Basic Guide: CJC-1295

Basic Guide: CJC-1295

Partial explanation (Oct 21, 2009) “Cell-to-cell communication is also likely to reflect the density and proximity of adjacent cells as GH responsiveness (but not sensitivity) to GHRH is enhanced at higher densities and basal GH release is greatest at low densities.”
“Cell-to-cell contact may therefore affect the cellular integrity of somatotrophs because GH synthesis or secretory granule storage may be better maintained in high density cell concentration then in low-density concentrations.” – Growth Hormone, Stephen Harvey What happens is cells in the pituitary communicate. They self organize and create a firing network for coordinated growth hormone release. This communication creates a high density of GH releasing cells. They are in close proximity through their communicatory network. The cells have specific spatial relationships that may be modulated by peripheral endocrines. These include sex steroids, thyroid hormones, glucorticoids and even the pancreatic and gut hormones. Their spatial relationship is also effected by physiological state such as nutrient status, age and pregnancy.
As a quick example, corticotroph, thyrotrophs and folliculostellate cells are in close proximity to somatotrophs and communicate with them through gap junctions (almost like just reaching out and touching signaling). They have the potential to effect and be effected by their neighbors.
What happens when you have GHRH always around is you force these somatotrophs to release GH because they are sensitive to the GHRH binding to them and effecting release. By constantly occupying you are preventing them from coordinating with surrounding cell populations. You force these cells to act as low density subpopulations. Basal GH release is greatest when you can disperse the spatial relationship between somatotrophs and that is what an always on GHRH will do.
CJC-1295 as an always on GHRH will force upon somatotrophs loner behavior with a single constant chore. This reduces GH responsiveness as this only occurs when somatotrophs can communicate, self organize and maintain social relationships with the surrounding community. These types of social somatotrophs are better able to make and store GH then the loner cells.
So CJC-1295 seems to disperse somatotrophs and enslave them getting less from them then if it had just let them congregate in towns and cities.
Aging has an effect on the vitality of city centers as well and as we age these somatotroph population centers become less vigorous. By using a more physiological GHRH such as modified GRF(1-29) together with a modulator GHRP-2 we revitalize that inner city and allow our cells to be more social and thus more productive. If instead we choose to use CJC-1295 we not only fail to remedy the problem associated with age , but we may end up exacerbating it.
I conjecture that it also makes them better neighbors to corticotroph, thyrotrophs and folliculostellate cells as well.

Revision 2 [8/31/08]

Restoring Growth Hormone “It has been argued that the age-dependent decline in sex steroid, Growth Hormone, and IGF-I production is nature’s way of protecting us from cancer and heart disease, but a far more likely scenario is that once we reach our reproductive capacity, nature begins programming us for death.”- Roy G. Smith, Ph.D. Director, Huffington Center on Aging; Professor, Department of Molecular & Cellular Biology; former Vice President for Basic Research at Merck Research Laboratories, Merck & Co Such programming begins as the second decade of life draws to a close, the negative consequences of which become more noticeable with each passing year.
We begin to experience a steady decline in immune function. (1,2) Our bodies increase production of glucocorticoids (catabolic hormones) and cytokines (inflammatory) which negatively impact metabolism, bone density, strength, exercise tolerance, cognitive function, and mood. (3,4–8)
The hormones of sex, dehydroepiandrosterone (DHEA), Growth Hormone (GH), and Insulin-like Growth Factor (IGF-1) are positively correlated with the health and well-being of the body in general and the specific functioning of metabolism, the cardiovascular system, the musculature skeletal system, cognitive function & the immune system. However these hormonal levels naturally decline as we age and as a consequence those systems necessary to maintain optimal health decline as well. (1-4,9)
“Hence, if we wish to maintain quality of life during aging we must oppose nature.” – Roy G. Smith, Ph.D.
A progressive decline in lean body mass, atrophy of its component organs & reduction in their function and increased deposition of adipose tissue mass characteristic of the aging human body result partially from the body’s diminished secretion of growth hormone. (10-13) These negative changes resulting from growth hormone deficiency have been shown to be reversible by replacement doses of growth hormone. (14-21)
Growth Hormone is a vital anabolic hormone whose positive stimulatory effects on protein synthesis (particularly in the liver, muscle, bone, cartlidge, spleen, kidney, skin, thymus, and red blood cells) and on lipolysis (the breakdown of fat stored in fat cells) contributes greatly to growth, repair & well-being. (10)
Growth Hormone (GH) secretion is primarily regulated by the release of two peptides, Growth Hormone-Releasing Hormone (GHRH) andSomatostatin. The hypothalamus region of the brain releases these hormones in response to signals from the central nervous system. GHRH once released makes its way to the receptors on the somatotrope cells of the pituitary gland below the brain where it stimulates Growth Hormone release.
Somatostatin once released makes its way to the receptors on the somatotrope cells of the pituitary gland below the brain where it inhibitsGrowth Hormone release. (15)
The primary physiological action of somatostatin is to inhibit synthesis and release of GH. (16-19) The primary physiological action of Growth Hormone-Releasing Hormone (GHRH) is to stimulate synthesis and release of GH.
The end product of this cascade, Growth Hormone (GH) once secreted exerts its effect in the body as a whole both directly and indirectly through its initiation of Insulin-like Growth Factor (IGF-1) synthesis in the liver. IGF-1 in turn exerts its effect in the body and its rise in turn begins to inhibit any further GH release.
Growth Hormone (GH) is released periodically within the body in a controlled pulsating fashion. This periodic pattern plays an important role in transmitting the GH “growth, repair & well-being” message to tissue. A review of several studies involving GH replacement in GH-deficient animals reveals the biological significance of episodic secretion. These studies conclude that GH released in a pulsatile pattern is far more efficient in improving mammalian growth and repair than the method of GH administration by constant infusion.
In males GH pulses occur approximately every three (3) hours, a frequency that appears across most mammals. The secretion bursts are preceded and followed by almost undetectable levels of plasma GH.
In females however GH pulses occur more frequently and the base level of plasma GH remains higher than males who have fewer GH pulses but the amplitude of which are more pronounced.
GH pulse amplitudes are increased during slow wave sleep such that particularly in males, most GH secretion occurs at night. (22)
Growth Hormone secretion is highest during the growing years of youth and early adulthood. In humans the secretion rate starts to noticeably decrease during the third decade of life and strongly decreases during the fourth decade of life. As we age the daytime secretory pulses diminish first, while the sleep associated GH pulse persists and diminishes gradually.
Nudging Nature
Growth Hormone levels may be increased either by exogenically administering Growth Hormone or by administering Growth Hormone-Releasing Hormone which then endogenically stimulates the somatrope cells of the pituitary to secrete additional Growth Hormone. The primary advantage of GHRH is that GH ends up being released in physiological conformance to the body’s natural biorhythm. This biorhythm is pulsatile.
Studies have concluded that endogenous Growth Hormone Releasing Hormone (GHRH) is the principal regulator of pulsatile GH secretion in humans and that continuous GHRH infusion augments pulsatile GH release. Whereas exogenic administration of GH raises overall GH levels but has no effect on amplifying the pulses.
People of all ages naturally continue to possess the ability to secrete GH from stores within the pituitary. Most studies are in agreement on this point. One study in particular examined the effects of administration of GHRH & a Growth Hormone Releasing Peptide on all adult age groups from those in their 20’s to those above 75 years of age. They observed substantial increases in GH release as a direct result of administration of GHRH & GHRP-6. This prompted them to conclude, “…that the lack of side-effects & safety of the protocol and the discovered lack of age-related decline in the ‘GHRH-GHRP-6-mediated’ GH release opens the possibility of using it as a therapeutical tool to revert some deleterious manifestations of aging in man.” (23)
Long-lasting GHRH analog CJC-1295
While the studies have demonstrated repeatedly that administration of GHRH does increase GH secretion and amplifies the release pulse there does remain a significant drawback. GHRH has a very short half life, measured in minutes with a fairly short clearance rate measured in hours. (24) While this is a sufficient amount of time to exert a positive effect on GH secretion, particularly if GHRH is administered multiple times a day, the result is less than optimal. (25,26)
It is for this reason that longer-lasting analogs of GHRH were researched and developed. (28) The most effective of which is CJC-1295.
Exposure of native GHRH to blood plasma results in rapid degradation. CJC-1295, a synthetic human GHRH analog avoids rapid degradation by possessing the ability to selectively and covalently bind to endogenous albumin after subcutaneous administration. Albumin possesses a half-life of 19 days in humans and so modified GHRH bound to albumin greatly extends its half-life and duration of action. (27)
In a recent (2006) study “Prolonged Stimulation of Growth Hormone (GH) and Insulin-Like Growth Factor I Secretion by CJC-1295, a Long-Acting Analog of GH-Releasing Hormone, in Healthy Adults”, Sam L. Teichman, et al. Journal of Clinical Endocrinology & Metabolism 91(3):799-805, CJC-1295 was found to result in “sustained, dose-dependent increases in GH and IGF-I levels in healthy adults and was safe and relatively well tolerated, particularly at doses of 30mcg/kg or 60 mcg/kg.”
It has been demonstrated repeatedly in various studies that GHRH is effective at instigating GH release and longer acting analogs do increase the overall effectiveness. So it is no surprise that the results of this CJC-1295 study comport with what has been previously demonstrated.
What was unknown was what effect persistent elevation of GH by a long-lasting GHRH analog would have on the pulsatility of release. This was explored in a follow up study, “Pulsatile Secretion of Growth Hormone (GH) Persists during Continuous Stimulation by CJC-1295, a Long- Acting GH-Releasing Hormone Analog”, Madalina Ionescu, et al. The Journal of Clinical Endocrinology & Metabolism 91(12):4792-4797.
That study found that pulsatility was not interfered with and was in fact preserved in all subjects both immediately after administration and continuing 7 days post-administration.
This is obviously a very beneficial characteristic to preserve. In fact episodic release appears to be imperative to growth and repair of tissue in mammals.
The study further found that while growth hormone secretion was increased by almost fifty percent there was no increase in pulse amplitude or frequency. All of the increase came from a substantial elevation of trough levels with preserved pulsatility.
One further note of interest is that study participants were all of young age with lower lean body masses which may indicate that GHRH in the form of CJC-1295 is an effective avenue for growth hormone release for those of young age.
The results of the study charted above show that administration of single doses of CJC-1295 remained in high concentration for 7 days with measurable concentration for 14 subsequent days. (29)
As seen in the chart below this resulted in substantial increases in mean serum GH levels in all dosing groups, which were dose incremental and persisted for up to 7 days.
As seen in the chart below this chronic elevation in CJC-1295 levels resulted in substantial increases in mean serum IGF-1 levels in all dosing groups, which were dose incremental and persisted for up to 7 days.
The results from a toxicology study wherein 50mcg/kg of CJC-1295 was administered subcutaneously to monkeys for a period of six months found no ill effects and no indication of presence of neutralizing antibodies. They concluded that the Drug Affinity Complex (DAC) a technology that enables covalent binding (conjugation) of a drug to albumin produced no evidence of immunogenic or immunotoxic effects in monkeys. (30)
In summary, although the added Drug Affinity Complex adds complexity and increases the expense of CJC-1295 peptide synthesis, it does add tremendously to both the dosing convenience and the biological activity of GHRH without any identifiable adverse toxicity.

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This Article is intended to clarify this topic and in no case as advice, recommendation or other advocacy of misuse!

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