Biomarkers
Overview
Biomarkers of aging are measurable indicators that predict biological age, healthspan, and lifespan more accurately than chronological age. These markers enable assessment of aging rate, evaluation of interventions, and prediction of age-related disease risk.
Related: [[Biological Age Assessment]] | [[Longevity Science Overview]]
[!note] 2025 Developments Two major 2025 publications established new frameworks for aging biomarkers:
The Lancet Healthy Longevity: Digital biomarkers across 10 physiological systems
Nature npj Aging: Functional parameters vs. molecular biomarkers
Expert Consensus Statement (Gerontology Series A): Standardized biomarkers for intervention studies
Categories of Biomarkers
1. Molecular Biomarkers
Epigenetic markers (DNA methylation)
Telomere length
Proteomics signatures
Metabolomics profiles
Glycomics patterns
Gene expression changes
2. Cellular Biomarkers
Senescent cell burden
Stem cell function
Immune cell profiles
Mitochondrial function
Cellular energy metabolism
3. Physiological Biomarkers
Blood chemistry panels
Inflammatory markers
Hormonal profiles
Organ function tests
Body composition
4. Functional Biomarkers
Physical performance tests
Cognitive assessments
Sensory function
Muscle strength and mass
Cardiovascular fitness
5. Digital Biomarkers (2025)
Wearable device metrics
Continuous monitoring data
Behavioral patterns
Sleep architecture
Activity levels
Epigenetic Biomarkers
DNA Methylation Clocks
[!tip] Gold Standard DNA methylation-based clocks represent the most accurate biological age predictors, with some achieving correlations of r > 0.95 with chronological age.
First Generation Clocks
Horvath Clock (2013)
Accuracy: r = 0.97 with chronological age, median error 2.9 years
CpG Sites: 353 specific methylation sites
Training: ~8,000 samples across 51 tissue types
Method: Elastic net regression on Illumina arrays
Applicability: Pan-tissue (works across different cell types)
Cost: $300-500 per test
Sample: Blood or saliva
Hannum Clock (2013)
CpG Sites: 71 sites
Tissue: Blood-specific
Accuracy: Strong correlation with chronological age
Applications: Blood-based aging assessment
Second Generation Clocks
DNAm PhenoAge (2018)
CpG Sites: 513 methylation sites
Accuracy: r = 0.94 with chronological age
Superior Predictions:
All-cause mortality
Cancer incidence
Alzheimer's disease risk
Overall healthspan
Development: Trained on clinical chemistry biomarkers + mortality data
Advantage: Captures biological aging better than chronological age
GrimAge (2019)
Components: DNA methylation surrogates for:
Smoking pack-years
7 plasma proteins (adrenomedullin
β2-microglobulin
cystatin C
etc.)
Performance: Strongest predictor of lifespan and healthspan
Mortality Prediction (2025 data):
GrimAgeEAA: β = +0.476 ± 0.0393 (NHANES)
GrimAgeEAA: β = +0.511 ± 0.0775 (HRS)
Outperforms telomere length in mortality prediction
Clinical Correlations:
Cardiovascular disease
Cancer
Cognitive decline
Frailty
Third Generation Clocks
DunedinPACE (Pace of Aging, Computed from the Epigenome)
Innovation: Measures rate of aging (not just age estimate)
Units: Years of biological aging per calendar year
Normal Range: 0.8-1.2 (slower to faster aging)
Applications: Intervention tracking, personalized medicine
Advantage: Detects aging rate changes over short periods
DunedinPoAm (Pace of Aging, methylation)
Training: Dunedin longitudinal birth cohort
Measures: Rate of biological decline
Validation: Multiple health outcomes over decades
Recent Developments (2025)
EpiAge Test
Method: Next-generation sequencing (NGS) based
Sample: Saliva or blood
Accuracy: Comparable to established clocks
Advantage: More accessible than microarray-based tests
Comparative Performance (2025) Based on three US cohorts (NHANES, HRS, HANDLS):
GrimAgeEAA: Strongest mortality predictor
HannumAgeEAA: Second-best performance
DunedinPACE/PoAM: Best for aging rate
Horvath: Pan-tissue accuracy, moderate mortality prediction
Telomere Length: Weaker than epigenetic clocks
Telomere Length
Biology:
Protective DNA caps on chromosome ends
Shorten with each cell division (50-200 base pairs/year)
Critical shortening triggers senescence
Measurement Methods:
Quantitative PCR (qPCR) - most common
Flow-FISH (flow cytometry)
Terminal restriction fragment (TRF) analysis
Single telomere length analysis (STELA)
Associations:
Cardiovascular disease
Cancer risk (complex relationship)
Cognitive decline
Mortality (weaker than epigenetic clocks)
2025 Research Findings:
Inflammaging mediates telomere-health associations
Faster telomere attrition → lower grip strength (β = 0.98
p = 0.035)
Association completely attenuated when adjusted for inflammation (p = 0.86)
Suggests inflammation drives telomere attrition
Inferior to epigenetic clocks for mortality prediction
Best used in combination with other biomarkers
Limitations:
High inter-individual variation
Tissue-specific differences
Influenced by genetics (~80% heritable)
Single time-point measurements less informative
Blood-Based Biomarkers
Inflammatory Markers
[!warning] Inflammaging Chronic low-grade inflammation ("inflammaging") is a hallmark of aging and predictor of multiple age-related diseases and mortality.
C-Reactive Protein (CRP)
Type: Acute phase reactant produced by liver
Normal Ranges:
Low risk: <1.0 mg/L
Moderate risk: 1.0-3.0 mg/L
High risk: >3.0 mg/L
Associations:
Cardiovascular disease (strongest predictor)
All-cause mortality
Alzheimer's disease
Metabolic syndrome
Frailty
Interpretation:
Values >10 mg/L suggest acute infection/inflammation
Track changes over time, not single values
Responds to lifestyle interventions
Interleukin-6 (IL-6)
Normal Range: <5 pg/mL (varies by assay)
Role in Aging:
Pro-inflammatory cytokine
Increases 2-4 fold from age 20-80
Predictor of disability and mortality
Associations:
Cardiovascular disease
Diabetes
Cancer
Sarcopenia (muscle loss)
Cognitive decline
Tumor Necrosis Factor-Alpha (TNF-α)
Normal Range: <8.1 pg/mL (varies)
Functions:
Pro-inflammatory signaling
Immune cell activation
Cell death regulation
Aging Impact:
Elevated in chronic inflammation
Muscle wasting
Insulin resistance
Neurodegenerative diseases
Metabolic Markers
Glucose Homeostasis
Fasting Glucose
Optimal: 70-85 mg/dL
Normal: <100 mg/dL
Prediabetes: 100-125 mg/dL
Diabetes: ≥126 mg/dL
Hemoglobin A1c (HbA1c)
Optimal: <5.4%
Normal: <5.7%
Prediabetes: 5.7-6.4%
Diabetes: ≥6.5%
Superior: 3-month glucose average, predicts complications
Fasting Insulin
Optimal: <5 μIU/mL
Elevated: >10 μIU/mL
Indicates insulin resistance before glucose rises
HOMA-IR (Insulin Resistance)
Formula: (Fasting Glucose × Fasting Insulin) / 405
Optimal: <1.0
Insulin resistant: >2.5
Lipid Panel
Total Cholesterol
Optimal: <200 mg/dL
Note: Less important than particle size/number
LDL Cholesterol
Optimal: <100 mg/dL (lower for high-risk)
Better: ApoB or LDL particle number
HDL Cholesterol
Optimal: >60 mg/dL
Risk factor if <40 mg/dL (men) or <50 mg/dL (women)
Triglycerides
Optimal: <100 mg/dL
Elevated: >150 mg/dL
Strong predictor of metabolic health
ApoB (Apolipoprotein B)
Better predictor than LDL-C
Optimal: <90 mg/dL
Counts all atherogenic particles
Kidney Function
Creatinine
Normal Ranges:
Men: 0.7-1.3 mg/dL
Women: 0.6-1.1 mg/dL
Aging Impact:
Muscle mass affects levels
May appear normal despite reduced kidney function
Use in eGFR calculation
Blood Urea Nitrogen (BUN)
Normal Range: 7-20 mg/dL
Elevated BUN:
Kidney dysfunction
Dehydration
High protein diet
Catabolic states
Cystatin C
[!tip] Superior Marker Cystatin C is a stronger predictor of mortality risk than creatinine-based eGFR.
Advantages:
Not affected by muscle mass
Earlier detection of kidney decline
Better predictor of cardiovascular events and mortality
Normal Range: 0.6-1.0 mg/L
Use in Biological Age:
Included in enhanced PhenoAge calculations
Strongest single predictor in some studies
eGFR (Estimated Glomerular Filtration Rate)
Calculation: Uses creatinine, age, sex, race
Normal Range: >90 mL/min/1.73m²
Stages of Kidney Disease:
Stage 1: ≥90 (normal)
Stage 2: 60-89 (mild decrease)
Stage 3a: 45-59 (mild-moderate)
Stage 3b: 30-44 (moderate-severe)
Stage 4: 15-29 (severe)
Stage 5: <15 (kidney failure)
Liver Function
Albumin
Normal Range: 3.5-5.5 g/dL
Functions:
Protein nutritional status
Liver synthetic function
Oncotic pressure maintenance
Low Albumin:
Malnutrition
Liver disease
Kidney disease
Inflammation
Mortality predictor
Alkaline Phosphatase (ALP)
Normal Range: 30-120 U/L (varies by age)
Sources:
Liver
Bone
Intestine
Placenta (pregnancy)
Elevated ALP:
Bone disorders (Paget's disease, fractures)
Liver disease (cholestasis)
Associated with increased mortality in elderly
Alanine Aminotransferase (ALT)
Normal Range: 7-56 U/L
Indication:
Liver cell damage/inflammation
Non-alcoholic fatty liver disease (NAFLD)
Metabolic health
Optimal: Lower end of normal range (<30 U/L)
Complete Blood Count (CBC)
White Blood Cell Count (WBC)
Normal Range: 4,000-11,000 cells/μL
Components:
Neutrophils, lymphocytes, monocytes, eosinophils, basophils
Aging:
Chronic elevation associated with inflammation
Immunosenescence affects distribution
High-normal WBC predicts mortality
Red Blood Cell Indices
Mean Cell Volume (MCV)
Normal: 80-100 fL
Low (microcytic): Iron deficiency, thalassemia
High (macrocytic): B12/folate deficiency, alcohol, liver disease
Included in PhenoAge calculation
Red Cell Distribution Width (RDW)
Normal: 11.5-14.5%
Measures variation in RBC size
Strong mortality predictor
Elevated in inflammation, nutritional deficiencies, bone marrow disorders
Included in PhenoAge calculation
Hemoglobin
Men: 13.5-17.5 g/dL
Women: 12.0-15.5 g/dL
Anemia associated with frailty and mortality
Novel Blood Biomarkers
Glycomics
IgG Glycosylation Patterns
Predict immune aging and inflammation
Glycan age correlates with biological aging
Responds to diet and exercise interventions
Emerging biomarker class (2025)
Applications:
Immune system aging
Inflammatory status
Intervention response
Proteomics
Plasma Protein Signatures
Hundreds of proteins change with age
SomaLogic platform: ~1,300 proteins
Olink platform: ~3,000 proteins
Used in GrimAge development
Key Proteins:
Growth differentiation factor 15 (GDF-15): stress, mitochondrial dysfunction
Beta-2 microglobulin: kidney function, immune activation
Cystatin C: kidney function
Adrenomedullin: vascular function
Metabolomics
Small Molecule Profiles
Amino acids, lipids, organic acids
Metabolic health assessment
Mitochondrial function indicators
Functional Biomarkers
[!note] Clinical Significance 2025 research emphasizes that functional biomarkers with excellent mortality correlation and extensive clinical data should not be overlooked in favor of molecular markers.
Physical Performance
Grip Strength
Measurement: Hand dynamometer (kg)
Norms (approximate):
Men 40-49: 40-50 kg
Women 40-49: 25-30 kg
Declines ~1% per year after 50
Significance:
Strong predictor of all-cause mortality
Cardiovascular disease
Disability
Hospitalization
Cognitive decline
2025 Finding:
Association with telomere length mediated by inflammation
Directly reflects systemic biological aging
Walking Speed
Measurement: Time to walk 4-6 meters at usual pace
Threshold: <0.8 m/s indicates high mortality risk
Significance:
Predicts survival in elderly
Cardiovascular fitness
Neurological function
Overall vitality
Easy to measure: Accessible in any clinical setting
Chair Stand Test
Method: Time to stand from chair 5 times without arms
Norms:
<11 seconds: excellent
15 seconds: increased risk
Measures:
Lower body strength
Fall risk
Functional independence
Standing Balance
Tests:
Side-by-side stand
Semi-tandem stand
Full tandem stand
Duration: Hold for 10 seconds each
Predicts:
Fall risk
Neurological health
Mobility decline
Cardiovascular Fitness
VO2 Max
Definition: Maximum oxygen consumption during exercise
Measurement:
Direct: Metabolic cart during exercise test
Estimated: Fitness tracker algorithms
Significance:
Strongest predictor of cardiovascular mortality
Declines ~10% per decade
Modifiable through exercise
Elite vs. Poor:
50-year-old with VO2max of 30-year-old: Biological age advantage
Resting Heart Rate
Optimal: 50-70 bpm (lower in athletes)
Associations:
Cardiovascular health
Autonomic nervous system function
Metabolic health
Mortality risk (elevated RHR)
Heart Rate Variability (HRV)
Measurement: Variation in time between heartbeats
Significance:
Autonomic nervous system balance
Stress resilience
Recovery capacity
Decreases with age
Measurement:
RMSSD (root mean square of successive differences)
SDNN (standard deviation of NN intervals)
Wearable devices now provide
Body Composition
Body Mass Index (BMI)
Calculation: weight (kg) / height (m)²
Categories:
Underweight: <18.5
Normal: 18.5-24.9
Overweight: 25-29.9
Obese: ≥30
Limitations:
Doesn't distinguish muscle vs. fat
Use with waist circumference
Waist Circumference
High Risk:
Men: >102 cm (40 inches)
Women: >88 cm (35 inches)
Indicator:
Visceral fat (metabolically active)
Metabolic syndrome
Cardiovascular risk
All-cause mortality
Waist-to-Height Ratio
Calculation: Waist circumference / Height
Target: <0.5
Advantage: Accounts for height variation
Muscle Mass
Measurement:
DEXA scan (gold standard)
Bioelectrical impedance (BIA)
Anthropometry
Sarcopenia:
Age-related muscle loss
Begins in 30s-40s
Accelerates after 60
Associated with frailty, falls, mortality
Digital Biomarkers (2025)
Wearable-Derived Metrics
[!tip] Continuous Monitoring Digital biomarkers enable continuous, real-world assessment across 10 physiological systems (Lancet Healthy Longevity, 2025).
Sleep Metrics
Key Parameters:
Total sleep time
Sleep efficiency
REM and deep sleep percentage
Sleep fragmentation
Sleep-wake timing
Aging Associations:
Sleep quality declines with age
Reduced deep sleep
Increased fragmentation
Cardiovascular and cognitive health
Activity Patterns
Metrics:
Step count
Active minutes
Sedentary time
Activity intensity distribution
Significance:
Physical activity level
Metabolic health
Cardiovascular fitness
Mortality predictor
Continuous Glucose Monitoring (CGM)
Advanced Metrics:
Time in range (70-140 mg/dL)
Glucose variability
Post-prandial responses
Overnight glucose
Applications:
Metabolic health assessment
Dietary intervention testing
Diabetes prevention
Organ-Specific Biomarkers
Cardiovascular System
Blood Pressure
Systolic BP: optimal <120 mmHg
Diastolic BP: optimal <80 mmHg
Most frequently used in biological age models
Pulse Wave Velocity (PWV)
Arterial stiffness measure
Gold standard: carotid-femoral PWV
Increases with age
Predicts cardiovascular events
Coronary Artery Calcium (CAC) Score
CT scan measurement
Quantifies atherosclerosis
Strong predictor of cardiac events
Zero score: very low risk
NT-proBNP
Heart failure biomarker
Increases with cardiac stress
Predicts cardiovascular events
Brain and Cognition
Cognitive Testing
Memory (verbal, visual)
Processing speed
Executive function
Attention
Brain Imaging
MRI volumetrics (hippocampal volume)
White matter hyperintensities
Amyloid PET (Alzheimer's)
Tau PET
Biomarkers:
Plasma p-tau217 (Alzheimer's prediction)
Neurofilament light chain (NfL): neurodegeneration
BDNF: neuroplasticity
Bone Health
Bone Mineral Density (BMD)
DEXA scan
T-score: <-2.5 = osteoporosis
Fracture risk prediction
Biochemical Markers:
Vitamin D (25-OH)
Parathyroid hormone (PTH)
Bone-specific alkaline phosphatase
Lung Function
FEV1 (Forced Expiratory Volume)
Volume exhaled in 1 second
Declines with age
Predicts mortality
Reduced in COPD, asthma
FVC (Forced Vital Capacity)
Total exhaled volume
FEV1/FVC ratio diagnostic
Composite Biological Age Algorithms
PhenoAge
Components:
Chronological age
Albumin (↓ worse)
Creatinine (↑ worse)
Glucose (↑ worse)
CRP (↑ worse)
Lymphocyte % (↓ worse)
Mean cell volume (↑ worse)
RDW (↑ worse)
ALP (↑ worse)
WBC (↑ worse)
Calculation: Publicly available formula
Interpretation:
PhenoAge < Chronological Age: biologically younger
PhenoAge > Chronological Age: biologically older
Each year difference correlates with mortality risk
Klemera-Doubal Method (KDM)
Approach: Statistical method combining biomarkers
Advantages:
Most validated in systematic reviews
Best mortality predictor
Accounts for biomarker variability
Weighted combination
Biomarkers Used: Flexible (typically 8-15 biomarkers)
Status: Recommended by 2025 systematic review of 56 studies
AI/ML-Based Models
Recent Developments (2025):
27 clinical factors
Multiple algorithm comparison
Elastic-Net Cox: C-Index = 0.778
Outperforms traditional PhenoAge (C-Index = 0.750)
Training Data:
UK Biobank: 306,116 participants, 60 biomarkers
Long-term follow-up
Mortality outcomes
Algorithms:
Elastic Net (best performance)
Random Forest
Gradient Boosting
Support Vector Machine
Ridge regression
LASSO
Biomarker Validation Criteria
Essential Characteristics
Reproducibility: Consistent results across labs and time
Predictive Value: Correlates with aging outcomes
Sensitivity: Detects changes in aging rate
Specificity: Distinguishes biological from chronological aging
Practicality: Cost-effective, accessible, minimally invasive
Evidence Levels
Tier 1: Validated
Epigenetic clocks (Horvath, GrimAge, PhenoAge)
Functional tests (grip strength, walking speed)
Standard blood panels with algorithms (PhenoAge, KDM)
Tier 2: Promising
Telomere length (in combination)
Proteomics signatures
Wearable-derived metrics
Organ-specific imaging
Tier 3: Emerging
Glycomics
Metabolomics
Microbiome markers
Senescent cell burden (in development)
Practical Implementation
For Clinical Use
Minimum Assessment:
Standard blood panel (CBC, CMP, CRP)
Blood pressure
BMI and waist circumference
Grip strength
Calculate: PhenoAge
Enhanced Assessment:
Add: HbA1c, lipid panel, cystatin C
Functional tests (walking speed, chair stand)
Calculate: KDM or AI-based model
Advanced Assessment:
Epigenetic clock (saliva/blood sample)
Wearable data integration
Organ-specific imaging
Comprehensive: Multi-modal biological age
For Research
Longitudinal Studies:
Multiple time points (baseline, 6mo, 1yr, 2yr)
Track intervention effects
Population-specific validation
Intervention Trials:
Primary endpoint: biological age change
Secondary: individual biomarker changes
Quality of life and functional outcomes
Limitations and Considerations
Individual Variation
Genetics account for 20-30% of aging rate
Lifestyle factors: 70-80% influence
Baseline differences affect interpretation
Population-specific models needed
Measurement Challenges
Technical:
Lab-to-lab variation
Timing effects (circadian, seasonal)
Fasting vs. non-fasting
Medication effects
Biological:
Acute illness skews results
Hydration status
Recent exercise
Stress
Interpretation Caution
Single time-point limited value
Trends more meaningful than absolute values
Context matters (acute vs. chronic changes)
Not all biomarkers respond equally to interventions
Future Directions
Emerging Biomarker Classes
Single-cell technologies: Cell-specific aging signatures
Spatial transcriptomics: Tissue-level aging patterns
Circulating cell-free DNA: Non-invasive tissue assessment
Exosome profiling: Intercellular communication
Microbiome markers: Gut-aging axis
Technology Integration
AI/ML Advances:
Multi-omic integration
Personalized biomarker panels
Real-time aging rate calculation
Intervention optimization algorithms
Consumer Accessibility:
At-home testing kits
Smartphone-based assessments
Continuous monitoring devices
Democratization of longevity medicine
Standardization Efforts
Regulatory:
FDA biomarker qualification
Clinical trial acceptance
Insurance coverage pathways
Scientific:
Biomarkers of Aging Consortium
International harmonization
Reference population databases
Intervention response standards
Key Research Resources
2025 Landmark Publications
Digital Biomarkers Review
Digital biomarkers of ageing - The Lancet Healthy Longevity, 2025
10 physiological systems, digital health technologies
Functional vs. Molecular
Biomarkers of aging: functional aspects still trump molecular parameters - Nature npj Aging, 2025
Emphasis on clinical validation
Expert Consensus
Expert Consensus Statement on Biomarkers - Gerontology Series A, 2025
Intervention study standards
Comparative Analysis
Telomere Length, Epigenetic Age Acceleration, and Mortality - Aging Cell, 2025
Head-to-head biomarker comparison
Conferences and Organizations
Biomarkers of Aging Conference
October 20-21, 2025, Boston
Organized by Biomarkers of Aging Consortium
Field-defining annual event
Key Organizations:
American Federation for Aging Research (AFAR)
Gerontological Society of America
Online Resources
Glossary
Epigenetic Clock: DNA methylation-based predictor of biological age
Epigenetic Age Acceleration (EAA): Difference between epigenetic and chronological age
Inflammaging: Chronic low-grade inflammation associated with aging
Immunosenescence: Age-related decline in immune system function
Proteostasis: Maintenance of protein homeostasis
Senescence: Irreversible cell cycle arrest with altered secretory phenotype
Biomarker: Measurable indicator of biological state or condition
Healthspan: Period of life spent in good health
C-Index: Concordance index, measures predictive accuracy (0.5 = random, 1.0 = perfect)
Related Documents
[[Biological Age Assessment]] - Implementation methods and calculations
[[Longevity Science Overview]] - Aging mechanisms and hallmarks
[[Longevity Interventions]] - How to improve biomarkers
[[Recent Longevity Research 2025]] - Latest scientific findings
Last updated: 2025-12-09 Related tags: #biomarkers #aging #testing #measurement #research
Last updated