NAD+ buffer

NAD+ buffer is presented here as a laboratory catalogue entry for research environments that need clear identification, labelled variants, and direct access to supporting records. The current listing includes 2 labelled variants: 500mg and 1000mg. That structure keeps the page useful as both a procurement reference and an indexable resource covering stock visibility, pricing context, and documentation.

Within the wider Au Peptide Labs catalogue, NAD+ buffer sits alongside Tesamorelin, Ipamorelin, and MOTS-c. Researchers often review neighbouring compounds before selecting a comparator or deciding which sequence belongs in a screening panel. Keeping those internal paths close to the product page improves traceability and helps laboratory buyers compare materials without relying on vague or consumer-style copy.

In research literature, NAD+ buffer is generally treated as a formulation-grade redox-active research material — either the tripeptide antioxidant glutathione (γ-Glu-Cys-Gly) or nicotinamide adenine dinucleotide (NAD⁺), a central coenzyme in cellular oxidation-reduction biochemistry. Glutathione (GSH) is the most abundant intracellular thiol antioxidant (cytoplasmic concentrations 1–10 mM in most mammalian cells). It serves as the electron donor for glutathione peroxidase (GPx) in peroxide detoxification, as a co-substrate for glutathione S-transferases (GSTs) in Phase II xenobiotic conjugation, and as a key regulator of protein thiol redox state. In research, the GSH:GSSG ratio is used as a quantitative readout of cellular redox status. NAD⁺ functions as a hydride acceptor in glycolysis, the TCA cycle, and β-oxidation; its reduced form NADH feeds electrons into Complex I of the mitochondrial ETC. NAD⁺ is also the obligate substrate of sirtuins (SIRT1–7), PARP family enzymes, and cyclic ADP-ribose synthases, making it a substrate-level regulator of epigenetic, DNA repair, and calcium signalling pathways.

Research using these materials often centres on cellular redox homeostasis, NAD⁺-dependent enzyme activity, or their roles as components of a reconstituted biochemical assay system. Both require careful attention to oxidation state during preparation — GSSG contamination in GSH stocks and NAD⁺/NADH contamination affect assay validity. For laboratory teams, the practical emphasis is usually on sequence identity, receptor or pathway relevance where documented, and whether NAD+ buffer behaves consistently across stability, purity, and analytical verification workflows. Variant labels on this page support clearer internal referencing when multiple labelled variants are under review.

A product-specific COA is linked on this page, with purity noted as available in the document. The COA section is useful for confirming how the product is labelled in the catalogue, whether purity information has been published, and whether the laboratory record for the material is complete before bench use.

When teams compare NAD+ buffer with Tesamorelin, Ipamorelin, and MOTS-c, COA access also helps keep comparator decisions grounded in documented material identity rather than assumption. That is especially important for research pages that combine pricing, variant selection, and analytical records on a single URL.