Peptides

BPC-157 peptide is a synthetic pentadecapeptide derived from a protective protein found in gastric tissue. The BPC-157 peptide belongs to a class of regenerative peptides studied in peptide research for their role in tissue repair, cellular signaling, and inflammatory pathway regulation. Researchers investigate the BPC-157 peptide to better understand how regenerative peptides influence biological processes such as tissue regeneration, muscle physiology, and cellular recovery. Because peptides such as the BPC-157 peptide interact with pathways involved in tissue repair and inflammatory signaling, this peptide has become an important subject of research in studies related to regenerative peptides, gastrointestinal biology, and peptide-based healing mechanisms.

Ipamorelin peptide is a synthetic growth hormone–releasing peptide studied in peptide research for its interaction with ghrelin receptors involved in growth hormone signaling. The Ipamorelin peptide belongs to a class of regulatory peptides known as growth hormone secretagogues, which influence endocrine signaling pathways related to growth hormone release. Researchers investigate the Ipamorelin peptide to better understand how peptides that target ghrelin receptors affect metabolic regulation, muscle physiology, and hormonal signaling pathways. Because peptides such as the Ipamorelin peptide interact with growth hormone pathways, this peptide has become an important subject of research in studies focused on metabolism, recovery, and peptide-based endocrine regulation.

SS-31 peptide (also known as elamipretide peptide) is a synthetic mitochondrial-targeting peptide studied in peptide research for its interaction with mitochondrial membranes and cellular energy pathways. The SS-31 peptide belongs to a class of regulatory mitochondrial peptides designed to influence mitochondrial function and oxidative stress pathways. Researchers investigate the SS-31 peptide to better understand how mitochondrial peptides affect cellular energy metabolism, mitochondrial signaling, and oxidative damage responses. Because peptides such as the SS-31 peptide interact with mitochondrial membranes and bioenergetic processes.

TB-500 peptide is a synthetic peptide derived from thymosin beta-4, a naturally occurring regulatory peptide involved in cellular migration and tissue repair. The TB-500 peptide is widely studied in peptide research because peptides related to thymosin beta-4 play an important role in cellular regeneration and tissue remodeling. Researchers investigate the TB-500 peptide to better understand how regenerative peptides influence cell migration, tissue repair, and inflammatory signaling pathways. Because peptides such as the TB-500 peptide participate in biological processes related to recovery and regeneration, this peptide has become an important subject of research in studies focused on regenerative peptides, muscle physiology, and tissue repair mechanisms.

KPV peptide is a synthetic tripeptide derived from the alpha-melanocyte-stimulating hormone (α-MSH) sequence. The KPV peptide belongs to a class of regulatory peptides studied in peptide research for their role in inflammatory signaling and immune system regulation. Researchers investigate the KPV peptide to better understand how anti-inflammatory peptides influence cytokine signaling pathways and immune responses. Because peptides such as the KPV peptide interact with inflammatory pathways, this peptide has become an important subject of research in studies focused on immune regulation, inflammatory diseases, and peptide-based immune signaling.

Tirzepatide peptide is a synthetic dual-incretin peptide studied in peptide research for its interaction with GLP-1 and GIP receptors involved in metabolic regulation. The Tirzepatide peptide belongs to a class of regulatory metabolic peptides that influence glucose metabolism, insulin signaling, and energy balance. Researchers investigate the Tirzepatide peptide to better understand how incretin peptides affect metabolic pathways related to glucose control, fat metabolism, and endocrine signaling. Because peptides such as the Tirzepatide peptide interact with multiple metabolic hormone receptors, this peptide has become an important subject of research in studies focused on obesity, metabolic disorders, and peptide-based metabolic therapies.

GHK-Cu peptide is a copper-binding peptide belonging to a class of regulatory peptides studied in peptide research for their role in skin biology, tissue repair, and cellular signaling. The GHK-Cu peptide is a naturally occurring copper peptide that forms when the GHK peptide binds with copper ions. In peptide research, GHK-Cu peptides are widely studied for their interaction with biological pathways related to collagen production, tissue regeneration, and skin health. Because copper peptides such as the GHK-Cu peptide influence cellular repair mechanisms, this peptide has become an important subject of research in studies related to regenerative peptides, skin biology, and peptide-based tissue repair.

LL-37 peptide is a synthetic antimicrobial peptide belonging to the cathelicidin family of host-defense peptides. The LL-37 peptide is widely studied in peptide research because antimicrobial peptides such as the LL-37 peptide play an important role in immune defense and inflammatory signaling pathways. Researchers investigate the LL-37 peptide to better understand how host-defense peptides interact with immune cells, microbial membranes, and infection-related pathways. Because peptides such as the LL-37 peptide are involved in innate immune responses, this peptide has become an important subject of research in studies related to antimicrobial peptides, immune regulation, and inflammatory signaling.

Test results for -> RETARUTIDE

Retatrutide peptide is a synthetic multi-receptor metabolic peptide studied in peptide research for its interaction with GLP-1, GIP, and glucagon receptors involved in metabolic signaling. The Retatrutide peptide belongs to a class of regulatory metabolic peptides designed to influence energy balance, glucose metabolism, and fat metabolism pathways. Researchers investigate the Retatrutide peptide to better understand how multi-agonist peptides affect metabolic regulation and weight management mechanisms. Because peptides such as the Retatrutide peptide interact with several metabolic hormone receptors, this peptide has become an important subject of research in studies focused on obesity, metabolic health, and peptide-based metabolic therapies.

Sermorelin peptide is a synthetic growth hormone–releasing hormone (GHRH) peptide studied in peptide research for its ability to stimulate the natural release of growth hormone from the pituitary gland. The Sermorelin peptide belongs to a class of regulatory peptides that influence the growth hormone signaling pathway and endocrine regulation. Researchers investigate the Sermorelin peptide to better understand how GHRH peptides affect metabolic regulation, muscle physiology, and hormonal signaling. Because peptides such as the Sermorelin peptide influence growth hormone pathways, this peptide has become an important subject of research in studies related to metabolism, recovery, and peptide-based endocrine regulation.

Test results for -> TESAMORELIN

Tesamorelin peptide is a synthetic growth hormone–releasing hormone (GHRH) peptide studied in peptide research for its interaction with endocrine signaling pathways that regulate growth hormone secretion. The Tesamorelin peptide belongs to a class of regulatory peptides that influence the growth hormone axis and metabolic signaling. Researchers investigate the Tesamorelin peptide to better understand how GHRH peptides affect metabolic regulation, fat metabolism, and hormonal signaling pathways. Because peptides such as the Tesamorelin peptide influence growth hormone pathways, this peptide has become an important subject of research in studies focused on metabolism, endocrine signaling, and peptide-based hormonal regulation.

MOTS-C (Mitochondrial Open Reading Frame of the 12S rRNA-c) is a mitochondrial-derived peptide (MDP) encoded within the mitochondrial genome. It is extensively researched for its potential to enhance metabolic flexibility, promote fat loss, improve insulin sensitivity, and support longevity by regulating cellular energy metabolism. MOTS-C is a promising candidate in studies focused on obesity, type 2 diabetes, aging, and exercise performance.

This product is intended solely for research purposes and is not for human or animal consumption.