BPC-157 + TB-500 Blend 10mg
CAS: 137525-51-0, 77591-33-4
BPC-157 + TB-500 Blend 10mg from Bio-Peptides is a premium dual-peptide research formulation identified by CAS 137525-51-0 and CAS 77591-33-4. Manufactured using Solid-Phase Peptide Synthesis (SPPS) and validated through HPLC, Mass Spectrometry, and UV analysis, this blend achieves ≥99% purity and excellent batch consistency. Trusted by European laboratories, it supports reproducible in-vitro research focused on cellular signalling, protein-peptide interaction, and regenerative pathway investigation.
$195.00
Research Use Only
Advanced Research Peptide Blend Overview
BPC-157 + TB-500 Blend 10mg is a specialised dual-peptide research formulation supplied by Bio-Peptides for precision in-vitro experimentation.
The blend combines two well-characterised synthetic peptides under tightly controlled production conditions to ensure batch-to-batch uniformity.
Identified by CAS 137525-51-0 (BPC-157) and CAS 77591-33-4 (TB-500), the product meets traceability and documentation requirements expected by European research laboratories.
Scientific Context and Research Relevance
Synthetic peptide blends are valuable tools in modern biochemical and molecular research due to their ability to influence multiple pathways simultaneously.
The BPC-157 + TB-500 Blend is frequently selected for studies involving cellular signalling behaviour, protein-peptide interactions, and regenerative model exploration.
Blended formulations allow researchers to evaluate interaction effects, signal amplification, and pathway modulation under controlled conditions.
European laboratories increasingly prefer blend formats to reduce handling variability and improve experimental consistency.
Mechanistic Research Characteristics
- Modulation of intracellular signalling pathways in controlled in-vitro systems
- Influence on growth factor sensitivity and molecular activation cascades
- Regulation of gene expression patterns in peptide-based research models
- Interaction with mitochondrial ATP dynamics and metabolic pathways
- Support of enzymatic response analysis and pathway-driven research designs
Primary Research Applications
Synergistic Peptide Interaction Studies: Evaluating interaction effects and signal modulation between multiple peptide pathways.
Cellular Repair and Regeneration Research: Studying controlled cellular response behaviour in regenerative research models.
Angiogenesis and Vascular Signalling Models: Investigating peptide-mediated signalling related to vascular and angiogenic pathways.
Protein Expression and Receptor-Binding Studies: Analysing molecular interaction dynamics under defined laboratory conditions.
Mitochondrial and Metabolic Research: Assessing peptide blend influence on energy-related cellular processes.
Matrix Remodelling and Structural Assays: Exploring extracellular structure behaviour and peptide-driven cellular environments.
Molecular Composition and Characteristics
- Component 1: BPC-157 (synthetic pentadecapeptide)
- Component 2: TB-500 (thymosin beta-4 analogue)
- Structure: Linear peptide chains supplied as a blended formulation
- Stability: High when stored under recommended laboratory conditions
Molecular Stability and Storage Profile
- Supplied as a lyophilised powder for enhanced long-term stability
- Recommended storage: −20°C for extended research use
- Sensitive to moisture, oxygen, and prolonged light exposure
- Predictable degradation at elevated temperatures
- Reconstituted solutions remain stable for approximately 24–48 hours under refrigeration
Solubility and Reconstitution Considerations
- Bacteriostatic water
- Sterile saline solutions
- Acidic laboratory buffers
- Compatible analytical-grade organic solvents
Technical Specifications
product Name
BPC-157 + TB-500 Blend 10mg
cas
137525-51-0, 77591-33-4
purity
≥99% (HPLC verified)
unit Size
10 mg blended vial
form
Lyophilised peptide blend
synthesis
Solid-Phase Peptide Synthesis (SPPS)
analytical
HPLC, Mass Spectrometry, UV Spectrophotometry
molecular Structure
Linear synthetic peptide chains
stability
High under appropriate laboratory storage
Analytical Validation and Quality Assurance
- HPLC purity verification for each peptide component
- Mass Spectrometry confirmation of molecular identity
- UV spectrophotometric concentration analysis
- Batch consistency and reproducibility testing
- Endotoxin and microbial screening for regulated research environments
Regulatory and Research Compliance
BPC-157 + TB-500 Blend 10mg is supplied strictly for laboratory research and in-vitro scientific investigation. It is not approved as a drug, food, cosmetic, or medical product and is not intended for human or animal use. Certificates of Analysis (COA) and Material Safety Data Sheets (MSDS) are available upon request to support institutional compliance across EU jurisdictions.
Why European Laboratories Choose Bio-Peptides
Research institutions across Germany, France, Italy, Spain, the Netherlands, Belgium, Austria, Sweden, and Denmark rely on Bio-Peptides for consistent supply, transparent documentation, and high-purity research compounds. For laboratories seeking to buy peptides online with confidence, Bio-Peptides delivers reliability, traceability, and scientific integrity.
Frequently Asked Questions
It is used exclusively in laboratory research to study cellular signalling behaviour, protein-peptide interactions, and molecular pathway dynamics under controlled in-vitro conditions.
The blend contains CAS 137525-51-0 for BPC-157 and CAS 77591-33-4 for TB-500, ensuring full molecular traceability.
No. This product is strictly for laboratory research and is not approved for human, animal, or clinical use.
Store the lyophilised blend at −20°C, protected from light and moisture, to preserve molecular integrity.
Yes. Bio-Peptides supplies this blend to research facilities across Europe with full analytical documentation.
Purity and identity are verified using HPLC, Mass Spectrometry, and UV analysis before release.
Common solvents include bacteriostatic water, sterile saline, acidic buffers, and compatible analytical solvents.
Blended peptides allow researchers to observe interaction effects and pathway modulation with reduced handling variability and improved experimental consistency.