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BPC-157 Capsules – High Purity Research Peptide (500mcg per capsule)
€190,00
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BPC 157 Peptide Research Overview
BPC-157 is a synthetic pentadecapeptide originally characterized in experimental studies as a stable fragment derived from gastric protective proteins. In laboratory research, it is widely examined as a multi-pathway signaling peptide due to its interaction with cellular repair mechanisms, vascular signaling systems, and inflammatory modulation pathways.
Rather than focusing on a single molecular target, BPC-157 is studied for its broad regulatory behavior across connective tissue, endothelial function, and neurochemical signaling under controlled experimental conditions.
Key Molecular Research Context
Experimental literature describes BPC-157 as interacting with multiple intracellular and extracellular signaling pathways, including:
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modulation of fibroblast activity and extracellular matrix dynamics
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regulation of angiogenic signaling via VEGF-associated pathways
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influence on nitric oxide–related signaling involved in vascular homeostasis
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participation in cellular stress response and survival signaling cascades
These characteristics make BPC-157 a commonly referenced peptide in laboratory models examining tissue repair signaling, vascular adaptation, and inflammation-related processes.
Experimental Models Referenced in Research
In controlled laboratory environments, BPC-157 has been incorporated into experimental models exploring:
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connective tissue signaling in tendon, ligament, and muscle research
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gastrointestinal cytoprotection and endothelial stability models
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vascular integrity and angiogenesis under stress conditions
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neurochemical signaling pathways, including serotonergic and dopaminergic systems
These studies focus on mechanistic observation, not therapeutic application, and are designed to explore how peptide-mediated signaling influences complex biological systems.
Capsule Format in Research Settings
The capsule format of BPC-157 is commonly referenced in research discussions comparing different laboratory delivery formats, allowing investigators to evaluate stability, handling characteristics, and experimental consistency across study designs.
For a comprehensive scientific background on BPC-157, including its origin and broader research classification, see:
➝ What is BPC-157? – Research Overview
➝ BPC-157: Oral vs Injection – Research Perspectives
➝ Best Peptides for Muscle and Tendon Recovery
Product Description:
- Synonyms: Body Protection Compound 15, Bepecin, L-Valine, glycyl-L-alpha-glutamyl-L-prolyl-L-prolyl-L-prolylglycyl-L-lysyl-L-prolyl-L-alanyl-L-alpha-aspartyl-L-alpha-aspartyl-L-alanylglycyl-L-leucyl-
- Molar Mass: 1419.5 g/mol
- CAS Number: 137525-51-0
- PubChem: 994195
- Total Active Ingredient: 60000mcg (500mcg per capsule)
- Shelf Life: 36 months
BPC-157 Structures:
Sources PubChem
Product Usage
This item is supplied for research purposes only.
Peptide Storage
All information provided by PRG is for educational and informational purposes only.
Best Practices for Storing Peptides
To maintain the reliability of laboratory results, correct peptide storage is essential. Proper storage conditions help preserve peptide stability for years while protecting against contamination, oxidation, and breakdown. Although certain peptides are more sensitive than others, following these best practices will greatly extend their shelf life and structural integrity.
- Short-Term Storage (days to months): Keep peptides cool and protected from light. Temperatures below 4 °C (39 °F) are generally suitable. Lyophilized peptides often remain stable at room temperature for several weeks, but refrigeration is still preferred if use is not immediate.
- Long-Term Storage (months to years): Store peptides at –80 °C (–112 °F) for maximum stability. Avoid frost-free freezers, as defrost cycles can cause damaging temperature fluctuations.
- Minimize Freeze–Thaw Cycles: Repeated freezing and thawing accelerates degradation. Instead, divide peptides into aliquots before freezing.
Preventing Oxidation & Moisture Damage
Peptides can be compromised by exposure to moisture and air—especially immediately after removal from a freezer.
- Let the vial warm to room temperature before opening to prevent condensation.
- Keep containers sealed as much as possible, and if possible, reseal under a dry, inert gas such as nitrogen or argon.
- Amino acids like cysteine (C), methionine (M), and tryptophan (W) are particularly sensitive to oxidation.
Storing Peptides in Solution
Peptides in solution have a much shorter lifespan compared to lyophilized form and are prone to bacterial degradation.
- If storage in solution is unavoidable, use sterile buffers at pH 5–6.
- Prepare single-use aliquots to avoid repeated freeze–thaw cycles.
- Most peptide solutions are stable for up to 30 days at 4 °C (39 °F), but sensitive sequences should remain frozen when not in use.
Containers for Peptide Storage
Select containers that are clean, intact, chemically resistant, and appropriately sized for the sample.
- Glass vials: offer clarity, durability, and chemical resistance.
- Plastic vials: polystyrene (clear but less resistant) or polypropylene (translucent but chemically resistant).
- Peptides shipped in plastic vials may be transferred to glass for long-term storage if desired.
Regenesis Peptide Storage Quick Tips
- Keep peptides in a cold, dry, dark environment
- Avoid repeated freeze–thaw cycles
- Minimize exposure to air
- Protect from light
- Avoid storing in solution long term
- Aliquot peptides to match experimental needs