NAD+
Certificate of Analysis
Each batch is tested by an independent third-party laboratory. Certificate of Analysis is available upon request.
What is NAD+?
What is NAD+?
NAD+ (Nicotinamide Adenine Dinucleotide) is a coenzyme found in every cell, essential for energy production and cellular metabolism. It helps repair DNA, regulate cellular stress, and maintain mitochondrial function. NAD+ is studied for its potential to improve overall cellular health, making it key in longevity research.
Frequently asked questions
Are your products tested?
Yes, all products are tested by third-party laboratories to ensure purity and potency.
What is the shipping time?
Orders ship same day from our facility and typically arrive within 5–10 business days.
Do you offer bulk pricing?
Please contact us for bulk order inquiries.
Made in China
Peptides are precision-synthesized and lyophilized at state-of-the-art laboratories.
NAD+ Overview
Nicotinamide adenine dinucleotide (NAD⁺) is a naturally occurring coenzyme central to redox reactions, energy metabolism, and cellular signaling. In laboratory and preclinical models, NAD⁺ has been studied for its role in mitochondrial function, DNA repair, and regulation of cellular resilience. Research continues to explore its influence on sirtuin activation, oxidative stress response, and metabolic pathways.
History
NAD+ was first identified in the early 20th century during research into fermentation and cellular respiration. Its structure and biochemical role were later clarified, establishing it as a key coenzyme in metabolic and enzymatic reactions. In recent decades, research has expanded to its involvement in DNA repair, aging biology, and cell survival pathways, with growing use as a research tool in models of metabolism and stress response.
NAD+ Structure
CAS #: 53-84-9
Molecular Formula: C₂₁H₂₇N₇O₁₄P₂
Molecular Weight: 663.4 g/mol
PubChem ID: 5892
Research Findings
NAD+ has been investigated in metabolic, cellular, and systemic models, with research highlighting its role in energy metabolism, mitochondrial function, and cellular repair processes. Studies have also examined its influence on oxidative stress, DNA repair, and overall cellular resilience in preclinical settings.
Key Areas of Research:
• Metabolic: energy production, mitochondrial function
• Cellular: DNA repair, oxidative stress, viability
• Systemic: protection, recovery, resilience
Together, these findings suggest broad experimental potential for NAD+ in supporting cellular and systemic biology. By engaging core metabolic pathways and influencing repair and stress responses, NAD+ provides a versatile platform for research into energy regulation, cellular recovery, and systemic health in laboratory models.
