RESEARCH BASE
Search 3,717 documents across 34 fields — every claim tier-rated by evidence
13 results for "senescence"
R_3_14 — Evolution of Aging and Senescence
Aging — the progressive decline in physiological function and increase in mortality rate with time — is one of evolution's deepest puzzles: why would natural selection, which optimizes fitness, permit organisms to deteri
Z_2_19 — Senolytics & Geroscience: Targeting Cellular Senescence in Aging
Cellular senescence — the irreversible arrest of cell division first described by Leonard Hayflick and Paul Moorhead (1961, Experimental Cell Research) — has emerged as a central mechanism of aging and age-related diseas
Z_2_10 — Genetics of Aging and Progeria
Aging — the progressive decline in physiological function leading to increased vulnerability to disease and death — has a substantial genetic component: twin studies estimate heritability of human lifespan at ~25–30% (He
Z_2_21 — Epigenetic Aging Clocks
Epigenetic aging clocks are mathematical models that use patterns of DNA methylation at specific CpG dinucleotides across the genome to estimate an individual's biological age with remarkable accuracy — typically within
Z_2_14 — Genetics of Longevity and Blue Zones
The genetics of human longevity — why some individuals live past 100 while most do not — is a field where heritability is modest, effect sizes are small, and environmental factors dominate, yet several genetic pathways h
Z_2_22 — Telomere Molecular Biology
Telomeres are the protective nucleoprotein structures capping the ends of linear eukaryotic chromosomes, consisting of tandem repetitive DNA sequences (5'-TTAGGG-3' in vertebrates, repeating ~1,000–2,000 times for a tota
Z_2_02 — Telomere Biology & Genetics of Aging
Telomeres — repetitive DNA sequences (TTAGGG)ₙ capping the ends of linear chromosomes — serve as protective buffers against chromosome degradation, end-to-end fusion, and the progressive DNA loss inherent in the end-repl
ZB_2_05 — Aging, Longevity, and the Biology of Death
Why do organisms age and die? This question — one of the oldest in human inquiry — has yielded remarkable molecular answers in recent decades. Leonard Hayflick's 1961 discovery that human cells have a finite replicative
ZB_2_13 — Death Biology: Programmed Cell Death
Death in biology is not merely the passive failure of living systems but an actively regulated process at multiple levels — from individual cells to whole organisms. Programmed cell death (PCD), particularly apoptosis, w
L_3_10 — Telomeres Aging and Longevity Genetics
Telomeres — the repetitive DNA sequences (TTAGGG in vertebrates) capping the ends of linear chromosomes — protect genome integrity by preventing chromosome ends from being recognized as double-strand breaks and triggerin
L_5_05 — Epigenetic Clocks: Measuring Biological Age
Epigenetic clocks are mathematical models that estimate biological age — the physiological age of an organism's cells and tissues — based on DNA methylation patterns at specific CpG sites (regions where a cytosine nucleo
S_2_08 — Longevity Science: Senolytics, Telomeres, and Lifespan Extension
Longevity science — the systematic study of biological aging with the goal of extending human healthspan (years of healthy life) and potentially lifespan — has transformed from a fringe pursuit into a mainstream biomedic
S_2_20 — Longevity Science & Senolytics
Longevity science — also termed geroscience — aims to understand and intervene in the biological mechanisms of aging to extend human healthspan (years of healthy life) and potentially lifespan. The field has shifted from
BROWSE BY SECTION — 3717 documents across 34 fields