NAD+ Boosters: Difference between revisions

    From Longevity Wiki
    Line 33: Line 33:
    ! Notes
    ! Notes
    |-
    |-
    | NMN (Nicotinamide Mononucleotide)
    | [[Nicotinamide Mononucleotide (NMN)]]
    | NAD+ Precursor
    | NAD+ Precursor
    | High
    | High
    Line 43: Line 43:
    | Converted to NMN in the body before participating in NAD+ synthesis
    | Converted to NMN in the body before participating in NAD+ synthesis
    |-
    |-
    | Nicotinamide (NAM)
    | [[Nicotinamide (NAM)]]
    | NAD+ Precursor via the salvage pathway
    | NAD+ Precursor via the salvage pathway
    | Medium
    | Medium
    | More research needed on optimal dosing and long-term effects
    | More research needed on optimal dosing and long-term effects
    |-
    |-
    | Resveratrol
    | [[Resveratrol]]
    | Sirtuin activator; may have indirect effects on NAD+ levels and metabolism
    | Sirtuin activator; may have indirect effects on NAD+ levels and metabolism
    | Low to Medium
    | Low to Medium
    | Effectiveness may be influenced by individual metabolic differences and supplement formulation
    | Effectiveness may be influenced by individual metabolic differences and supplement formulation
    |-
    |-
    | Quercetin
    | [[Quercetin]]
    | Inhibits CD38; may increase NAD+ levels indirectly
    | Inhibits CD38; may increase NAD+ levels indirectly
    | Low to Medium
    | Low to Medium
    | More research needed to quantify the impact on NAD+ levels
    | More research needed to quantify the impact on NAD+ levels
    |-
    |-
    | Pterostilbene
    | [[Pterostilbene]]
    | Similar to resveratrol; purported to have beneficial effects on NAD+ metabolism and sirtuin activation
    | Similar to resveratrol; purported to have beneficial effects on NAD+ metabolism and sirtuin activation
    | Low to Medium
    | Low to Medium
    | Requires more rigorous studies to confirm efficacy
    | Requires more rigorous studies to confirm efficacy
    |-
    |-
    | Exercise
    | [[Exercise]]
    | Increases NAD+ levels likely due to enhanced energy metabolism and increased demand for ATP
    | Increases NAD+ levels likely due to enhanced energy metabolism and increased demand for ATP
    | Medium to High
    | Medium to High
    | Effectiveness may depend on exercise type, intensity, and individual fitness level
    | Effectiveness may depend on exercise type, intensity, and individual fitness level
    |-
    |-
    | Caloric Restriction
    | [[Caloric Restriction]]
    | Elevates NAD+ levels potentially through the activation of sirtuins and improved metabolic efficiency
    | Elevates NAD+ levels potentially through the activation of sirtuins and improved metabolic efficiency
    | High
    | High
    | Sustained caloric restriction may have compliance challenges
    | Sustained caloric restriction may have compliance challenges
    |-
    |-
    | Intermittent Fasting
    | [[Intermittent Fasting]]
    | Elevates NAD+ levels through mechanisms similar to caloric restriction
    | Elevates NAD+ levels through mechanisms similar to caloric restriction
    | Medium to High
    | Medium to High

    Revision as of 16:05, 26 September 2023

    NAD+ boosters are substances or interventions designed to increase levels of NAD+ (Nicotinamide Adenine Dinucleotide), a critical coenzyme found in every cell, essential for cellular energy production, metabolism, and repair processes. Boosting NAD+ levels is of significant interest in the fields of health and longevity, as declining levels of NAD+ are associated with aging and various age-related diseases.

    NAD+ Precursors

    NAD+ precursors are molecules that serve as substrates in the biosynthesis of NAD+. They can be converted into NAD+ within the body, thus serving as effective NAD+ boosters.

    Boosting NAD+ by Inhibiting NAD+ Consumers

    NAD+ consumers are enzymes that use NAD+ as a substrate, reducing the available NAD+ in the cell. By inhibiting these consumers, more NAD+ remains available for other cellular processes.

    • Sirtuins: A family of proteins that deacetylate proteins and consume NAD+ in the process. Compounds like resveratrol can activate sirtuins and the subsequent cellular effects can create an environment where cells might maintain or produce NAD+ more efficiently, which could indirectly support NAD+ availability.
    • PARPs (Poly(ADP-ribose) polymerases): Enzymes involved in DNA repair that also consume NAD+. Inhibiting PARP activity can help maintain NAD+ levels.
    • CD38: A glycoprotein that uses NAD+; reducing CD38 levels or activity can potentially elevate NAD+ levels.

    Other NAD+ Boosting Supplements

    Beyond precursors and inhibitors of NAD+ consumers, several other supplements claim to boost NAD+ levels or improve NAD+ metabolism.

    • Resveratrol: While primarily known as a sirtuin activator, it might also have indirect effects on NAD+ levels and metabolism.
    • Quercetin: A flavonoid that can inhibit CD38 and may, therefore, increase NAD+ levels indirectly.
    • Pterostilbene: A polyphenol, similar to resveratrol, purported to have beneficial effects on NAD+ metabolism and sirtuin activation.

    Interventions to Boost NAD+

    Apart from supplements, certain lifestyle and dietary interventions may also support NAD+ levels.

    • Exercise: Regular physical activity has been shown to increase NAD+ levels, likely due to enhanced energy metabolism and increased demand for ATP.
    • Caloric Restriction: Reducing calorie intake without malnutrition can elevate NAD+ levels, potentially through the activation of sirtuins and improved metabolic efficiency.
    • Intermittent Fasting: This dietary approach can also elevate NAD+ levels, likely through mechanisms similar to caloric restriction, such as increased stress resistance and metabolic adaptations.

    Comparison

    Booster Mechanism of Action Relative Strength Notes
    Nicotinamide Mononucleotide (NMN) NAD+ Precursor High Well-researched, direct precursor to NAD+
    NR (Nicotinamide Riboside) NAD+ Precursor High Converted to NMN in the body before participating in NAD+ synthesis
    Nicotinamide (NAM) NAD+ Precursor via the salvage pathway Medium More research needed on optimal dosing and long-term effects
    Resveratrol Sirtuin activator; may have indirect effects on NAD+ levels and metabolism Low to Medium Effectiveness may be influenced by individual metabolic differences and supplement formulation
    Quercetin Inhibits CD38; may increase NAD+ levels indirectly Low to Medium More research needed to quantify the impact on NAD+ levels
    Pterostilbene Similar to resveratrol; purported to have beneficial effects on NAD+ metabolism and sirtuin activation Low to Medium Requires more rigorous studies to confirm efficacy
    Exercise Increases NAD+ levels likely due to enhanced energy metabolism and increased demand for ATP Medium to High Effectiveness may depend on exercise type, intensity, and individual fitness level
    Caloric Restriction Elevates NAD+ levels potentially through the activation of sirtuins and improved metabolic efficiency High Sustained caloric restriction may have compliance challenges
    Intermittent Fasting Elevates NAD+ levels through mechanisms similar to caloric restriction Medium to High Impact may vary depending on the specific fasting protocol employed

    Conclusion

    NAD+ boosters, encompassing NAD+ precursors, inhibitors of NAD+ consuming enzymes, and various other supplements, along with non-supplemental measures like exercise and dietary modifications, offer promising avenues to enhance cellular vitality, metabolism, and potentially, longevity. While the science is evolving, understanding the diverse approaches to boost NAD+ highlights the multifaceted nature of cellular health and provides multiple pathways to explore for maintaining optimal health and combating age-related decline.