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NAD+

Table of Contents

What NAD+ does in your cells
Why NAD+ declines with age
NAD+ biosynthesis: three pathways
Sirtuins and the NAD+ connection
Safety and emerging concerns
Practical strategies to maintain NAD+

What NAD+ does in your cells

Nicotinamide adenine dinucleotide (NAD+) is a coenzyme found in every living cell. It participates in more than 500 enzymatic reactions, working as an electron carrier in mitochondrial energy production and as a substrate consumed by three enzyme families tied to cellular maintenance: sirtuins, PARPs (poly-ADP-ribose polymerases), and CD38. Without adequate NAD+, cells can't efficiently produce ATP, repair damaged DNA, or regulate inflammatory responses.

NAD+ levels drop by roughly 50% between ages 40 and 60 ^[1]. This decline is now considered a hallmark of biological aging, linked to mitochondrial dysfunction, genomic instability, and weakened cellular repair.

Why NAD+ declines with age

Several factors converge to drain NAD+ as we get older. CD38, an enzyme expressed on immune cells, ramps up activity during chronic low-grade inflammation (sometimes called inflammaging) and is the single largest consumer of NAD+ in aging tissues ^[1]^[2]. PARP enzymes, which patch up accumulated DNA damage, also consume more NAD+ over time. Meanwhile, expression of NAMPT, the rate-limiting enzyme in the NAD+ salvage pathway, decreases with age, reducing the body's capacity to recycle NAD+ from nicotinamide. The result is a progressive energy deficit at the cellular level.

NAD+ biosynthesis: three pathways

Your body produces NAD+ through three distinct routes. The de novo pathway converts the amino acid tryptophan into NAD+ via the kynurenine pathway. The Preiss-Handler pathway uses dietary niacin (vitamin B3). And the salvage pathway recycles nicotinamide back into NAD+ through NAMPT. The salvage pathway handles the majority of daily NAD+ turnover and is the one most affected by aging.

NMN vs. NR as precursors

The two most studied NAD+ precursors are nicotinamide mononucleotide (NMN) and nicotinamide riboside (NR). NMN sits one enzymatic step closer to NAD+ in the biosynthesis chain, while NR must first be phosphorylated to NMN by NR kinases. Both effectively raise blood NAD+ levels in human trials. NMN at 250 to 1,000 mg daily has shown improvements in muscle insulin sensitivity, aerobic capacity, and walking speed in older adults ^[3]^[5]. NR at 300 to 1,000 mg daily has raised NAD+ by 40 to 90% in clinical studies, with safety data at doses up to 2,000 mg ^[4]. A 2025 meta-analysis found that despite clear NAD+ elevation, most clinically relevant endpoints in muscle mass and function did not reach statistical significance across pooled trials ^[6].

Sirtuins and the NAD+ connection

The sirtuin family (SIRT1 through SIRT7) are NAD+-dependent deacetylases that regulate DNA repair, mitochondrial biogenesis, inflammation, and circadian rhythm. SIRT1 mimics caloric restriction benefits by deacetylating PGC-1 alpha and FOXO transcription factors, while SIRT3 protects mitochondrial proteins from oxidative damage. NAD+ availability is the rate-limiting factor for sirtuin activity, which is why NAD+ decline and accelerated aging track so closely together.

Safety and emerging concerns

NAD+ precursors are generally well tolerated. The most common side effects reported in trials are mild: nausea, flushing, and headaches ^[8]. However, a 2024 Cleveland Clinic study raised a new concern: elevated levels of 4PY (N1-methyl-4-pyridone-3-carboxamide), a terminal breakdown product of excess niacin, were associated with increased cardiovascular inflammation and higher risk of heart attack and stroke ^[9]. This doesn't apply equally to all precursors (NMN and NR are metabolized differently from free niacin), but it warrants caution with high-dose, long-term supplementation. People with active cancer should also exercise caution, since NAD+ fuels rapidly dividing cells regardless of whether they're healthy or malignant. Long-term safety data beyond 12 weeks remains limited for most precursors.

Practical strategies to maintain NAD+

Exercise regularly: HIIT and endurance training upregulate NAMPT and naturally boost NAD+ through the salvage pathway ^[5]
Practice time-restricted eating: fasting activates AMPK and increases NAMPT expression, synergizing with any precursor supplementation
Consider TMG (trimethylglycine, 500 to 1,000 mg): NAD+ synthesis consumes methyl groups, and TMG supports methylation balance
Include CD38-inhibiting foods: apigenin (parsley, chamomile) and quercetin (onions, apples) are natural CD38 inhibitors that may slow NAD+ degradation ^[1]
Take precursors in the morning to align with circadian NAD+ peaks and avoid possible sleep disruption from evening dosing
Start low (250 mg NMN or 300 mg NR) and increase gradually based on tolerance

References

Exercise boosts NAD+ naturally

High-intensity interval training (HIIT) and endurance exercise upregulate NAMPT, the rate-limiting enzyme in the NAD+ salvage pathway. Regular physical activity is the most evidence-backed way to maintain NAD+ levels without supplementation.

pmc.ncbi.nlm.nih.gov

Take NAD+ precursors in the morning

NAD+ levels follow a circadian rhythm and peak during the day. Taking NMN or NR in the morning aligns with this natural cycle and may help avoid sleep disruption that some users report from evening dosing.

Natural CD38 inhibitors may preserve NAD+

Apigenin (found in parsley and chamomile) and quercetin (in onions and apples) are natural CD38 inhibitors. Since CD38 is the dominant NAD+ consumer during aging, these flavonoids may help slow NAD+ degradation alongside precursor supplementation.

pmc.ncbi.nlm.nih.gov

Watch the 4PY concern with high-dose niacin

A 2024 Cleveland Clinic study found that 4PY, a breakdown product of excess niacin, is linked to vascular inflammation and cardiovascular risk. NMN and NR are metabolized differently, but this is another reason to avoid megadosing any single NAD+ precursor without medical guidance.

www.nature.com

Support methylation with TMG when supplementing

NAD+ synthesis from NMN or NR consumes methyl groups. Adding trimethylglycine (TMG, 500 to 1,000 mg) can help maintain methylation balance, especially at higher precursor doses. This is a commonly overlooked companion supplement.

Eat tryptophan-rich foods for de novo NAD+ production

Your body can build NAD+ from scratch using tryptophan through the kynurenine pathway. Foods like turkey, chicken, salmon, eggs, and dairy provide this amino acid. While the salvage pathway handles most NAD+ recycling, dietary tryptophan contributes to the baseline supply.

NMN/NR for cellular aging

NMN and NR are NAD+ precursors that may slow cellular aging. Typical doses are 250-500mg NMN or 300mg NR daily. Research is promising but long-term human data is limited.

NAD+ declines with age

NAD+ levels drop roughly 50% between ages 40 and 60. NMN and NR are the most researched precursors to restore NAD+ levels, though human evidence is still emerging.

Why does NAD+ decline with age?

NAD+ decline results from multiple converging factors. The enzyme CD38 on immune cells becomes increasingly active with chronic low-grade inflammation (inflammaging) and is the dominant NAD+ consumer. PARP enzymes that repair accumulated DNA damage also consume more NAD+ over time. Simultaneously, NAMPT expression decreases, reducing the body ability to recycle NAD+ through the salvage pathway. Together, these factors create a progressive cellular energy deficit.

Is NMN or NR better for raising NAD+ levels?

Both NMN and NR effectively raise blood NAD+ levels in human clinical trials. NMN is one enzymatic step closer to NAD+ in the biosynthetic pathway, while NR has a larger body of published human trial data and established safety profiles at doses up to 2,000 mg daily. Current evidence does not conclusively show one is superior to the other. The choice may depend on individual response, cost, and product quality.

Can you measure your NAD+ levels?

Intracellular NAD+ measurement remains primarily a research tool, though commercial whole-blood NAD+ tests are becoming available. These provide a snapshot but do not reflect tissue-specific NAD+ levels, which can vary significantly between organs. Functional proxies such as grip strength, VO2 max, heart rate variability (HRV), and fasting lactate levels may offer practical indicators of NAD+-dependent metabolic health.

Are there risks to taking NAD+ supplements long-term?

Most clinical trials have only tracked participants for 8 to 12 weeks, so true long-term safety data is limited. Reported side effects (nausea, flushing, headache) are generally mild. A 2024 study linked 4PY, a breakdown product of excess niacin, to cardiovascular inflammation, though this finding applies more directly to niacin than to NMN or NR. People with active cancer should be cautious, as NAD+ supports cell division in all rapidly growing cells. Discuss supplementation with a doctor if you have underlying health conditions.

Can you boost NAD+ without supplements?

Yes. Exercise is the strongest non-pharmacological NAD+ booster. HIIT and endurance training upregulate NAMPT, the enzyme that drives the NAD+ salvage pathway. Intermittent fasting and caloric restriction activate AMPK and sirtuin signaling, both of which increase NAD+ turnover. Eating foods rich in tryptophan (poultry, fish, eggs) and niacin (mushrooms, green peas, avocados) also supports NAD+ production through the de novo and Preiss-Handler pathways.

What is the difference between NAD+, NADH, and NAD?

NAD+ and NADH are two forms of the same molecule. NAD+ is the oxidized form that accepts electrons during metabolic reactions. NADH is the reduced form that carries those electrons to the mitochondrial electron transport chain for ATP production. The ratio between them reflects your cells' metabolic state. When people say 'NAD' without the plus sign, they usually mean the total pool of both forms. Supplements target the NAD+ side because that's the form consumed by sirtuins and PARPs.

Do longevity supplements actually work?

Some show promise: NMN/NR (NAD+ precursors) restore cellular NAD+ levels in human studies. Resveratrol activates sirtuin pathways in lab settings. Metformin is being studied in the TAME trial. However, no supplement has been proven to extend human lifespan yet. The strongest "longevity supplements" remain exercise, sleep, and nutrition.

What is NMN and NR?

NMN (nicotinamide mononucleotide) and NR (nicotinamide riboside) are precursors to NAD+, a coenzyme critical for cellular energy and repair that declines ~50% between ages 40-60. Both raise NAD+ levels in human studies. NMN may be more direct, NR has more published human trials. Typical doses: 250-500mg NMN or 300mg NR daily. Long-term safety data is still limited.