Research Use Disclaimer
All products referenced on this page are provided strictly for laboratory research, analytical testing, and scientific investigation.
They are not for human or veterinary use, not for consumption, injection, or administration, and are not intended to diagnose, treat, cure, mitigate, or prevent any disease.
All information presented below summarizes published scientific research, experimental observations, and mechanistic hypotheses derived from in-vitro and preclinical laboratory models. These findings do not establish safety, efficacy, or suitability for use outside of controlled research environments.
By accessing this page, you acknowledge responsibility for compliance with all applicable laws and regulations.
How to Use This Guide
This guide is designed to help researchers understand:
- What each compound is
- Why it is studied in scientific research
- What experimental outcomes have been observed
- What types of laboratory models are commonly used
No dosing, preparation, or administration instructions are provided.
NAD⁺ (Nicotinamide Adenine Dinucleotide)
NAD⁺ is a fundamental metabolic coenzyme studied extensively in cellular and mitochondrial research. Scientific literature examines its role in cellular energy transfer, redox balance, DNA repair signaling, and sirtuin-associated regulatory pathways.
Laboratory studies demonstrate that NAD⁺ availability influences cellular energy balance, metabolic efficiency, and oxidative stress response in experimental systems.
BPC-157 (Body Protection Compound)
BPC-157 is a synthetic pentadecapeptide investigated in preclinical research for its interaction with tissue repair signaling pathways, angiogenic signaling mechanisms, and inflammatory response modulation.
Experimental models suggest involvement in cellular resilience and structural signaling processes, though findings remain non-clinical and exploratory.
Retatrutide
Retatrutide is an investigational multi-receptor peptide studied in metabolic and receptor-signaling research. Research focuses on its interaction with multiple signaling pathways involved in energy balance and metabolic regulation.
Laboratory investigations evaluate receptor activation behavior and intracellular signaling patterns rather than physiological outcomes.
MOTS-C
MOTS-C is a mitochondrial-derived peptide studied for its role in mitochondrial-to-nuclear communication, cellular stress response signaling, and metabolic adaptation mechanisms.
Experimental research indicates involvement in energy sensing and stress-response pathways under controlled laboratory conditions.
GHK-Cu (Copper Tripeptide)
GHK-Cu is a copper-binding tripeptide widely studied in research involving collagen-related signaling, extracellular matrix remodeling, and oxidative stress response pathways.
In-vitro studies demonstrate involvement in fibroblast signaling and gene expression associated with tissue structure and maintenance.
Glutathione (GSH)
Glutathione is an endogenous antioxidant tripeptide central to research on cellular antioxidant defense systems, detoxification enzyme pathways, and redox homeostasis.
Laboratory research consistently demonstrates glutathione’s role in maintaining intracellular oxidative balance and cellular protection mechanisms.
TB-500 (Thymosin Beta-4 Acetate)
TB-500 is an actin-binding peptide investigated in experimental models focused on cell migration, cytoskeletal organization, and angiogenic signaling pathways.
Preclinical research highlights involvement in cellular movement and structural organization mechanisms.
CJC-1295
CJC-1295 is a growth hormone–releasing hormone analog studied in laboratory research for receptor activation dynamics and endocrine signaling pathway modeling.
Experimental research focuses on signal transduction behavior rather than physiological outcomes.
Ipamorelin
Ipamorelin is a growth hormone secretagogue studied in laboratory research for selective receptor activation and signaling specificity.
Research evaluates receptor interaction profiles under controlled experimental conditions.
Sermorelin
Sermorelin is a growth hormone–releasing hormone analog explored in endocrine signaling research involving growth hormone pathway activation and receptor binding characteristics.
All findings are derived from experimental models and mechanistic research.
AOD-9604
AOD-9604 is a peptide fragment investigated in metabolic research related to lipid metabolism signaling and adipocyte pathway exploration.
Laboratory studies focus on cellular signaling mechanisms rather than applied outcomes.
Selank
Selank is a synthetic neuropeptide studied in experimental models of neurochemical signaling and stress-response pathways.
Preclinical research evaluates neuromodulatory signaling mechanisms in controlled laboratory environments.
PT-141
PT-141 is a melanocortin receptor research peptide studied in laboratory models focused on receptor signaling and neural pathway mapping.
Research examines receptor-level signaling behavior rather than physiological or behavioral outcomes.
KLOW Research Blend
KLOW is a multi-peptide research formulation designed for laboratory investigation of overlapping signaling pathways related to tissue signaling, extracellular matrix dynamics, and inflammatory pathway modulation.
Research explores potential synergistic signaling effects under controlled experimental conditions.
GLOW Research Blend
GLOW is a multi-peptide research formulation studied in laboratory models focused on fibroblast signaling, collagen-associated pathways, and cellular migration mechanisms.
Experimental studies evaluate coordinated signaling behavior across structural and migratory pathways.
Wolverine Stack Research Blend
Wolverine Stack is a dual-peptide research formulation examined in laboratory research models evaluating tissue response signaling, cytoskeletal interaction pathways, and cell migration behavior.
Research explores combined pathway interactions rather than individual compound effects.
How to Interpret Research Data
In-vitro studies are conducted in controlled laboratory environments using cells or tissues and are designed to explore biological mechanisms rather than outcomes.
Preclinical studies explore signaling behavior in living systems but do not translate directly to humans.
Mechanistic research focuses on how compounds interact with biological pathways and should not be interpreted as evidence of safety or efficacy.
How to Read a Certificate of Analysis (COA)
A Certificate of Analysis (COA) is an analytical document that verifies the identity and quality of a research compound.
Key elements of a COA include compound identity confirmation, purity analysis (commonly measured by HPLC), analytical testing methods, lot or batch traceability, and testing dates.
A COA does not indicate approval, safety, or suitability for human or animal use.
Final Compliance Statement
Luxury Peptide™ provides research compounds exclusively for scientific investigation and analytical research.
No information on this website is intended for human or veterinary application.