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Cardiogen
Cardiogen
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Description
Cardiogen emerges as a promising peptide in cardiovascular and regenerative research. Acting on myocardial and vascular pathways under investigation, it supports optimal heart function, circulatory efficiency, and cellular resilience. By modulating cardiac tone and promoting adaptive repair, Cardiogen contributes to improved systemic recovery and protection against stress‑induced damage.
Its targeted mechanism not only enhances cardiovascular stability but also opens new directions for studying myocardial regeneration and age‑related decline in cardiac performance. Researchers value Cardiogen for its ability to mimic natural protective processes at the molecular level, positioning it as a key candidate in investigations of cardiovascular health, regenerative adaptation, and performance optimization under physiological stress.
Additional Information
Weight: 0.08 lbs
Dimensions: 0.87 × 1.18 × 0.87 in
Size: 5mg, 10mg
This product is intended solely for research purposes. It is not authorized for use in humans or animals and should only be handled by trained personnel in appropriate laboratory settings.
Highlights
Biochemical Profile
Stability :Stable lyophilized, refrigerated.
Solubility: Readily soluble in water and physiological saline
Storage Conditions: Store at 36‑46 °F (2‑8 °C)
Form: White to off‑white crystalline powder
Structural Properties
Amino acid sequence: Ala‑Glu‑Asp‑Arg
Molecular Mass: ~489.46 g/mol
Composition: C₁₈H₃₁N₇O₉
Architecture: Linear tetrapeptide (4 amino acids)
Biological Mechanism
Cardiogen functions as a synthetic tetrapeptide (Ala‑Glu‑Asp‑Arg), engaging myocardial and vascular regulatory pathways to support cardiac resilience and optimize circulatory performance. This cascade promotes balanced myocardial metabolism, enhances oxygen utilization, and contributes to adaptive repair processes under stress conditions.
Key Mechanisms
Myocardial Interaction
Engages cardiomyocytes and vascular cells, supporting contractile efficiency and myocardial integrity.
Protective Signaling Cascade
Modulates intracellular pathways that stabilize mitochondrial energy metabolism and promote adaptive repair responses.
Gene Regulation
Influences expression of cardiac‑related proteins involved in tissue resilience, regeneration, and stress adaptation.
Circulatory Support
Enhances systemic blood flow dynamics and oxygen utilization, contributing to recovery under cardiovascular strain.
Metabolic Benefits
Vascular Support
Enhances circulatory stability, promoting efficient nutrient and oxygen delivery to cardiac and systemic tissues.
Regenerative Adaptation
Stimulates myocardial and vascular repair pathways that contribute to tissue resilience under stress conditions.
Anti‑inflammatory Effect
Modulates inflammatory responses by reducing pro‑inflammatory signaling and supporting balanced cardiovascular recovery.
Research Highlights
Cardiogen demonstrates strong tolerability in investigative research settings, with only mild and short‑lived effects occasionally observed:
Myocardial Resilience
Experimental findings suggest Cardiogen supports cardiomyocyte integrity and adaptive recovery under stress conditions, with potential relevance in age-related cardiac decline.
Mitochondrial Modulation
Preclinical studies highlight stabilization of energy metabolism and improved ATP dynamics in cardiac tissue, contributing to enhanced cellular performance.
Inflammatory Regulation
Research indicates downregulation of pro-inflammatory markers and modulation of NF‑κB signaling, supporting balanced repair in cardiovascular models.
Circulatory Optimization
Investigations show improved blood flow dynamics and oxygen utilization, reinforcing systemic recovery and vascular stability under physiological strain.
Possible Research-Related Effects
Cardiogen exhibits favorable tolerability in research contexts, with minor and short‑duration effects occasionally reported:
Favorable Tolerability
Vesugen exhibits strong tolerability in research contexts, with minor and short-duration effects occasionally reported
Transient Flushing
Brief vasodilatory response observed in select subjects, typically affecting facial or upper thoracic skin.
Low-grade Fatigue
Mild tiredness noted in limited preclinical studies, resolving spontaneously without intervention.
Vascular Sensitivity
Occasional reports of temporary shifts in capillary tone or perfusion dynamics under stress conditions.
It’s important to note that these effects are typically mild and transient in research observations. However, comprehensive long-term safety data is still being collected.
Important Information: This material is restricted to experimental laboratory work and must not be used in humans or animals.
References
Cardiogen Peptide: Studies on cardiac tissues & cancerous cells. Biotech Peptides, 2024. — Usman U.
Cardiogen Peptide Research: Cardiovascular, Fibroblast and Cell Repair. Biolongevity Labs, 2025. — Editorial Team, reviewed by Ky H. Le.
Cardiomyocyte Metabolism Research and Cardiogen Peptide. Atlas of Science, 2023. — Editorial Team.
Cardiogen Peptide: A Promising Tool for Regenerative and Molecular Research. OutsFL Special Content, 2025. — Amelia Ford.
Cardiogen Peptide: A Frontier for Cellular Renewal and Regenerative Inquiry. TFE Times, 2025. — Editorial Team.
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