NAD+ 500mg

NAD+ (β-Nicotinamide Adenine Dinucleotide) 500mg is a premier, research-grade formulation of one of the most fundamentally important and scientifically significant biological molecules ever discovered in the history of biochemical science. As an essential coenzyme found in every living cell, NAD+ occupies a position of absolute centrality in the biochemical machinery of life itself — serving as an indispensable molecular currency in hundreds of critical metabolic reactions, a master regulator of cellular energy metabolism, and a key signaling molecule in some of the most important biological processes governing cellular health, longevity, and systemic metabolic function.

Since its discovery over a century ago, NAD+ has evolved from being understood simply as a hydrogen carrier in oxidation-reduction reactions to being recognized as one of the most multi-functionally critical and therapeutically relevant molecules in all of biology. Today, NAD+ sits at the very epicenter of some of the most exciting, rapidly evolving, and scientifically groundbreaking research fields in modern biological science — including aging biology, mitochondrial medicine, epigenetics, metabolic disease research, and DNA repair biology — attracting extraordinary levels of scientific investment, investigative attention, and research interest from leading research institutions and scientific organizations worldwide.

The 500mg variant of NAD+ offered by Mile High Compounds represents a substantial, high-volume research compound supply that is specifically formulated for large-scale laboratory investigations, extended research programs, high-throughput experimental protocols, and comprehensive multi-phase studies requiring consistent, uninterrupted access to the highest quality β-Nicotinamide Adenine Dinucleotide available in the research market. Its precision lyophilized formulation ensures outstanding compound stability, exceptional batch-to-batch consistency, and reliable reconstitution characteristics — all of which are absolutely essential for generating scientifically credible, reproducible, and meaningful research outcomes across all experimental applications.

What makes NAD+ uniquely extraordinary as a research compound is the breathtaking scope and fundamental importance of its biological roles. As both a coenzyme in redox reactions and a substrate for critical regulatory enzymes including sirtuins, PARPs, and CD38, NAD+ simultaneously influences cellular energy production, genome stability maintenance, epigenetic regulation, stress response signaling, circadian rhythm coordination, and the fundamental molecular processes governing cellular aging and longevity. This extraordinary breadth of biological influence across virtually every major cellular system makes NAD+ not merely a research compound of interest, but arguably one of the most important molecular research tools available to the modern biochemical scientist.

Research Applications:

NAD+ 500mg supports an exceptionally comprehensive and diverse range of cutting-edge scientific research applications spanning cellular metabolism, aging biology, epigenetics, DNA repair science, mitochondrial medicine, and systemic biochemistry, including:

• Cellular Energy Metabolism Research — conducting foundational and advanced investigations into NAD+'s indispensable role as a coenzyme in glycolysis, the citric acid cycle, and oxidative phosphorylation, examining how NAD+/NADH ratios govern cellular energy production efficiency, mitochondrial respiration dynamics, and overall metabolic flux in controlled in vitro research models

• Sirtuin Biology & Epigenetic Research — examining NAD+'s critical role as the essential substrate for sirtuin deacylase enzymes (SIRT1-7), investigating sirtuin-mediated histone deacetylation, protein deacylation, epigenetic reprogramming, and the downstream consequences of sirtuin activation on gene expression regulation, metabolic adaptation, and cellular stress response mechanisms

• DNA Repair & Genome Stability Research — studying NAD+'s fundamental role as the obligatory substrate for PARP (Poly ADP-Ribose Polymerase) enzymes in DNA damage detection, single and double strand break repair coordination, chromatin remodeling following genotoxic stress, and the maintenance of overall genome integrity and stability in laboratory research models

• Aging Biology & Cellular Senescence Research — exploring the extensively documented decline in cellular NAD+ levels associated with biological aging, investigating the molecular consequences of NAD+ depletion on mitochondrial function, sirtuin activity, DNA repair capacity, and the accumulation of cellular senescence markers in research models designed to study the fundamental biology of aging

• Mitochondrial Function & Biogenesis Research — conducting comprehensive investigations into NAD+'s influence on mitochondrial membrane potential, electron transport chain efficiency, mitochondrial biogenesis regulation through PGC-1α activation, and the broader relationship between cellular NAD+ availability and mitochondrial health, quality control, and functional integrity

• Circadian Rhythm & Biological Clock Research — examining the fascinating and well-documented bidirectional relationship between NAD+ metabolism and circadian clock gene regulation, investigating how NAD+ biosynthesis oscillations drive SIRT1-mediated circadian epigenetic programming and how circadian disruption influences cellular NAD+ homeostasis

• CD38 & NAD+ Consumption Research — studying the role of CD38 as a major NAD+-consuming enzyme, examining its influence on cellular NAD+ availability, calcium signaling regulation, immune cell function, and the competitive dynamics between different NAD+-consuming enzyme systems in metabolically active cells

• Metabolic Disease & Insulin Signaling Research — investigating NAD+'s influence on insulin receptor signaling, glucose transporter regulation, fatty acid oxidation efficiency, and the molecular mechanisms linking cellular NAD+ status to metabolic dysfunction, insulin resistance, and related metabolic pathway dysregulation in research models

• Neuroprotection & Neurological Research — exploring the emerging and scientifically compelling research interest in NAD+'s neuroprotective properties, including its influence on neuronal energy metabolism, axonal degeneration pathways, neuroinflammatory signaling, and the molecular mechanisms through which NAD+ availability influences neurological cell survival and functional integrity

• NAD+ Biosynthesis Pathway Research — conducting detailed investigations into the multiple NAD+ biosynthesis pathways including the Preiss-Handler pathway, de novo synthesis from tryptophan, and the salvage pathway from nicotinamide and NMN, examining enzyme kinetics, pathway regulation, and the cellular determinants of NAD+ homeostasis maintenance

• Immunological & Inflammatory Research — studying NAD+'s multifaceted influence on immune cell metabolism, macrophage polarization, T-cell function, inflammatory cytokine production regulation, and the molecular crosstalk between cellular NAD+ status and innate and adaptive immune system function in controlled laboratory research environments

• Redox Biology & Oxidative Stress Research — examining the fundamental role of the NAD+/NADH redox couple in cellular redox homeostasis, antioxidant defense system regulation, reactive oxygen species management, and the broader implications of redox imbalance on cellular function, stress signaling, and biological integrity across diverse research models

Specifications:

Intended Use: This compound is intended strictly for qualified in vitro laboratory research. It is not approved for use in humans or animals and must not be used in food, drugs, cosmetics, or diagnostics of any kind.

Legal Disclaimer: This product and associated statements have not been evaluated by the FDA. No material is intended to diagnose, treat, cure, or prevent any disease. Use is limited to certified laboratories and research institutions operating under appropriate regulatory oversight.

Terms of Sale: All sales from Mile High Compounds are final. By purchasing, the buyer affirms they are a qualified professional with adequate knowledge of laboratory protocols and assumes full responsibility for safe use, proper storage, and regulatory compliance within their jurisdiction.