Product Overview
The MOTS-c 60mg premixed pen provides a high-purity, synthetic peptide directly derived from mitochondrial DNA (mtDNA). Specifically, MOTS-c belongs to the Mitochondrial-Derived Peptide (MDP) family. Consequently, it has become a primary subject in advanced research regarding cellular metabolic regulation and energy homeostasis.
This 60mg premixed peptide pen offers maximum stability for rigorous laboratory use. Furthermore, researchers widely investigate MOTS-c for its "exercise mimetic" properties. Specifically, the peptide activates the AMPK pathway. Therefore, it influences systemic glucose utilization and improves metabolic flexibility in experimental models.
Product Features and Specifications
We manufacture our MOTS-c 60mg pens to meet the highest industry standards. This ensures laboratory-grade results for every study.
- Quantity: 60mg of high-purity synthetic peptide.
- Format: Premixed pen for easy and consistent laboratory administration.
- Stability: Optimized for long-term shelf life and structural integrity.
- Application: Ideal for advanced metabolic and mitochondrial signaling research.
Primary Research Applications
In controlled laboratory environments, researchers utilize MOTS-c for several specialized purposes. Specifically, examples include:
- Mitochondrial Signaling Investigations: Mapping complex intracellular regulatory networks.
- Metabolic Flexibility Modeling: Studying how skeletal muscle switches between fuel sources.
- MDP Comparative Research: Benchmarking MOTS-c against other mitochondrial peptides like Humanin.
- Adaptive Stress Response Studies: Exploring cellular resilience to metabolic deprivation.
Key Areas of Metabolic & Longevity Research
Scientists focus on several core areas when investigating MOTS-c. These include:
- AMPK Activation: Investigating how MOTS-c triggers the AMP-activated protein kinase (AMPK) pathway to promote energy balance.
- Glucose & Lipid Metabolism: Studying its role in enhancing glucose uptake in skeletal muscle. Additionally, researchers analyze its ability to promote fatty acid oxidation (fat burning).
- Mitochondrial Homeostasis: Analyzing how MOTS-c optimizes the function of cellular "powerhouses." Moreover, researchers study how it enhances resilience to environmental stressors.
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