SIRT1 regulates the circadian clock — NMN can accelerate adaptation to time-zone shifts.

This guide covers the underlying mechanism, the human and animal evidence supporting NMN and NAD+ precursor use for jet lag and circadian rhythm reset, a practical dosing protocol, and the products that consistently appear in evidence-based stacks.

NAD+ (nicotinamide adenine dinucleotide) is a redox coenzyme present in every cell. It powers mitochondrial ATP production via the electron-transport chain, fuels DNA-repair enzymes (PARPs), and is the obligatory substrate for sirtuins (SIRT1–SIRT7) — the enzyme family that controls gene expression, inflammation, and cellular survival.

NAD+ levels fall by 50% or more between ages 30 and 60. That decline is now considered a leading mechanistic explanation for age-related metabolic dysfunction, mitochondrial fatigue, accumulation of senescent cells, and the loss of muscle, skin, and cognitive resilience seen in aging.

NMN (nicotinamide mononucleotide) and NR (nicotinamide riboside) are the two NAD+ precursors with the strongest human data. Both raise NAD+ via the salvage pathway: NR is phosphorylated by NRK1/NRK2 to form NMN, then converted to NAD+; NMN is dephosphorylated to NR for cellular uptake or — per Imai's lab — taken up directly through the Slc12a8 transporter in mouse small intestine. NADH is the reduced electron-carrying form. Niacinamide (nicotinamide) and niacin (nicotinic acid) are cheaper but raise NAD+ less efficiently, and high-dose nicotinamide (>1 g/day) inhibits sirtuins.