Sermorelin은 소수의 성장 호르몬 방출 호르몬 중 하나입니다.죄) 바람직하지 않은 효과를 피하면서 자연 GHRH의 긍정적 인 효과를 보존하기 위해 최근 몇 년 동안 개발 된 아날로그. Sermorelin (Geref)은 현재 성장 호르몬 분비를 평가하기 위해 임상 적으로 사용되지만 펩티드는 다음의 능력에 추가로 관심이 있습니다.

• 심장 마비 후 흉터를 줄이고
• 뼈 밀도를 높이고
• 만성 질환의 영양 개선,
• 신장 기능 향상,
• 치매의 효과와 싸우십시오
• 발작 활동을 줄입니다.

순서:Tyr-DL-Ala-DL-ASP-DL-Ala-DL-Xiile-DL-PHE-DL-DL-DL-DL-DL-DL-TYR-DL-ARG-DLYS-DL-VAL-DL-LEU-GL Y-DL-GLN-DL-LEU-DL-SER-DL-ALA-DL-ARG-DL-LYS-DL-LEU-DL-LEU-DL-GLN-DL-XIILE-DL-MET-DL-SER-DL-ARG
분자식 :기음₁₄₉시간₂₄₆N₄₄영형₄₂에스
분자량 :3357.933 g/mol
Pubchem CID : 16129620

1. 서리 렐린과 심장 건강

심장 마비는 생명을 위협하지만 심부전에 이차적 인 장기 장애, 심장 전도 이상 (부정맥), 운동 능력 감소, 통증 등을 유발할 수 있습니다. 이러한 문제 중 다수는 근세포 (심장 근육 세포)의 손상을 따르는 심장 리모델링으로 인해 발생합니다. 종종 심장 리모델링은 심장 마비 후 손상 영역에서 흉터가 될뿐만 아니라 주변 지역에서도 손상되지 않은 지역에서도 이어집니다. 이 리모델링은 다수의 장기적인 문제를 일으키고 연구 결과에 따르면 심장 마비 직후와 몇 년이 지날수록 결과가 크게 향상 될 수 있습니다.

2016 년 돼지에 대한 연구에 따르면 Sermorelin 투여는 심장 마비에 따른 리모델링을 줄이는 데 효과적입니다. 연구에 따르면 Sermorelin :

• 심근 세포에서 세포 사멸을 줄이고
• 적절한 치유에 필요한 세포 외 매트릭스 성분의 생성을 증가시킵니다.
• 손상된 조직으로 혈관의 성장을 증가시키고
• 염증이 손상되는 물질의 생성을 줄입니다.

임상 적으로 Sermorelin의 효과는 이완기 기능 향상, 흉터 크기 감소 및 모세관 성장 증가에서 나타납니다.^[1], ^[2]. There is current research exploring the benefits of sermorelin in other forms of heart disease, such as heart failure and even valve disorders.

GHRH treatment reduces scar mass. A. Shows graph of percent change in scar mass over time on top and the relationship between the percent change in scar mass as a percentage of left ventricular mass. B. Shows images of the heart before and after 4 weeks of sermorlin treatment or placebo.

2. Sermorelin and Epilepsy

Gamma-aminobutyric acid (GABA) is a central nervous system signaling molecule known to reduce electrical activity in the spinal cord and reduce overall electrical excitability in the central nervous system. A number of anti-seizure medications work either by increasing levels of GABA in the central nervous system or by binding to GABA receptors and mimicking the effects of GABA. In a recent study of mice with epilepsy, scientists administered GHRH analogues, like sermorelin, to test the effect of these peptides on seizure activity. It turns out that GHRH analogues are effective in suppressing seizures by activating GABA receptors_[3]. This is a very new finding and an active area of research as medications for treating seizure conditions, while effective, have a range of detrimental side effects that reduce their clinical use.

3. Sermorelin and Sleep

There is good evidence that sleep cycles are regulated by orexin, a potent neurochemical produced by certain neurons in the brain. It is also well understood that growth and healing, which are strongly associated with growth hormone secretion, primarily take place during sleep. Research in rainbow trout suggests that this is no coincidence, with an intact GHRH axis being a necessary component for proper orexin secretion and function. In addition, the research reveals that exogenous administration of sermorelin and other GHRH agonists can boost orexin secretion ^[4]. There is ongoing research into the benefits of using sermorelin in sleep disorders.

4. Sermorelin Preferred to Growth Hormone

Sermorelin is a growth hormone releasing hormone derivative and, as such, produces all of the same effects that GH produces, including increasing muscle mass, boosting long bone growth, and reducing adipose tissue. Even though the effects are the same, the side effects are not. In fact, sermorelin is the preferred way to increase GH levels in humans, even over the exogenous administration of growth hormone itself. The primary reason for this preference is that sermorelin is subject to physiological feedback mechanisms that help to prevent common problems encountered with GH administration. These problems include overdose, improper dosing, and unintended side effects like edema, joint pain, and dysregulation of normal physiology^[5].

A second reason to prefer sermorelin is that research shows it is not subject to tachyphylaxis, the process by which the body becomes accustomed to a medication and requires higher and higher doses to achieve desired effects. In some cases, tachyphylaxis is so severe that a drug holiday (complete cessation of use of a medication) is required to regain the effects of a medication. Long-term use of sermorelin in certain clinical settings as well as animal studies of the peptide indicate that the body has a unique response to the peptide. Rather than down-regulate the production of GHRH receptors with administration of sermorelin, the body instead increases their production. This ensures that sermorelin’s effects are unchanged, that tachyphylaxis does not develop to a substantial degree, and that dose escalation is generally not required^[6].

Sermorelin exhibits moderate side effects, low oral and excellent subcutaneous bioavailability in mice. Per kg dosage in mice does not scale to humans. Sermorelin for sale at

The above literature was researched, edited and organized by Dr. Logan, M.D. Dr. Logan holds a doctorate degree from Case Western Reserve University School of Medicine and a B.S. in molecular biology.

Richard F. Walker, Ph.D, R.Ph, lead author of A better approach to management of adult-onset growth hormone insufficiency?”, received a BS in pharmacy from Rutgers University, a MS in Biochemistry from New Mexico State University and a PhD in a physiology from Rutgers University. He holds postdoctoral fellowships in neuroendocrinology and neuropharmacology at Duke University College of Medicine (Center for the Study of Aging and Human Development) and the University of California, Berkeley, respectively.

Richard F. Walker, Ph.D, R.Ph is being referenced as one of the leading scientists involved in the research and development of Sermorelin. In no way is this doctor/scientist endorsing or advocating the purchase, sale, or use of this product for any reason. There is no affiliation or relationship, implied or otherwise, between

1. L. L. Bagno et al., “Growth Hormone–Releasing Hormone Agonists Reduce Myocardial Infarct Scar in Swine With Subacute Ischemic Cardiomyopathy,” J. Am. Heart Assoc. Cardiovasc. Cerebrovasc. Dis., vol. 4, no. 4, Mar. 2015.
2. R. M. Kanashiro-Takeuchi et al., “New therapeutic approach to heart failure due to myocardial infarction based on targeting growth hormone-releasing hormone receptor,” Oncotarget, vol. 6, no. 12, pp. 9728–9739, Mar. 2015.
3. S. Tang et al., “Interactions between GHRH and GABAARs in the brains of patients with epilepsy and in animal models of epilepsy,” Sci. Rep., vol. 7, Dec. 2017.
4. B. S. Shepherd et al., “Endocrine and orexigenic actions of growth hormone secretagogues in rainbow trout (Oncorhynchus mykiss),” Comp. Biochem. Physiol. A. Mol. Integr. Physiol., vol. 146, no. 3, pp. 390–399, Mar. 2007.
5. R. F. Walker, “Sermorelin: A better approach to management of adult-onset growth hormone insufficiency?,” Clin. Interv. Aging, vol. 1, no. 4, pp. 307–308, Dec. 2006.
6. S. T. Wahid, P. Marbach, B. Stolz, M. Miller, R. A. James, and S. G. Ball, “Partial tachyphylaxis to somatostatin (SST) analogues in a patient with acromegaly: the role of SST receptor desensitisation and circulating antibodies to SST analogues,” Eur. J. Endocrinol., vol. 146, no. 3, pp. 295–302, Mar. 2002.

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