NAD+
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NAD+

$74.99

NAD⁺ is a coenzyme present in all living cells, playing a central role in redox reactions, energy metabolism, DNA repair, and cellular signaling. This high-purity NAD⁺ solution is designed for laboratory research involving aging, mitochondrial function, and sirtuin activation pathways. Not for human use or therapeutic application.

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Product Overview:

Product Name: NAD⁺ (Nicotinamide Adenine Dinucleotide)
Quantity: 500mg
Molecular Formula: C21H27N7O14P2
Molecular Weight: 663.43 g/mol
Research Use Only. Not for Human Consumption.

Research Applications:

  1. Mitochondrial Function and Energy Metabolism

NAD⁺ is an essential redox cofactor in mitochondrial energy production, particularly in oxidative phosphorylation. It shuttles electrons from glycolysis and the TCA cycle to the electron transport chain, enabling ATP generation [1]. Research using NAD⁺ focuses on its role in mitochondrial bioenergetics and cellular adaptation under energetic stress.

Depletion of NAD⁺ levels is frequently observed in aged or metabolically stressed cells, making it a target in studies of mitochondrial dysfunction, senescence, and metabolic disorders.

  1. Sirtuin Activation and Epigenetic Regulation

NAD⁺ is a required co-substrate for sirtuin deacetylases (SIRT1–SIRT7), which are involved in DNA repair, chromatin remodeling, and gene expression [2]. These enzymes regulate cellular longevity, inflammation, and metabolic adaptation, making NAD⁺ supplementation a critical variable in aging and epigenetic studies.

Studies often explore how NAD⁺ influences SIRT1-mediated pathways to improve DNA stability, reduce histone acetylation, and modulate transcriptional activity under stress conditions.

  1. DNA Repair and PARP Function

NAD⁺ is also a substrate for poly(ADP-ribose) polymerases (PARPs), which mediate DNA damage response and repair mechanisms. When DNA strand breaks occur, PARP enzymes consume NAD⁺ to signal for repair machinery, especially under oxidative stress or genotoxic insult [3].

In research models, excessive PARP activation can lead to NAD⁺ depletion and subsequent ATP loss, contributing to cell death. Thus, NAD⁺ is studied in contexts of genomic stability, neurodegeneration, and cell survival signaling.

  1. Immunometabolism and Inflammatory Regulation

Recent research links NAD⁺ to immune cell regulation, particularly via CD38 and SIRT1 pathways in macrophages and T-cells. NAD⁺ modulates pro-inflammatory cytokine expression and T-cell function, making it a point of interest in immunometabolic research [4].

Studies are exploring how NAD⁺ levels influence cellular redox states and inflammatory gene transcription, especially in chronic inflammatory or autoimmune models.

Referenced Citations:

  1. Ying W. “NAD⁺ and NADH in cellular metabolism.” PubMed
    Source: Antioxidants & Redox Signaling – Fundamental review on redox roles of NAD⁺.
  2. Imai S, Guarente L. “NAD⁺ and sirtuins in aging.” PubMed
    Source: Trends in Cell Biology – NAD⁺ as a cofactor for SIRT enzymes.
  3. Bai P, et al. “PARP enzymes and NAD⁺ depletion in DNA damage.” PubMed
    Source: Molecular Cell – PARP-mediated NAD⁺ use in genomic repair.
  4. Chini EN, et al. “CD38/NAD⁺ axis in inflammation and immunity.” PubMed
    Source: Cell Metabolism – NAD⁺ in immunological and inflammatory signaling.

Product Usage:

This product is meant only for research use. It is made for lab testing and in vitro experiments (outside a living body), not for use in people or animals. All information on this website is for learning purposes only. Bodily introduction of any kind into humans or animals is strictly forbidden by law. It should only be used by trained professionals in a proper lab setting. This product is not a medicine, food, or cosmetic, and must not be sold or used as one.