This research-grade compound is supplied exclusively for laboratory and experimental use. NAD⁺ is widely studied in experimental models focused on cellular energy metabolism, mitochondrial function, and longevity-related pathways. Research interest centers on its role as a core coenzyme supporting metabolic and repair processes at the cellular level.
In experimental and laboratory research settings, NAD+ is commonly examined alongside compounds involved in cellular energy metabolism, redox regulation, and mitochondrial signaling pathways.
→ L-Glutathione – redox balance and antioxidant system research
Some experimental models explore NAD+ in parallel with compounds studied for NAD⁺ biosynthesis, salvage pathways, and intracellular signaling regulation.
→ 5-Amino-1MQ – NNMT-related metabolic and NAD⁺ pathway research
Additional research frameworks reference NAD+ alongside compounds examined for mitochondrial energy signaling, energy expenditure, and systemic metabolic regulation.
→ SLU-PP-332 – mitochondrial energy signaling and metabolic research
Nicotinamide adenine dinucleotide (NAD+) is a vital coenzyme found in every living cell, playing a central role in energy production, redox reactions, and cellular signaling. NAD+ supports mitochondrial efficiency, influences gene expression through sirtuin activation, and contributes to DNA repair. Research shows NAD+ levels decline with age, which may contribute to metabolic disorders, cognitive decline, and other age-related conditions. Supplementation aims to restore optimal levels, potentially improving resilience to oxidative stress and supporting overall cellular health.
Studies have demonstrated that NAD+ participates in critical oxidation–reduction reactions, acting as a cofactor for enzymes in glycolysis, the Krebs cycle, and oxidative phosphorylation. Beyond its metabolic role, NAD+ regulates signaling pathways involved in calcium homeostasis, inflammation, and chromatin remodeling. Declines in NAD+ during aging have been linked to increased oxidative stress, DNA damage, and mitochondrial dysfunction. This creates a cycle of metabolic decline, contributing to cellular senescence and impaired tissue function. Enhancing NAD+ availability has been shown to activate DNA repair enzymes, boost mitochondrial biogenesis, and improve metabolic performance in various models of aging and disease.
For an in-depth overview of NAD⁺ biochemistry and its role in cellular energy metabolism, see our article What Is NAD⁺?, which examines the molecular mechanisms underlying NAD⁺ function in experimental research models.
To explore how NAD⁺ is studied in the context of aging-related pathways, autophagy, and cellular renewal, refer to our research overview on NAD⁺ and longevity research.
NAD⁺ metabolism is also closely associated with NNMT-related regulatory pathways in experimental research models. Certain small-molecule research compounds are frequently examined for their role in modulating NAD⁺ availability through NNMT activity.
For a research-focused overview of NNMT modulation and its relationship with NAD⁺ metabolism, see:
→ What is 5-Amino-1MQ? – Research overview of NNMT-related metabolic pathways
Related research context
To explore how this compound fits into broader experimental frameworks focused on cellular homeostasis, metabolic balance, antioxidant regulation, and long-term functional maintenance, see:
→ Cellular Homeostasis & Health Maintenance Research
Synonyms: nadide, coenzyme I, beta-NAD, beta-nicotinamide adenine dinucleotide
Molecular Formula: C21H27N7O14P2
Molar Mass: 663.4 g/mol
CAS Number: 53-84-9
PubChem: 5892
Total Amount of the Active Ingredient: 1000 mg (1 vial)
Shelf Life: 36 months
Source: PubMed
NAD⁺ is frequently studied in experimental models alongside compounds involved in metabolic regulation and NAD⁺-dependent signaling pathways. In preclinical research, small molecules such as 5-Amino-1MQ are investigated for their role in pathways that influence intracellular NAD⁺ availability, metabolic flux, and cellular energy balance.
Researchers examining NAD⁺ metabolism, redox regulation, and energy-related signaling may reference related research materials explored within these experimental frameworks.
In vitro research or further manufacturing use only. Not for human or animal use.
All information provided by PRG is for educational and informational purposes only.
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