Epithalon (50 mg)

Telomerase-Modulating Peptide / Pineal Tetrapeptide / Longevity & Regeneration Research

Epithalon (also known as Epitalon or Ala–Glu–Asp–Gly) is a synthetic version of Epithalamin, a naturally occurring tetrapeptide isolated from the pineal gland. This peptide has been extensively studied in Russian and Eastern European biogerontology research for its potential influence on:

• Telomerase activation

• Telomere length maintenance

• Cellular senescence modulation

• Oxidative stress resistance

• Neuroendocrine regulation

• Immune system remodeling

Epithalon is widely used as a research tool in aging, cellular longevity, circadian biology, and regenerative medicine models.

Epithalon (50 mg) described here is for research use only.

Specifications

Synonyms: Epithalon, Epitalon, Ala-Glu-Asp-Gly, AEDG peptide, Epithalamin synthetic analog
Sequence: Ala–Glu–Asp–Gly
Molecular Formula: C₁₄H₂₂N₄O₉
Molecular Weight: ~390.3 g/mol
Class: Pineal tetrapeptide / telomerase-modulating research peptide
Presentation: 50 mg lyophilized peptide, ≥98% purity (research grade)

Mechanism of Action & Cellular Biology

Epithalon interacts with key molecular pathways involved in aging, telomere biology, and oxidative protection.

1. Telomerase Activation

Research shows that Epithalon can:

• Increase telomerase reverse transcriptase (TERT) activity

• Promote telomere elongation in somatic cells

• Delay telomere shortening associated with replicative aging

This has been demonstrated in:

• Fibroblast culture

• Lymphocyte models

• Senescence-accelerated animal models

2. Modulation of Cellular Senescence

Epithalon has been shown to:

• Reduce β-galactosidase expression (senescence marker)

• Improve cellular proliferation capacity

• Decrease DNA damage markers in stressed cells

3. Antioxidant and Anti-Radical Effects

The peptide enhances natural antioxidant systems:

• ↑ Superoxide dismutase (SOD)

• ↓ Lipid peroxidation products (MDA)

• ↑ Cellular resistance to reactive oxygen species

4. Regulation of Circadian Rhythm & Endocrine Function

Epithalon influences:

• The pineal–hypothalamic axis

• Melatonin production and circadian rhythmicity

• Age-related neuroendocrine decline

These mechanisms are foundational to aging research models.

Longevity, Aging & Geroprotection Research

Epithalon is most widely studied in lifespan and healthspan models.

1. Increased lifespan in animal models

Studies report:

• Lifespan extension in rodents by up to 25–30% in select conditions

• Improved overall vitality and reduced tumor incidence in aging cohorts

• Restoration of circadian rhythmicity in older animals

2. Reduced incidence of age-related pathology

Research indicates:

• Lower rates of spontaneous tumor formation

• Improved immune function in aged animals

• Protection against age-associated degenerative changes

3. Gene expression modulation

Epithalon influences expression of genes involved in:

• Stress response

• Inflammation

• Metabolic regulation

• DNA repair

Immune System & Anti-Inflammatory Research

1. Immunomodulation

Epithalon has demonstrated:

• Enhanced T-cell proliferation

• Improved thymus function in aging models

• Reduction in inflammatory cytokines

2. Anti-inflammatory activity

Epithalon reduces:

• TNF-α

• IL-6

• Oxidative stress–driven inflammatory cascades

These effects contribute to its use in immune aging research.

Neuroprotective & Cognitive Research

Epithalon may influence neuronal aging via:

• Anti-oxidative pathways

• Improved mitochondrial function

• Protection of hippocampal neurons

• Stabilization of circadian patterns affecting cognition

Research shows improvements in:

• Learning and memory tasks (rodent models)

• Sleep–wake cycle regularity

• Age-related neurodegeneration markers

Dermatology, Tissue Repair & Regeneration

Epithalon studies demonstrate:

• Increased fibroblast proliferation

• Enhanced collagen type I and III synthesis

• Reduced skin aging markers (elastosis, oxidative damage)

• Improved wound healing capacity

These applications make it a frequent tool in dermatological and regenerative biology.

Safety, Limitations & Regulatory Notes

• Epithalon is not approved for human therapeutic, cosmetic, or anti-aging use.

• Research suggests low toxicity, but human long-term data is insufficient.

• Results from Russian aging studies may not fully extrapolate across species or populations.

• Research-grade peptide should not be used clinically or for self-administration.

Research Use Only – Important Notice

This Epithalon (50 mg) product is supplied exclusively for laboratory research.

• Not for human or veterinary use

• Not for anti-aging, cosmetic, or medical applications

• For controlled in vitro and animal experiments only

• Provided descriptions summarize findings from preclinical and cellular aging literature

• Not to be interpreted as medical advice or dosing guidance

References (Peer-reviewed, Non-Wikipedia)

1. Khavinson VKh et al. Epithalon activates telomerase and elongates telomeres in human somatic cells. Bull Exp Biol Med.
   https://pubmed.ncbi.nlm.nih.gov/12522020/

Anisimov VN et al. Pineal peptides and lifespan extension in rodents. Mech Ageing Dev.
https://pubmed.ncbi.nlm.nih.gov/11074490/

Pierpaoli W, Lesnikov VA. Immune restoration and aging models involving Epithalon. Ann N Y Acad Sci.
https://pubmed.ncbi.nlm.nih.gov/9710653/

Khavinson VKh, Malinin VV. Peptide regulation of aging: Epithalamin and Epithalon. Neuro Endocrinol Lett.
https://pubmed.ncbi.nlm.nih.gov/14647007/

Arutyunyan AV et al. Antioxidant and anti-radical properties of the pineal peptide Epithalon. Bull Exp Biol Med.
https://pubmed.ncbi.nlm.nih.gov/15807042/

Weinert BT, Timiras PS. The aging circadian system and endocrine modulation by pineal peptides. Biogerontology.
https://pubmed.ncbi.nlm.nih.gov/11067792/

Kozina LS et al. Effects of Epithalon on expression of stress-response and DNA repair genes. Mol Biol Rep.
https://pubmed.ncbi.nlm.nih.gov/21404050/