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Research Areas

1. Anti-aging Research

Focus:

This research area explores peptides that may be involved in cellular rejuvenation, oxidative stress resistance, mitochondrial function, and telomere maintenance. Scientists are examining various peptides for their potential to interact with biological pathways associated with aging, metabolic efficiency, and cellular repair mechanisms.

Current research is investigating how peptides may influence autophagy, DNA repair, and proteostasis, which are fundamental processes in cellular maintenance and longevity studies. Peptides are also being studied in laboratory settings for their role in modulating inflammatory markers, mitochondrial biogenesis, and senescence-associated secretory phenotypes (SASP), all of which are areas of interest in aging-related research.

Additionally, scientists are exploring how peptides might contribute to the regulation of NAD+ levels, antioxidant defenses, and metabolic homeostasis, as these factors play a role in mitochondrial energy dynamics and the overall cellular response to age-related stressors. Research continues to expand on how peptides function within growth factor pathways, extracellular matrix maintenance, and tissue remodeling, shedding light on potential molecular interactions in longevity research.

Core Peptides:

  • Epithalon – Investigated for its potential role in telomere-related research and cellular homeostasis.
  • Thymosin Beta-4 (Coming Soon) – Studied for its involvement in cellular migration and tissue repair processes.
  • GHK-Cu – Examined for its influence on extracellular matrix remodeling and antioxidant mechanisms.
  • NAD+ – Researched in the context of mitochondrial function and oxidative stress resistance.
  • MOTS-C (Coming Soon) – Studied for its role in mitochondrial regulation and metabolic adaptation.

Core Blends (Coming Soon):

  • GHK-Cu/Epithalon
  • BPC-157/GHK-Cu/TB-500 (“GLOW”)
  • BPC-157/GHK-Cu/TB-500/Thymosin Alpha-1 (“GLOW-Plus”)
2. Cognitive & Neuro Research

Focus:

This research area examines peptides that may play a role in neuromodulation, synaptic plasticity, and neuroprotection. Scientists are investigating how peptides interact with cognitive processes, neurochemical signaling, and stress-related pathways to better understand their potential roles in neurological research.

Current studies are focused on the potential regulation of neurotransmitter activity, neuronal repair mechanisms, and oxidative stress resistance. Researchers are particularly interested in how peptides may influence brain-derived neurotrophic factors (BDNF), glial cell interactions, and mitochondrial function in models of cognitive function and neurobiology.

Peptides in this category are also being explored for their potential involvement in circadian rhythm regulation, hypothalamic-pituitary-adrenal (HPA) axis response, and neuroinflammatory pathways. Further research aims to uncover molecular mechanisms related to learning processes, stress adaptation, and synaptic network integrity in laboratory settings.

Core Peptides:

  • Cerebrolysin (Coming Soon) – Investigated for its potential role in neurotrophic factor research and synaptic plasticity.
  • Selank (Coming Soon) – Studied for its interaction with stress response pathways and neurotransmitter modulation.
  • Epithalon – Examined for its involvement in oxidative stress research and cellular maintenance.
  • MOTS-C (Coming Soon) – Researched for its role in mitochondrial regulation and metabolic efficiency.
  • DSIP – Explored in studies related to circadian rhythm and sleep cycle regulation.
  • Semax (Coming Soon) – Investigated for its effects on neuroprotection and synaptic activity.
  • Oxytocin – Studied for its role in neurochemical signaling and social cognition research.

Core Blends (Coming Soon):

  • GHK-Cu/Epithalon
  • IGF-1 LR3/MOTS-C
3. GLP Research

Focus:

This research area investigates peptides involved in metabolic regulation, glucose homeostasis, and appetite signaling. Scientists are exploring how these peptides interact with pancreatic hormone secretion, lipid metabolism, and neuroendocrine pathways to influence energy balance and systemic metabolic health.

Recent studies have highlighted their potential roles in improving insulin sensitivity, modulating gastric emptying, and influencing satiety signaling through the gut-brain axis. Additionally, emerging research suggests that these peptides may contribute to weight regulation by affecting adipose tissue activity, metabolic rate, and the body’s ability to adapt to changes in caloric intake.

Beyond metabolic effects, some studies have begun to explore how metabolic peptides may influence musculoskeletal function, including body posture correction and movement efficiency. By improving weight distribution and energy utilization, researchers are investigating whether these compounds play a role in postural adaptation, mobility, and biomechanical balance.

The appeal of this research category lies in its intersection with multiple physiological systems, including neuroendocrine signaling, mitochondrial function, and metabolic adaptation. As researchers continue to explore these mechanisms, new insights are emerging into how metabolic peptides may contribute to long-term metabolic flexibility, musculoskeletal health, and overall physical resilience in controlled research environments.

Current Research Peptides:

  • AOD9604 – Investigated for its role in peptide-based research on lipid metabolism and fat utilization.
  • GLP Peptides – Studied for their involvement in metabolic signaling pathways, appetite regulation, and energy homeostasis. 
4. Growth Hormone Research

Focus:

This research area examines peptides that may be involved in hormonal signaling, endocrine regulation, and metabolic homeostasis. Scientists are studying how peptides interact with growth hormone-releasing pathways, pituitary function, and neuroendocrine feedback mechanisms to better understand their roles in hormonal research.

Current investigations focus on peptide-mediated regulation of growth factor expression, hypothalamic-pituitary communication, and anabolic signaling pathways. Researchers are exploring how peptides may influence hormone secretion dynamics, receptor activation, and intracellular signaling cascades within controlled research environments.

Additional studies are being conducted on how these peptides interact with circadian rhythm regulation, metabolic adaptation, and cellular stress responses to expand scientific knowledge in the field of endocrine research. The role of peptide-receptor binding, feedback inhibition, and secretagogue activity continues to be a key focus of laboratory research.

Core Peptides:

  • Tesamorelin – Investigated for its role in research related to growth hormone-releasing hormone (GHRH) pathways.
  • CJC-1295 (DAC & No DAC) – Studied for its potential impact on growth hormone pulsatility and secretion patterns.
  • Ipamorelin – Examined in research exploring ghrelin receptor activation and secretagogue function.
  • Hexarelin – Researched for its interaction with growth hormone release pathways and pituitary response.

Core Blends (Coming Soon):

  • Tesamorelin/Ipamorelin
5. Immune & Inflammatory Research

Focus:

This research area explores peptides that may be involved in immune system modulation, cellular defense mechanisms, and inflammatory response regulation. Scientists are studying how peptides interact with cytokine signaling, immune cell activity, and oxidative stress pathways to better understand their potential roles in immune-related research.

Ongoing studies examine how peptides may influence T-cell and B-cell activity, macrophage function, and immunomodulatory responses. Researchers are also investigating peptide-mediated pathways related to inflammation resolution, antioxidant defense mechanisms, and cellular repair processes within controlled research settings.

Further exploration is being conducted into the interplay between peptides, microbiome interactions, and immune homeostasis to better understand their role in immune signaling networks and inflammatory biomarker regulation.Research continues to expand on how peptides may be involved in tissue recovery, immune cell communication, and adaptive immune responses in laboratory models.

Core Peptides:

  • Thymosin Alpha-1 – Investigated for its role in research related to T-cell activity and immune regulation.
  • BPC-157 – Studied for its potential role in tissue repair mechanisms and inflammatory response modulation.
  • TB-500 – Examined for its involvement in cell migration, repair processes, and inflammation research.
  • Thymosin Beta-4 (Coming Soon) – Researched for its potential role in cellular regeneration and immune signaling.
  • LL-37 – Studied for its role in antimicrobial peptide research and immune defense mechanisms.
  • Epithalon – Examined in studies related to oxidative stress and cellular maintenance.
  • Glutathione – Researched for its role in antioxidant mechanisms and redox balance in immune response studies.

Core Blends (Coming Soon):

  • BPC-157/TB-500
  • BPC-157/GHK-Cu/TB-500 (“GLOW”)
  • BPC-157/GHK-Cu/TB-500/Thymosin Alpha-1 (“GLOW-Plus”)
6. Libido & Reproductive Research

Focus:

This research area explores peptides that may be involved in hormonal signaling, reproductive function, and neuroendocrine regulation related to sexual behavior. Scientists are studying how peptides interact with hypothalamic-pituitary-gonadal (HPG) axis dynamics, neuropeptide signaling, and receptor-mediated pathways to better understand their potential roles in reproductive and sexual health research.

Current investigations focus on peptide interactions with gonadotropin-releasing hormone (GnRH) pathways, oxytocinergic signaling, and melanocortin receptor activation. Researchers are examining how peptides may influence hormone secretion patterns, neurochemical activity, and sensory processing in laboratory models.

Additional studies are being conducted on the relationship between peptides and neuroendocrine feedback loops, libido-associated neurotransmitter pathways, and reproductive system responses. Research continues to explore the molecular mechanisms behind sexual motivation, arousal signaling, and fertility-related peptide activity in controlled experimental settings.

Core Peptides:

  • PT-141 (Coming Soon) – Investigated for its role in research related to melanocortin receptor activation and neurochemical pathways.
  • Kisspeptin-10 – Studied for its involvement in GnRH regulation and reproductive hormone signaling.
  • Oxytocin – Examined for its role in social bonding, neuroendocrine modulation, and sensory perception research.
  • Melanotan-2 – Researched for its potential role in melanocortin pathway signaling and hypothalamic regulation
7. Skin & Hair Research

Focus:

This research area explores peptides that may play a role in skin regeneration, collagen synthesis, wound healing, pigmentation, and hair follicle activity. Scientists are studying various peptides for their ability to influence extracellular matrix remodeling, fibroblast activity, and melanogenesis, which are critical processes for maintaining skin elasticity, barrier function, and pigmentation balance.

Additionally, peptides are being investigated for their potential interactions with growth factors and signaling pathwaysinvolved in hair follicle cycling, scalp health, and dermal papilla cell function. Studies aim to better understand how peptides may support keratinocyte proliferation, angiogenesis, and inflammatory modulation in skin and hair research.

Researchers continue to explore how peptides might be leveraged in laboratory settings for studies on oxidative stress resistance, cellular repair mechanisms, and the role of bioactive molecules in aging-related skin and hair changes.These investigations are essential in expanding scientific knowledge about peptide-based mechanisms related to cellular longevity, skin hydration, and follicular regeneration.

Core Peptides:

  • GHK-Cu – A copper-binding peptide studied for its potential role in collagen production, skin remodeling, and cellular regeneration.
  • Epithalon – Investigated for its possible involvement in cellular aging mechanisms and oxidative stress response.
  • Thymosin Beta-4 (Coming Soon) – Examined for its potential impact on cellular migration, wound healing, and skin recovery.
  • Melanotan-2 – Researched for its role in melanogenesis and pigmentation pathways.
  • BPC-157 – Explored for its potential role in tissue repair, wound healing, and inflammation modulation.

Core Blends (Coming Soon):

  • GHK-Cu/Epithalon
  • BPC-157/GHK-Cu/TB-500 (“GLOW”)
  • BPC-157/GHK-Cu/TB-500/Thymosin Alpha-1 (“GLOW-Plus”)