BPC-157: Peptide for Tissue Repair
Overview of BPC-157: Peptide for Tissue Repair
- Unit Size: | 10 mg/vial
- Unit Quantity: | 1 Vial
- Sequence: | Gly- Glu-Pro-Pro-Pro-Gly-Lys-Pro-Ala-Asp-Asp-Ala-Gly-Leu-Val
- Appearance: | White Powder
- Peptide Purity: | >98.1%
- Solubility: | Soluble in water or 1% acetic acid
BPC-157 is a synthetic peptide, often referred to in research as a tissue repair compound, is a promising subject in biomedical studies, particularly for its potential in supporting tissue regeneration and healing. Formally known as Body Protection Compound-157, this engineered peptide is derived from a naturally occurring protein in the digestive system and known by various designations in scientific literature including Bepecin, PL 14736 and PL-10, reflecting its broad application in healing-related research.
This peptide is a stable, synthetically designed molecule with a structure tailored to mimic the regenerative properties observed in the gastrointestinal system. Its chemical composition enhances its durability and efficacy, overcoming common issues such as rapid breakdown and limited bioavailability seen in naturally occurring peptides.
A key focus of research on BPC-157 is its interaction with the Nitric Oxide (NO) pathway, which plays a vital role in tissue repair and wound healing. Nitric Oxide regulates blood vessel function, supports endothelial health, and promotes the formation of new blood vessels. By engaging this pathway, the peptide supports processes like endothelial cell growth, blood vessel development, and improved circulation, all of which contribute to effective tissue repair and regeneration.
Beyond its vascular effects, BPC-157 shows potential in supporting the recovery of various tissues, including joints and connective tissues. Studies suggest it may enhance ligament and tendon health, improve joint flexibility, and strengthen connective tissues. These benefits are believed to be due to the peptide's influence on collagen synthesis, extracellular matrix restructuring, and inflammation modulation, fostering an environment conducive to tissue repair & recovery.