AOD 9604 5mg Peptides

AOD 9604 Peptides: Research Uses, Structure, Benefits & Storage Guide

AOD 9604 peptides are synthetic fragments derived lfrom the human growth hormone (HGH 176-191) region. They are widely studied in scientific and laboratory research for their role in lipid metabolism, fat oxidation pathways, and anti-lipogenic activity. Due to their targeted structure, AOD 9604 peptides have become popular in metabolic and obesity-related research models.

For research and laboratory use only. Not intended for human or veterinary diagnosis or treatment.

What Are AOD 9604 Peptides?

AOD 9604 is a modified peptide fragment of the C-terminal region of human growth hormone (HGH). Unlike full-length HGH, AOD 9604 peptides are designed to focus specifically on fat metabolism signaling pathways without stimulating overall growth hormone secretion or IGF-1 production in research settings.

Key characteristics:

• Fragment of HGH (amino acids 176–191)
• Synthetic, lab-grade peptide
• Studied for lipid metabolism regulation
• Does not mimic full HGH systemic activity

How AOD 9604 Peptides Work (Mechanism of Action)

In laboratory studies, AOD 9604 peptides have shown activity in two major metabolic pathways:

1. Lipolysis Activation

AOD 9604 is researched for its ability to stimulate fat breakdown pathways by activating hormone-sensitive lipase (HSL) and related enzymes.

2. Lipogenesis Inhibition

The peptide is also studied for its potential to inhibit the formation of new fat cells by suppressing acetyl-CoA carboxylase and fatty acid synthase activity.

This dual-action profile makes AOD 9604 peptides unique compared to traditional growth hormone fragments.

AOD 9604 Peptides vs Human Growth Hormone (HGH)

Feature	AOD 9604 Peptides	Full HGH
Structure	Fragment (176-191)	191 amino acids
IGF-1 Stimulation	Minimal (research data)	Strong
Primary Research Focus	Fat metabolism	Growth & regeneration
Side Effects	Limited in studies	Broader hormonal effects

Research Applications of AOD 9604 Peptides

AOD 9604 peptides are commonly used in:

• Obesity and metabolic disorder research
• Fat oxidation pathway studies
• Lipid storage regulation models
• Growth hormone fragment comparison studies
• Peptide receptor interaction research

Their specificity allows researchers to isolate fat-related mechanisms without the broader endocrine effects of full HGH.