Anti-Ageing Research Stack

£48.99

Purity: ≥ 99%

£48.99

Anti-Ageing Research Stack

Name: Anti-Ageing Research Stack
Brand: Pure Grade Labs
Price: 48.99 GBP
Availability: OutOfStock

£48.99

Purity: ≥ 99%

£48.99

GENE EXPRESSION - Epigenetic regulation and longevity pathway research

MITOCHONDRIAL FUNCTION - Cellular energy production and metabolic efficiency research

TISSUE REPAIR - Collagen production and connective tissue regeneration research

TELOMERE BIOLOGY - Telomere length maintenance and cellular ageing research

Three Compounds. Three Distinct Hallmarks of Ageing.

Research into the biology of ageing has identified multiple interconnected hallmarks - genomic instability, epigenetic alterations, mitochondrial dysfunction, cellular senescence, and others - that drive the gradual loss of cellular function over time. Most longevity interventions address one or two of these pathways. The Longevity Stack is designed around three compounds that each target a different hallmark with a distinct mechanism and independent evidence base.

Epithalon (tetrapeptide Ala-Glu-Asp-Gly) has been studied for its effects on telomerase activation and telomere length extension in human somatic cells - targeting genomic instability at the chromosomal level. GHK-Cu (Glycyl-L-Histidyl-L-Lysine copper chelate) is a naturally occurring human tripeptide that declines from approximately 200ng/ml at age 20 to 80ng/ml by age 60, studied for collagen synthesis, tissue repair, antioxidant activity, and broad gene expression modulation. MOTS-C is a 16-amino-acid mitochondrial-derived peptide encoded within the 12S rRNA region of the mitochondrial genome, studied for AMPK-mediated metabolic regulation and mitochondrial-nuclear communication - directly targeting mitochondrial dysfunction, one of the best-characterised hallmarks of cellular ageing.

Epithalon (AEDG)

Synthetic tetrapeptide based on Epithalamin, a naturally occurring pineal gland extract first characterised by Khavinson et al. at the St Petersburg Institute of Bioregulation and Gerontology. Studied for telomerase activation, telomere length extension in human somatic cells, melatonin secretion restoration, and chromosomal stability in ageing models. Has been investigated in human clinical studies including retinitis pigmentosa and pulmonary tuberculosis cohorts.

GHK-Cu

Naturally occurring human tripeptide (Glycyl-L-Histidyl-L-Lysine) with high affinity for copper(II) ions. Originally isolated from human plasma by Pickart & Thaler in 1973. Serum levels decline significantly with age. Studied for collagen synthesis stimulation, wound healing, angiogenesis, anti-inflammatory activity, antioxidant effects, and modulation of over 4,000 human genes involved in tissue repair and remodelling. Used in clinical wound healing applications.

MOTS-C

16-amino-acid peptide encoded by a short open reading frame within the 12S rRNA region of the mitochondrial genome - making it one of a small class of mitochondrial-derived peptides (MDPs). Acts as a retrograde signalling molecule, translocating from mitochondria to the nucleus under metabolic stress to regulate nuclear gene expression via the AMPK/AICAR pathway. Plasma levels decline with age (11-21% lower in middle-aged and elderly versus young adults). The first mitochondrial-encoded peptide to enter clinical trials.

Epithalon Sequence (Tetrapeptide): Ala-Glu-Asp-Gly (AEDG) - MW: 390.35 g/mol - CAS: 307297-39-8

GHK-Cu Sequence (Tripeptide Copper Chelate): Gly-His-Lys · Cu(II) - MW: 340.38 g/mol (peptide) - CAS: 49557-75-7

MOTS-C Sequence (Mitochondrial-Derived, 16 AA): Met-Arg-Trp-Gln-Glu-Met-Gly-Tyr-Ile-Phe-Tyr-Pro-Arg-Lys-Leu-Arg - MW: 2,174.6 g/mol - CAS: 1627580-64-6

2003 | Bulletin of Experimental Biology and Medicine | In Vitro / Human Cell Culture

Epithalon induces telomerase activity and telomere elongation in human somatic cells

Khavinson, Bondarev, and Butyugov investigated Epithalon's effect on telomerase expression and telomere length in human fetal fibroblast cultures. Epithalon treatment produced upregulation of the hTERT catalytic subunit, activation of telomerase, and measurable telomere elongation in cells that were telomerase-negative prior to treatment. The degree of telomere extension was sufficient for treated cells to surpass the Hayflick limit - the proliferative barrier imposed by critically short telomeres - extending the number of divisions the cells could undergo before entering senescence. This study established the foundational mechanistic rationale for Epithalon's investigation as a telomere-targeting compound in ageing research and has been cited extensively in subsequent longevity peptide literature.

Khavinson VK, Bondarev IE, Butyugov AA. Bull Exp Biol Med. 2003;135(6):590-592. PubMed →

2025 | Research Square (Preprint) / PMC | In Vitro / Human Cell Lines

Epitalon increases telomere length in human cell lines through telomerase upregulation or ALT activity

Al-dulaimi et al. conducted a systematic quantitative study of Epithalon's effects on telomere length, hTERT mRNA expression, telomerase enzyme activity, and ALT (Alternative Lengthening of Telomeres) activity across multiple human cell lines. In normal fibroblast and epithelial cells, Epithalon produced dose-dependent telomere extension through hTERT upregulation and telomerase activation - with 12-fold upregulation of hTERT expression at 1 μg/ml in 21NT cells. In cancer cells, where hTERT is already active, Epithalon instead activated ALT pathways for telomere maintenance, which the authors attributed to Epithalon's known binding to histone H1 and methylated cytosine, suggesting epigenetic rather than direct telomerase-mediated effects in those cell types. This study provided the most quantitatively detailed characterisation of Epithalon's telomere biology to date.

Al-dulaimi S, et al. PMC12411320. 2025. PMC →

1988 | FEBS Letters | In Vitro

GHK-Cu stimulates collagen synthesis in fibroblast cultures with activity beginning at 10⁻¹² M

Maquart et al. reported the foundational characterisation of GHK-Cu's effect on collagen synthesis in human fibroblast cultures. Collagen stimulation began at concentrations between 10⁻¹² and 10⁻¹¹ M, maximised at 10⁻¹ M, and was independent of any change in cell number - confirming the effect was on collagen production per cell rather than cell proliferation. The presence of a GHK triplet sequence in the alpha-2(I) chain of type I collagen led the authors to propose that GHK may be naturally liberated by proteases at wound sites, acting as an in situ repair signal. This study established GHK-Cu as a collagen synthesis stimulant and initiated four decades of tissue repair research on the compound.

Maquart FX, Pickart L, Laurent M, Gillery P, Monboisse JC, Borel JP. FEBS Lett. 1988;238(2):343-346. PubMed →

2018 | Frontiers in Pharmacology | Review / Gene Expression Analysis

GHK-Cu modulates over 4,000 human genes and exerts protective actions across multiple tissue systems

Pickart and Margolina synthesised the genomic and pharmacological literature on GHK-Cu, drawing on gene expression databases to identify the breadth of GHK's regulatory influence. GHK was found to modulate expression of more than 4,000 human genes, including those involved in collagen and elastin synthesis, angiogenesis, metalloproteinase regulation, anti-inflammatory signalling, DNA repair, antioxidant response, and cell cleansing via the proteasome system. The authors highlighted GHK's ability to suppress NFkB (a key driver of inflammation-associated ageing) and its neuroprotective effects in cognitive ageing models. The review characterised GHK as a naturally occurring systemic repair signal that declines with age, making its restoration a target of interest in ageing biology research.

Pickart L, Margolina A. Front Pharmacol. 2018;9:438. PubMed →

2021 | Nature Communications | Animal Study + Human Observation

MOTS-C is an exercise-induced mitochondrial-encoded regulator of age-dependent physical decline and muscle homeostasis

Reynolds et al. published the landmark characterisation of MOTS-C as an exercise-regulated mitochondrial peptide with direct effects on ageing. In mice, MOTS-C administration significantly enhanced physical performance across young (2 months), middle-aged (12 months), and old (22 months) subjects. Late-life treatment (initiated at 23.5 months) increased physical capacity and healthspan. In human subjects, exercise induced MOTS-C expression in skeletal muscle by 11.9-fold and in circulation by 1.5-fold. MOTS-C was shown to regulate nuclear genes related to metabolism and proteostasis, improve skeletal muscle glucose and amino acid metabolism, and enhance myoblast adaptation to metabolic stress. The study established MOTS-C as the first mitochondrially encoded peptide demonstrated to actively regulate physical ageing, and provided the human physiological evidence for its role as an exercise-induced metabolic signal whose endogenous levels decline with age.

Reynolds JC, et al. Nat Commun. 2021;12(1):470. PubMed →

2015 | Cell Metabolism | Animal Study

MOTS-C promotes metabolic homeostasis and reduces obesity and insulin resistance via AMPK pathway

Lee et al. characterised MOTS-C's metabolic effects in the foundational study establishing this peptide's role in metabolism. MOTS-C was shown to act primarily through the Folate-AICAR-AMPK pathway, increasing glucose uptake and stimulating glycolysis in skeletal muscle. In high-fat diet mice, MOTS-C prevented weight gain, reduced insulin resistance, and improved metabolic parameters without caloric restriction. The peptide regulated nuclear gene expression by translocating from mitochondria to the nucleus under stress conditions, identifying it as a novel retrograde mitochondrial-to-nuclear signal. The study's framing of MOTS-C as an "exercise mimetic" - a compound that activates the same metabolic pathways induced by physical activity via AMPK - established the basis for its investigation in ageing-related metabolic decline.

Lee C, et al. Cell Metab. 2015;21(3):443-454. PubMed →

Every Longevity Stack ships with a single batch-specific Certificate of Analysis from an independent third-party analytical laboratory, covering all three compounds. The COA confirms identity, purity by HPLC, and absence of contaminants for Epithalon, GHK-Cu, and MOTS-C in your batch.

All three compounds are supplied as lyophilised (freeze-dried) solids. Bacteriostatic water is required for reconstitution of all three vials and is available separately. Storage specifications below apply to all compounds in the stack.

Temperature: -20°C Long-term storage. For short-term use (up to 4 weeks), 2-8°C is acceptable.

Light Sensitivity: Light-Sensitive. Store in original opaque vial. Avoid direct UV or prolonged exposure to light.

Shelf Life: 24 Months. Lyophilized, sealed, stored at -20°C. Batch expiry printed on vial label.

Allow sealed vials to reach room temperature before opening to minimise moisture introduction. Bacteriostatic water is supplied ready to use - no preparation required.
Use the included bacteriostatic water as reconstitution solvent. Add solvent slowly down the inside wall of the vial - do not inject directly onto the lyophilised cake.
Gently swirl each vial until fully dissolved. Do not vortex or shake vigorously. Both compounds dissolve readily in BAC water.
Once reconstituted, store at 2-8°C. Use within 28 days. Do not freeze reconstituted solution.
Discard if solution appears cloudy, discoloured, or contains particulate matter.

Epithalon, GHK-Cu, and MOTS-C supplied by Pure Grade Labs are intended exclusively for in vitro research and laboratory use. None of these products are approved for human or veterinary use by any regulatory authority, including the FDA, MHRA, TGA, or EMA.

These products are not drugs, medicines, or supplements and must not be used as such.
Pure Grade Labs makes no claims regarding therapeutic or clinical efficacy in humans for any of the three compounds in this stack.
These products must not be administered to humans or animals outside of a licensed research context.
MOTS-C is the first mitochondrial-derived peptide to enter clinical trials - this does not constitute approval and does not change the research-use classification of this supply.
All three compounds may be prohibited in sport under applicable WADA categories. Athletes subject to drug testing should verify current classifications before ordering.
Purchasers are solely responsible for compliance with all applicable laws and regulations in their jurisdiction.

All research summaries and study citations on this page are provided for informational context only and do not constitute medical advice, endorsement of any treatment, or recommendation for human use.