rescue age-related deficits in DNA repair and tissue regeneration. While the perspective offers a coherent conceptual model, the authors are explicit about limitations and caution: the idea is currently a hypothesis that requires experimental validation, and the evolutionary rationale (selection for an optimal rate of glycolytic decline) must be tested by comparative and mechanistic work. Translation to human rejuvenation therapies — whether via stem-cell approaches, metabolic activators, or gene transfer — will require careful preclinical studies to evaluate efficacy, safety, and long-term consequences. DOI - https://doi.org/10.18632/aging.206356 Corresponding author - Akihiko Taguchi - taguchi@fbri.org Abstract video - https://www.youtube.com/watch?v=rA23radaoqI Subscribe for free publication alerts from Aging - https://www.aging-us.com/subscribe-to-toc-alerts To learn more about the journal, please visit https://www.Aging-US.com​​ and connect with us on social media at: Bluesky - https://bsky.app/profile/aging-us.bsky.social ResearchGate - https://www.researchgate.net/journal/Aging-1945-4589 X - https://twitter.com/AgingJrnl Facebook - https://www.facebook.com/AgingUS/ Instagram - https://www.instagram.com/agingjrnl/ LinkedIn - https://www.linkedin.com/company/aging/ Reddit - https://www.reddit.com/user/AgingUS/ Pinterest - https://www.pinterest.com/AgingUS/ YouTube - https://www.youtube.com/@Aging-US Spotify - https://open.spotify.com/show/1X4HQQgegjReaf6Mozn6Mc MEDIA@IMPACTJOURNALS.COM

    4 min
  5. Study Identifies Opposing Roles for IL6 and IL6R in Long-Term Mortality

    27 FEB

    Study Identifies Opposing Roles for IL6 and IL6R in Long-Term Mortality

    BUFFALO, NY — February 27, 2026 — A new #research paper was #published in Volume 18 of Aging-US on February 6, 2026, titled “Causal effects of inflammation on long-term mortality: a Mendelian randomization study.” Led by Eliano P. Navarese from Department of Life and Health Sciences, Link Campus University and SIRIO MEDICINE Research Network, Nicolaus Copernicus University, who is also the corresponding author — the study used large-scale Mendelian randomization (MR) to test whether genetically proxied levels of inflammatory biomarkers causally influence long-term all-cause mortality. The analysis combined genome-wide association instruments from more than 750,000 individuals and used FinnGen mortality data (median follow-up 11.7 years) to assess effects on overall survival and major cardiovascular endpoints. Using robust MR methods and multiple sensitivity analyses, the authors report that genetically higher IL6R (soluble IL-6 receptor) levels were associated with reduced all-cause mortality (odds ratio per 1-SD increase: 0.95; 95% CI: 0.91–0.98), and with lower risk of atrial fibrillation, coronary artery disease, stroke, and lung cancer. By contrast, genetically higher IL6 levels were associated with increased mortality (OR 1.05; 95% CI: 1.02–1.08). No significant causal effects were observed for CRP or GDF15, suggesting those markers more likely reflect disease burden than drive it. “These results support IL6R antagonism as a potential strategy for cardiovascular disease prevention.” The authors emphasize that the opposing directions for IL6 and IL6R point to distinct biological mechanisms: IL6 likely promotes chronic pro-inflammatory states that increase cardiovascular risk, while higher circulating IL6R (reflecting altered receptor shedding and signaling) appears to dampen harmful IL6 activity at the vessel wall and myocardium, yielding cardiovascular protection. Sensitivity and cis-MR analyses reinforced the IL6R protective signal and showed minimal evidence of directional pleiotropy. Together, the genetic evidence aligns with clinical trial data for IL6R antagonists in other settings and supports further evaluation of IL6R-targeted strategies for cardiovascular prevention. The paper also notes important limitations and next steps. Analyses were restricted to individuals of European ancestry, so results require replication in other ancestries. Translating genetic evidence into preventive therapies will need careful clinical evaluation, long-term safety assessment, and trials designed for primary prevention in high-risk populations. The authors also call for additional mechanistic work to map how IL6/IL6R modulation alters vascular inflammation and downstream disease processes. DOI - https://doi.org/10.18632/aging.206352 Corresponding author - Eliano P. Navarese - elianonavarese@gmail.com Abstract video - https://www.youtube.com/watch?v=Br1A0jgU-4M Sign up for free Altmetric alerts about this article - https://aging.altmetric.com/details/email_updates?id=10.18632%2Faging.206352 Subscribe for free publication alerts from Aging - https://www.aging-us.com/subscribe-to-toc-alerts Keywords - aging, mendelian randomization, inflammatory biomarkers, mortality, cardiovascular disease To learn more about the journal, please visit https://www.Aging-US.com​​ and connect with us on social media at: Bluesky - https://bsky.app/profile/aging-us.bsky.social ResearchGate - https://www.researchgate.net/journal/Aging-1945-4589 X - https://twitter.com/AgingJrnl Facebook - https://www.facebook.com/AgingUS/ Instagram - https://www.instagram.com/agingjrnl/ LinkedIn - https://www.linkedin.com/company/aging/ Reddit - https://www.reddit.com/user/AgingUS/ Pinterest - https://www.pinterest.com/AgingUS/ YouTube - https://www.youtube.com/@Aging-US Spotify - https://open.spotify.com/show/1X4HQQgegjReaf6Mozn6Mc MEDIA@IMPACTJOURNALS.COM

    4 min
  6. Acknowledgment of 2025 Reviewers

    25 FEB

    Acknowledgment of 2025 Reviewers

    Aging-US sincerely thanks all reviewers who contributed their expertise and time during 2025. Rigorous and constructive peer review is essential to scientific progress. Through their careful evaluations, our reviewers played a central role in maintaining the scientific quality, integrity, and credibility of the journal. Their efforts also directly support one of the core missions of Aging-US, which is to increase the visibility and impact of high-quality research in the biology of aging and age-related disease. We are deeply grateful for this commitment to excellence and to the aging research community, and we look forward to continued collaboration in the coming year. –Marco Demaria Editor-in-Chief, Aging-US ____________ To learn more about the journal, please visit https://www.Aging-US.com​​ and connect with us on social media at: Bluesky - https://bsky.app/profile/aging-us.bsky.social ResearchGate - https://www.researchgate.net/journal/Aging-1945-4589 X - https://twitter.com/AgingJrnl Facebook - https://www.facebook.com/AgingUS/ Instagram - https://www.instagram.com/agingjrnl/ LinkedIn - https://www.linkedin.com/company/aging/ Reddit - https://www.reddit.com/user/AgingUS/ Pinterest - https://www.pinterest.com/AgingUS/ YouTube - https://www.youtube.com/@Aging-US Spotify - https://open.spotify.com/show/1X4HQQgegjReaf6Mozn6Mc MEDIA@IMPACTJOURNALS.COM

    1 min
  7. Study Identifies Aging-Associated Mitochondrial Circular RNAs

    24 FEB

    Study Identifies Aging-Associated Mitochondrial Circular RNAs

    BUFFALO, NY — February 24, 2026 — A new #research paper was #published in Volume 18 of Aging-US on February 10, 2026, titled “Aging-associated mitochondrial circular RNAs.” Led by first author Hyejin Mun from the University of Oklahoma — with corresponding authors Je-Hyun Yoon from the University of Oklahoma and Young-Kook Kim from Chonnam National University Medical School — the study profiles mitochondrial circular RNAs in Peripheral Blood Mononuclear Cells (PBMCs) from young and old human cohorts and probes how mitochondrial circRNAs and the mitochondrial RNA-binding protein GRSF1 relate to mitochondrial metabolism and cellular senescence. Using total RNA sequencing of PBMCs from young and old donors and complementary cell-based experiments, the authors report that a large fraction of circular RNA junctions originates from the mitochondrial genome, with MT-RNR2 producing the most abundant circular junctions. They show that circMT-RNR2 levels are depleted in older cohorts and in replicative senescence of human fibroblasts, and that the mitochondria-localized RNA-binding protein GRSF1 interacts with both linear and circular MT-RNR2. Loss of GRSF1 reduced circMT-RNR2 levels, decreased mitochondrial TCA intermediates (fumarate and succinate), and accelerated cellular senescence and mitochondrial dysfunction — findings that link mitochondrial circRNAs to mitochondrial energetics and proliferative status in younger cells. “Taken together, our findings demonstrate the existence and possible function of circular MT-RNR2 during human aging and senescence, implicating its role in promoting the TCA cycle.” The authors note key limitations and outline next steps: clarifying the biogenesis mechanism of mitochondrial circular RNAs (including whether trans-splicing contributes), mapping direct interactions between mitochondrial transcripts and metabolic enzymes, and performing mechanistic studies (in vivo and in additional human cohorts) to test how circMT-RNR2 and GRSF1 influence mitochondrial energetics and organismal aging. These follow-ups will determine whether mitochondrial circular RNAs are actionable targets for modulating mitochondrial metabolism or delaying aspects of cellular aging. DOI - https://doi.org/10.18632/aging.206354 Corresponding authors - Je-Hyun Yoon - jehyun-yoon@ou.edu, and Young-Kook Kim - ykk@jnu.ac.kr Abstract video - https://www.youtube.com/watch?v=f8uZ6_tcOHw Sign up for free Altmetric alerts about this article - https://aging.altmetric.com/details/email_updates?id=10.18632%2Faging.206354 Subscribe for free publication alerts from Aging - https://www.aging-us.com/subscribe-to-toc-alerts Keywords - aging, circular RNA, MT-RNR2, GRSF1, TCA cycle To learn more about the journal, please visit https://www.Aging-US.com​​ and connect with us on social media at: Bluesky - https://bsky.app/profile/aging-us.bsky.social ResearchGate - https://www.researchgate.net/journal/Aging-1945-4589 X - https://twitter.com/AgingJrnl Facebook - https://www.facebook.com/AgingUS/ Instagram - https://www.instagram.com/agingjrnl/ LinkedIn - https://www.linkedin.com/company/aging/ Reddit - https://www.reddit.com/user/AgingUS/ Pinterest - https://www.pinterest.com/AgingUS/ YouTube - https://www.youtube.com/@Aging-US Spotify - https://open.spotify.com/show/1X4HQQgegjReaf6Mozn6Mc MEDIA@IMPACTJOURNALS.COM

    3 min
  8. New Single-Cell Transcriptomic Clock Reveals Intrinsic and Systemic T Cell Aging in COVID-19 and HIV

    19 FEB

    New Single-Cell Transcriptomic Clock Reveals Intrinsic and Systemic T Cell Aging in COVID-19 and HIV

    BUFFALO, NY — February 19, 2026 — A new #research paper was #published in Volume 18 of Aging-US on February 8, 2026, titled “Single-cell transcriptomics reveal intrinsic and systemic T cell aging in COVID-19 and HIV.” In this study, co-first authors Alan Tomusiak from the Buck Institute for Research on Aging and the University of Southern California, and Sierra Lore from the Buck Institute for Research on Aging and the University of Copenhagen, together with corresponding author Eric Verdin from the Buck Institute for Research on Aging, developed a new single-cell transcriptomic clock called T immune cell transcriptomic clock (Tictock) to measure aging in specific immune cells. Immune aging increases susceptibility to infection, cancer, and chronic inflammatory disease. Most aging clocks, used to measure it, rely on bulk measurements from mixed cell populations. As a result, they cannot determine whether age-related signals reflect shifts in cell proportions or true molecular aging within defined immune cells. To address this limitation, the research team used single-cell RNA sequencing, a method that measures gene expression in individual cells. They analyzed nearly two million immune cells from the blood of healthy adults to develop Tictock. This tool integrates automated classification of six canonical T cell subsets with cell-type specific age prediction models. This design enables the separation of systemic aging, reflected by changes in cell proportions, from intrinsic aging, which occurs within individual cells. When the team applied Tictock to patients with acute COVID-19, they found two clear effects. First, COVID-19 altered T cell composition, including significant reductions in naïve CD8 and naïve CD4 T cells. Second, the infection increased the biological age of naïve CD8 T cells. In people living with HIV who were receiving long-term antiretroviral therapy, T cell proportions remained largely stable. However, naïve CD8 T cells still showed signs of accelerated aging. The study also uncovered shared biological pathways linked to immune aging. Many of the genes that predicted age were involved in ribosomes, the structures that help cells produce proteins. The researchers also observed that older immune cells often had shorter average transcript lengths, a feature previously linked to aging. These findings suggest that changes in protein production and gene regulation play an important role in immune decline. “Gene Ontology enrichment of 209 genes shared across six clock models identified common pathways including the cytosolic small ribosomal subunit, TNF receptor binding, and cytosolic ribosome components.” Overall, Tictock was designed to measure relative aging within defined T cell populations rather than overall biological aging. By distinguishing systemic from cell-intrinsic immune aging, it provides a clearer understanding of how viral infections such as COVID-19 and HIV reshape immune function. This approach enables the study of immune aging at single-cell resolution and may support improved immune risk assessment in clinical and research settings. DOI - https://doi.org/10.18632/aging.206353 Corresponding author - Eric Verdin - EVerdin@buckinstitute.org Abstract video - https://www.youtube.com/watch?v=_r3AF7OrgKY Subscribe for free publication alerts from Aging - https://www.aging-us.com/subscribe-to-toc-alerts To learn more about the journal, please visit https://www.Aging-US.com​​. MEDIA@IMPACTJOURNALS.COM

    4 min
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About

Aging-US is dedicated to advancing our understanding of the biological mechanisms that drive aging and the development of age-related diseases. Our mission is to serve as a platform for high-quality research that uncovers the cellular, molecular, and systemic processes underlying aging, and translates these insights into strategies to extend healthspan and delay the onset of chronic disease. Read about the Aging-US Scientific Integrity Process: https://aging-us.com/scientific-integrity

Information

  • Creator
    Aging-US Podcast
  • Years Active
    2021 - 2026
  • Episodes
    500
  • Rating
    Clean
  • Copyright
    © All rights reserved
  • Show Website
    Aging-US

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