Description
Sermorelin + GHRP-6 + GHRP-2 Blend (9mg)
For Research Use Only. Not for Human or Animal Consumption.
The Triple-Action Research Standard
You’re looking at a serious research tool. This isn’t a single-compound vial. It’s a 9mg blend of three distinct, high-purity peptides—Sermorelin, GHRP-6, and GHRP-2—designed for one purpose: to give your laboratory model a comprehensive look at growth hormone (GH) signaling from multiple, simultaneous angles. Think of it as running three precise experiments in one controlled system. If your work involves the somatotropic axis, ghrelin pathways, or receptor-level endocrine signaling, this blend provides a defined framework you can’t get from solo compounds.
We mix this here in the USA under strict, sterile conditions. Every batch gets third-party verified for purity, potency, and sterility. You get the data sheet with it. No guesswork, just a reliable research chemical that does what the label says.
What This Blend Is For (The Short Version)
In a controlled lab setting, this combination allows for the study of integrated signaling. Each peptide hits a different receptor target. Sermorelin is a GHRH analogue. GHRP-6 and GHRP-2 are both GHS-R1a agonists, but they don’t act identically. By introducing all three, you can observe receptor convergence, signal amplification, and potential feedback mechanisms in your model. It’s for examining how these pathways talk to each other, not just how one acts alone. The research implications are focused on mechanistic biology within neuroendocrine networks.
Breakdown of the Components
Here’s what you’re working with. Know your materials.
Sermorelin (GHRH(1-29)NH2)
- Target: Growth Hormone-Releasing Hormone Receptor (GHRH-R).
- Primary Research Action: Binds to the classic GHRH receptor. In models, this typically triggers the cAMP/PKA signaling pathway. It’s the direct route, mimicking the body’s primary GH-releasing signal.
- Molecular Formula: C149H246N44O42S
- Molecular Weight: 3357.9 g/mol
GHRP-6 (Growth Hormone Releasing Peptide-6)
- Target: Ghrelin Receptor (GHS-R1a).
- Primary Research Action: Potent GHS-R1a agonist. Research indicates its signaling heavily involves the PLC/IP3 pathway, leading to intracellular calcium mobilization. Notably, some studies suggest it does not significantly elevate cAMP in somatotroph models, providing a distinct signaling profile.
- Molecular Formula: C46H56N12O6
- Molecular Weight: 873.0 g/mol
GHRP-2 (Pralmorelin)
- Target: Ghrelin Receptor (GHS-R1a).
- Primary Research Action: Another potent GHS-R1a agonist, but with a different structure than GHRP-6. Key research difference: In some pituitary cell models, GHRP-2 has been shown to elevate cAMP levels, similar to GHRH, while also activating the PLC pathway. This makes it a useful comparative tool against GHRP-6 for studying ligand-specific signaling bias at the same receptor.
- Molecular Formula: C45H55N9O6
- Molecular Weight: 818.0 g/mol
Key Research Applications & Considerations
This blend is for in-vitro or controlled preclinical research. Here’s where it adds value to a study design:
- Comparative Signaling Studies: Directly compare the downstream effects of GHRH receptor activation vs. GHS-R1a activation in the same system.
- Receptor Crosstalk: Investigate how simultaneous stimulation of both major GH-release pathways (GHRH and Ghrelin) affects signal integration, amplification, or feedback.
- Ligand Bias Analysis: Use GHRP-6 and GHRP-2 together to probe how different agonists at the GHS-R1a can produce different intracellular effects (e.g., calcium flux vs. cAMP elevation).
- Gene Expression Profiling: Study the combined impact on mRNA levels for GH, transcription factors (like Pit-1), and receptor subtypes in responsive cell cultures.
Important Note: Research suggests the effects of GHRP-2 and GHRP-6 can be additive on GH secretion in some models, but their intracellular signaling pathways show distinct characteristics. This blend lets you dig into that complexity.
Why Source This From PeptideMarketUSA?
This isn’t a hobby. Your research depends on consistency. Here’s ours:
- Made Here, Tested Here: Synthesized
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