so for those of us with higher t3 how would implementing a small dose of thyroid inhibition help with bulking mass. T3 is catabolic so by inhibiting it would help to gain mass. I wouldn’t recommend anyone ever mess with their thyroid for any reason but if you’re a “hard gainer” I wonder how this could be used.
I thought of this after seeing this post on trenbolone. And this is the reason I enjoyed tren the last time I ran it I felt like my body didn’t constantly need a protein shake to retain mass.
———
Here is an avenue that has not been explored in this thread: The potential relationship between trenbolone, thyrotropin-releasing hormone (TRH) and prolactin. TRH stimulates the synthesis and release of thyrotropin (thyroid stimulating hormone) from the pituitary. Thyrotropin in turn stimulates the release of the thyroid hormones. A negative feedback loop exists whereby low levels of T4 stimulate the release of TRH (1).
It has been established that in humans TRH is also capable of stimulating the release of prolactin (2). In hypothyroid patients there is often an elevation of TRH and prolactin due to diminished levels of T4. (3) Galactorrhea often presents as a symptom of hypothyroidism.
In sheep, administration of trenbolone acetate results in 45% decrease in thyroxine levels (4). This should exert a stimulatory effect on TRH. ( Interestingly, the same study shows that unlike in humans prolactin levels in the sheep remained unchanged. This is due to the fact that in sheep, unlike in humans, TRH and prolactin are secreted independently of each other (5).)
If it assumed that trenbolone acetate also lowers thyroxine levels in humans, the resulting rise in TRH would stimulate prolactin release, leading to galactorrhea and gynecomastia.
Due to the lack of human studies involving tren, we are all forced to speculate, and try to extrapolate from animal studies.
(1)Endocrinology 1999 Jan;140(1):43-9
Feedback regulation of thyrotropin-releasing hormone gene expression by thyroid hormone in the caudal raphe nuclei in rats.
Yang H, Yuan P, Wu V, Tache Y.
Digestive Diseases Research Center, West Los Angeles VA Medical Center, Department of Medicine and Brain Research Institute, UCLA, California 90073, USA. hoyang@ucla.edu
(2)Goodman and Gilman's The Pharmacological Basis of Therapeutics 8th ed. pp.1345-1346
(3) : Endocr J 1997 Feb;44(1):89-94
Incidence of hyperprolactinemia in patients with Hashimoto's thyroiditis.
Notsu K, Ito Y, Furuya H, Ohguni S, Kato Y.
Department of Medicine, Shimane Prefectural Central Hospital, Izumo, Japan.
(4)Res Vet Sci 1981 Jan;30(1):7-13
Growth hormone, insulin, prolactin and total thyroxine in the plasma of sheep implanted with the anabolic steroid trenbolone acetate alone or with oestradiol.
Donaldson IA, Hart IC, Heitzman RJ.
(5) Endocrinol 1988 Apr;117(1):115-22
Release of prolactin is independent of the secretion of thyrotrophin-releasing hormone into hypophysial portal blood of sheep.
Thomas GB, Cummins JT, Yao B, Gordon K, Clarke IJ.
Medical Research Centre, Prince Henry's Hospital, Melbourne, Australia.
--------------------------------------------------------------------------------
Yes, finally!!! you hit the nail right on the head.
Fina is a VERY POWERFUL anti-glucocorticoid, so what
exactly does it do to reduce endogeneous cortisone
levels?
There is only ONE mechanism:
A reduction in the TOTAL Free T4 and T3 levels within the
body.
T3 is HIGHLY catabolic to muscle, therefore by reducing it by(
take 45% as shown by Nandi as an example), you are
exerting a ridiculously high protein-sparing effect.
YES, thats right, Fina is not THAT anabolic IN VIVO, it is
far, and I do mean FAR more of an ANTI-CATABOLIC
AAS than anything else.
Ok, now lets back-track to the problem at hand.
TSH has been reduced by the trenbolone, which in
turns signals the thyroid to reduce endogeneously
produced levels of T3 and T4.
This reduction(As Nandi mentioned) causes a VERY
sharp drop in free T3 levels because of the reduction
in both the endogeneously produced T4 and T3.
(Remember that 80% of the free T3 is produced from
the metabolically inactive T4)
These dimished levels of T3,T4 cause Thyrotropin Releasing
Hormone(TRH) to become OVER-STIMULATED.
In essence, this is your bodies feed-back loop to reduced
thyroid hormones, due to a GLUCO-CORTICOID suppresive
effect. This is however NOT like hypothyroidic patients
who have a naturally defective(or damaged) thyroid.
I thought of this after seeing this post on trenbolone. And this is the reason I enjoyed tren the last time I ran it I felt like my body didn’t constantly need a protein shake to retain mass.
———
Here is an avenue that has not been explored in this thread: The potential relationship between trenbolone, thyrotropin-releasing hormone (TRH) and prolactin. TRH stimulates the synthesis and release of thyrotropin (thyroid stimulating hormone) from the pituitary. Thyrotropin in turn stimulates the release of the thyroid hormones. A negative feedback loop exists whereby low levels of T4 stimulate the release of TRH (1).
It has been established that in humans TRH is also capable of stimulating the release of prolactin (2). In hypothyroid patients there is often an elevation of TRH and prolactin due to diminished levels of T4. (3) Galactorrhea often presents as a symptom of hypothyroidism.
In sheep, administration of trenbolone acetate results in 45% decrease in thyroxine levels (4). This should exert a stimulatory effect on TRH. ( Interestingly, the same study shows that unlike in humans prolactin levels in the sheep remained unchanged. This is due to the fact that in sheep, unlike in humans, TRH and prolactin are secreted independently of each other (5).)
If it assumed that trenbolone acetate also lowers thyroxine levels in humans, the resulting rise in TRH would stimulate prolactin release, leading to galactorrhea and gynecomastia.
Due to the lack of human studies involving tren, we are all forced to speculate, and try to extrapolate from animal studies.
(1)Endocrinology 1999 Jan;140(1):43-9
Feedback regulation of thyrotropin-releasing hormone gene expression by thyroid hormone in the caudal raphe nuclei in rats.
Yang H, Yuan P, Wu V, Tache Y.
Digestive Diseases Research Center, West Los Angeles VA Medical Center, Department of Medicine and Brain Research Institute, UCLA, California 90073, USA. hoyang@ucla.edu
(2)Goodman and Gilman's The Pharmacological Basis of Therapeutics 8th ed. pp.1345-1346
(3) : Endocr J 1997 Feb;44(1):89-94
Incidence of hyperprolactinemia in patients with Hashimoto's thyroiditis.
Notsu K, Ito Y, Furuya H, Ohguni S, Kato Y.
Department of Medicine, Shimane Prefectural Central Hospital, Izumo, Japan.
(4)Res Vet Sci 1981 Jan;30(1):7-13
Growth hormone, insulin, prolactin and total thyroxine in the plasma of sheep implanted with the anabolic steroid trenbolone acetate alone or with oestradiol.
Donaldson IA, Hart IC, Heitzman RJ.
(5) Endocrinol 1988 Apr;117(1):115-22
Release of prolactin is independent of the secretion of thyrotrophin-releasing hormone into hypophysial portal blood of sheep.
Thomas GB, Cummins JT, Yao B, Gordon K, Clarke IJ.
Medical Research Centre, Prince Henry's Hospital, Melbourne, Australia.
--------------------------------------------------------------------------------
Yes, finally!!! you hit the nail right on the head.
Fina is a VERY POWERFUL anti-glucocorticoid, so what
exactly does it do to reduce endogeneous cortisone
levels?
There is only ONE mechanism:
A reduction in the TOTAL Free T4 and T3 levels within the
body.
T3 is HIGHLY catabolic to muscle, therefore by reducing it by(
take 45% as shown by Nandi as an example), you are
exerting a ridiculously high protein-sparing effect.
YES, thats right, Fina is not THAT anabolic IN VIVO, it is
far, and I do mean FAR more of an ANTI-CATABOLIC
AAS than anything else.
Ok, now lets back-track to the problem at hand.
TSH has been reduced by the trenbolone, which in
turns signals the thyroid to reduce endogeneously
produced levels of T3 and T4.
This reduction(As Nandi mentioned) causes a VERY
sharp drop in free T3 levels because of the reduction
in both the endogeneously produced T4 and T3.
(Remember that 80% of the free T3 is produced from
the metabolically inactive T4)
These dimished levels of T3,T4 cause Thyrotropin Releasing
Hormone(TRH) to become OVER-STIMULATED.
In essence, this is your bodies feed-back loop to reduced
thyroid hormones, due to a GLUCO-CORTICOID suppresive
effect. This is however NOT like hypothyroidic patients
who have a naturally defective(or damaged) thyroid.
