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NAD+ / MOTS-c / 5-Amino-1MQ Peptide Blend 120mg

Original price was: $299.99.Current price is: $189.99.

NAD+/MOTS-c/5-Amino-1MQ Peptide Blend unites three distinct compounds that converge on cellular energy, mitochondrial function, and metabolic regulation. Together, their mechanisms are designed to: Enhance mitochondrial and cellular energy balance. Improve metabolic health. Support cognitive and longevity research.

SKU: NAD-MOTS-5AM-120MG Categories: , Tags: , , , Product ID: 6254

Description

NAD+ / MOTS-c / 5-Amino-1MQ Peptide Blend Product Description

The NAD+ / MOTS-c / 5-Amino-1MQ Peptide Blend is an advanced research formulation developed for investigators studying mitochondrial biology, metabolic regulation, cellular energy production, and healthy aging mechanisms. By combining three well-characterized compounds with complementary mechanisms of action, this blend provides a comprehensive platform for evaluating multiple pathways involved in metabolism, oxidative stress, and cellular resilience.

Each lyophilized vial contains 100 mg NAD+, 10 mg MOTS-c, and 10 mg 5-Amino-1MQ, allowing researchers to investigate the interactions between NAD+ metabolism, mitochondrial signaling, and nicotinamide N-methyltransferase (NNMT) inhibition within a single experimental protocol.

Manufactured under strict quality standards and verified through third-party analytical testing, this research compound is intended exclusively for laboratory and in vitro research applications.

NAD+ / MOTS-c / 5-Amino-1MQ Peptide Blend Structure

Ingredient Dose (per capsule) Key Actions
NAD+ 100 mg Cofactor in redox metabolism; activates sirtuins & AMPK; supports DNA repair & mitochondrial biogenesis [1][2][3]
MOTS-c 10 mg Mitochondria-encoded peptide; AMPK activation; improves insulin sensitivity; prevents metabolic dysfunction [4][5][6]
5-Amino-1MQ 10 mg NNMT inhibitor; ↑NAD+; ↓adiposity; epigenetic modulation; metabolic & oncology research [7][8][9]

NAD+ / MOTS-c / 5-Amino-1MQ Peptide Blend Benefits

Researchers utilize the NAD+ / MOTS-c / 5-Amino-1MQ Blend to investigate several interconnected biological pathways, including:

  • Cellular energy metabolism and ATP production
  • Mitochondrial function and metabolic flexibility
  • NAD+ biosynthesis and redox balance
  • AMPK activation and metabolic signaling
  • Insulin sensitivity and glucose metabolism
  • Fat metabolism and adipocyte regulation
  • Oxidative stress reduction
  • Cellular repair and DNA maintenance pathways
  • Healthy aging and longevity mechanisms
  • Cognitive function and neuroprotective signaling
  • Cellular resilience during metabolic stress
  • Epigenetic regulation through NNMT inhibition

NAD+ / MOTS-c / 5-Amino-1MQ Peptide Blend Effects

Supports Cellular Energy Production

NAD+ functions as one of the body’s most important metabolic cofactors, participating in hundreds of enzymatic reactions responsible for ATP generation, oxidative phosphorylation, and cellular respiration. Laboratory investigations suggest restoring intracellular NAD+ pools may improve mitochondrial efficiency and overall cellular energy metabolism.

Promotes Mitochondrial Function

MOTS-c is a mitochondria-derived peptide that acts as a metabolic signaling molecule. Research demonstrates that MOTS-c activates AMPK during metabolic stress, encouraging cells to utilize energy more efficiently while promoting mitochondrial adaptation.

Enhances Metabolic Regulation

Experimental models indicate that combining NAD+ restoration with MOTS-c signaling and NNMT inhibition may improve glucose utilization, insulin sensitivity, and overall metabolic homeostasis. Researchers frequently investigate this combination in studies involving obesity, insulin resistance, and metabolic syndrome.

Supports Healthy Fat Metabolism

5-Amino-1MQ functions as an inhibitor of nicotinamide N-methyltransferase (NNMT), an enzyme closely associated with fat storage and metabolic dysfunction. Preclinical studies suggest NNMT inhibition may increase NAD+ availability while supporting healthier lipid metabolism and reducing adipose tissue accumulation.

Activates Longevity Pathways

NAD+ serves as an essential substrate for sirtuins and PARP enzymes involved in DNA repair, genomic stability, and cellular stress resistance. Together with MOTS-c-mediated AMPK activation, this blend offers researchers an opportunity to examine multiple longevity-associated signaling pathways simultaneously.

Reduces Oxidative Stress

Research suggests all three compounds contribute to improved antioxidant defenses by enhancing mitochondrial efficiency, lowering reactive oxygen species production, and supporting endogenous antioxidant enzyme activity.

Supports Cognitive and Neurological Research

NAD+ replenishment and MOTS-c signaling have demonstrated promising activity in laboratory models investigating neuroinflammation, neuronal survival, and cognitive performance. Researchers continue evaluating these mechanisms for their potential role in maintaining healthy brain function during aging.

Investigates Epigenetic Regulation

5-Amino-1MQ influences cellular methylation pathways through inhibition of NNMT, providing researchers with a valuable tool for studying gene expression, metabolic programming, and epigenetic regulation.

Multi-Target Research Platform

Rather than acting through a single biological pathway, this formulation enables investigation of interconnected mechanisms involving:

  • NAD+ metabolism
  • Mitochondrial signaling
  • AMPK activation
  • Sirtuin activity
  • DNA repair pathways
  • NNMT inhibition
  • Glucose metabolism
  • Fat metabolism
  • Cellular aging

These complementary mechanisms make the blend suitable for advanced metabolic and longevity-focused research protocols.


Research Applications

The NAD+ / MOTS-c / 5-Amino-1MQ Blend is commonly investigated in laboratory studies involving:

  • Mitochondrial dysfunction
  • Healthy aging mechanisms
  • Metabolic syndrome
  • Obesity research
  • Insulin sensitivity
  • Glucose regulation
  • Cellular energy metabolism
  • Exercise physiology
  • Neuroprotection
  • Oxidative stress
  • DNA repair pathways
  • Cellular senescence
  • Epigenetic regulation

For laboratory research use only. Not intended for human consumption or therapeutic use.

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