20 AET-1 (testosterone buciclate)

Description:

Testosterone buciclate is a more recently developed injectable testosterone preparation, which utilizes the extremely long, highly oil-soluble, and very slow-acting buciclate ester (also commonly referred to as “20 Aet-1′). At 20 carbon atoms in length, the buciclate ester is the largest ester used to make an injectable steroid preparation. It is about seven times longer than propionate, three times longer than enanthate, and double the length of decanoate. Being that the carbon content of the ester correlates closely to the duration of release, testosterone buciclate is also the longest acting injectable testosterone medication yet to be tested in humans. It appears to be even longer acting than Nebido® (testosterone undecanoate), although both drugs are promising a similar 12-week window of therapeutic effect.

When administered to patients suffering from primary hypogonadism as part of initial clinical studies, a single 600 mg injection of testosterone buciclate was able to maintain therapeutically effective concept testosterone for approximately 12 weeks.1

No significant peaks were noted in testosterone levels in either group, which are normally observed with esters like enanthate and cypionate. There were no significant side effects, or unfavorable changes in urine flow, PSA (prostate specific antigen) values, or prostate volume. Testosterone buciclate seems to hold a good deal of promise as a slow-acting injectable androgen, with the potential to replace other common esters used for hormone replacement therapy.

History:

Testosterone buciclate was first described in 1986.2 It was developed as part of a steroid synthesis program that was initiated by the World Health Organization. The focus of this program was to develop longeracting esters of testosterone, which improved on the disadvantages of existing esters such as enanthate and cypionate, which tended to produce short supraphysiological surges in androgen levels, followed by steadily declining and uneven androgen levels until the next point of administration. Phase-l clinical studies were completed in 1992 (described above), and supported the potential adoption of this agent for the treatment of andropause. Studies conducted in years later suggest the drug may also be useful for male contraception.3 Testosterone buciclate has already seen a considerable amount of study at this point, but, unlike its similarly slow-acting cousin Nebido®, has yet to be adopted as a prescription drug for widespread use.

How Supplied:

Testosterone buciclate is not currently available as a commercial drug product.

Structural Characteristics:

Testosterone buciclate is a modified form testosterone, where a carboxylic acid ester (trans-4-n-butylcyclohexy-carboxylate) has been attached to the 17-beta hydroxyl group.

Esterified forms of testosterone are less polar than free testosterone, and are absorbed more slowly from the area of injection. Once in the bloodstream, the ester is removed to yield free (active) testosterone. Esterified forms of testosterone are designed to prolong the window of therapeutic effect following administration, allowing for a less frequent injection schedule compared to injections of free (unesterified) steroid. Testosterone buciclate is designed to maintain physiological levels of testosterone for approximately 12 weeks after injection.

Side Effects (Estrogenic):

Testosterone is readily aromatized in the body to estradiol (estrogen). The aromatase (estrogen synthetase) enzyme is responsible for this metabolism of testosterone. Elevated estrogen levels can cause side effects such as increased water retention, body fat gain, and gynecomastia. Testosterone is considered a moderately estrogenic steroid. An anti-estrogen such as clomiphene citrate or tamoxifen citrate may be necessary to prevent estrogenic side effects. One may alternately use an aromatase inhibitor like Arimidex® (anastrozole), which more efficiently controls estrogen by preventing its synthesis. Aromatase inhibitors can be quite expensive in comparison to antiestrogens, however, and may also have negative effects on blood lipids.

Estrogenic side effects will occur in a dose-dependant manner, with higher doses (above normal therapeutic levels) of testosterone more likely to require the concurrent use of an antiestrogen or aromatase inhibitor. Since water retention and loss of muscle definition are common with higher doses of testosterone, this drug is usually considered a poor choice for dieting or cutting phases of training. Its moderate estrogenicity makes it more ideal for bulking phases, where the added water retention will support raw strength and muscle size, and help foster a stronger anabolic environment.

Side Effects (Androgenic):

Testosterone is the primary male androgen, responsible for maintaining secondary male sexual characteristics. Elevated levels of testosterone are likely to produce androgenic side effects including oily skin, acne, and body/facial hair growth. Men with a genetic predisposition for hair loss (androgenetic alopecia) may notice accelerated male pattern balding. Those concerned about hair loss may find a more comfortable option in nandrolone decanoate, which is a comparably less androgenic steroid. Women are warned of the potential virilizing effects of anabolic/androgenic steroids, especially with a strong androgen such as testosterone. These may include deepening of the voice, menstrual irregularities, changes in skin texture, facial hair growth, and clitoral enlargement.

In androgen-responsive target tissues such as the skin, scalp, and prostate, the high relative androgenicity of testosterone is dependant on its reduction to dihydrotestosterone (DHT). The 5-alpha reductase enzyme is responsible for this metabolism of testosterone. The concurrent use of a 5-alpha reductase inhibitor such as finasteride or dutasteride will interfere with site-specific potentiation of testosterone action, lowering the tendency of testosterone drugs to produce androgenic side effects. It is important to remember that both anabolic and androgenic effects are mediated via the cytosolic androgen receptor. Complete separation of testosterone’s anabolic and androgenic properties is not possible, even with total 5-alpha reductase inhibition.

Side Effects (Hepatotoxicity):

Testosterone does not have hepatotoxic effects; liver toxicity is unlikely. One study examined the potential for hepatotoxicity with high doses of testosterone by administering 400 mg of the hormone per day (2,800 mg per week) to a group of male subjects. The steroid was taken orally so that higher peak concentrations would be reached in hepatic tissues compared to intramuscular injections. The hormone was given daily for 20 days, and produced no significant changes in liver enzyme values including serum albumin, bilirubin, alanineaminotransferase, and alkaline phosphatases.4

Side Effects Cardiovascular):

Anabolic/androgenic steroids can have deleterious effects on serum cholesterol. This includes a tendency to reduce HDL (good) cholesterol values and increase LDL (bad) cholesterol values, which may shift the HDL to LDL balance in a direction that favors greater risk of arteriosclerosis. The relative impact of an anabolic/androgenic steroid on serum lipids is dependant on the dose, route of administration (oral vs. injectable), type of steroid (aromatizable or nonaromatizable), and level of resistance to hepaticmetabolism. Anabolic/androgenic steroids may also adversely effect blood pressure and triglycerides, reduce endothelial relaxation, and support left ventricular hypertrophy, all potentially increasing the risk of cardiovascular disease and myocardial infarction.

Testosterone tends to have a much less dramatic impact on cardiovascular risk factors than synthetic steroids. This is due in part to its openness to metabolism by the liver, which allows it to have less effect on the hepatic management of cholesterol. The aromatization of testosterone to estradiol also helps to mitigate the negative effects of androgens on serum lipids.

In one study, 280 mg per week of testosterone ester (enanthate) had a slight but not statistically significant effect on HDL cholesterol after 12 weeks, but when taken with aromatase inhibitor a strong (25%) decrease was seen.5 Studies using 300 mg of testosterone ester (enanthate) per week for twenty weeks without an aromatase inhibitor demonstrated only a 13% decrease in HDL cholesterol, while at 600 mg the reduction reached 21%.6 The negative impact of aromatase inhibition should be taken into consideration before such drug is added to testosterone therapy.

Due to the positive influence of estrogen on serum lipids, tamoxifen citrate or clomiphene citrate are preferred to aromatase inhibitors for those concerned with cardiovascular health, as they offer a partial estrogenic effect in the liver. This allows them to potentially improve lipid profiles and offset some of the negative effects of androgens. With doses of 600 mg or less per week, the impact on lipid profile tends to be noticeable but not dramatic, making an anti-estrogen (for cardioprotective purposes) perhaps unnecessary. Doses of 600 mg or less per week have also failed to produce statistically significant changes in LDL/VLDL cholesterol, triglycerides, apolipoprotein B/C-III, C-reactive protein, and insulin sensitivity, all indicating a relatively weak impact on cardiovascular risk factors.7 When used in moderate doses, injectable testosterone esters are usually considered to be the safest of all anabolic/androgenic steroids.

To help reduce cardiovascular strain it is advised to maintain an active cardiovascular exercise program and minimize the intake of saturated fats, cholesterol, and simple carbohydrates at all times during active AAS administration. Supplementing with fish oils (4 grams per day) and a natural cholesterol/antioxidant formula such as Lipid Stabil or a product with comparable ingredients is also recommended.

Side Effects (Testosterone Suppression):

All anabolic/androgenic steroids when taken in doses sufficient to promote muscle gain are expected to suppress endogenous testosterone production Testosterone is the primary male androgen, and offers strong negative feedback on endogenous testosterone production. Testosterone-based drugs will, likewise, have a strong effect on the hypothalamic regulation of natural steroid hormones. Without the intervention of testosteronestimulating substances, testosterone levels should return to normal within 1-4 months after has fully cleared the body. Note that hypogonadotrophic hypogonadism can secondary to steroid abuse, necessitating medical intervention.

The above side effects are not inclusive. For more detailed discussion of potential side effects, see the Steroid Side Effects section of this book.

Administration (Men):

To treat androgen insufficiency, clinical protocols support the use of 600 mg every twelve weeks. For bodybuilding purposes, supraphysiological (rather than physiological) hormone levels would require injecting the drug on a more regular basis. The most effective use of this compound in a bodybuilding sense would probably entail the injection of two or more doses of 600 mg in the first two weeks of a cycle. After this point another full dose might be given every 7-15 days, depending on the desired potency or other steroids used. The drug could be discontinued 6-9 weeks before the cycle is going to be concluded, and may cause androgen levels to remain elevated 12 weeks or more after the last dose is given. Post-cycle therapy should be planned accordingly. Testosterone is ultimately very versatile, and can be combined with many other anabolic/androgenic steroids depending on the desired effect.

In the context of bodybuilding, testosterone buciclate will be an effective drug, but it is probably not going to win any awards. For one, a cycle based on this compound would be somewhat slower to start than normal, as it will take time and numerous injections for peak blood levels of testosterone to be reached. For the same reason, testosterone buciclate will end up offering its greatest value in cycles lasting more than 4 or 5 months, where its slow-acting nature may be beneficial by allowing a less frequent injection schedule and greater user comfort. In short cycles, this same trait will just be a hindrance, delaying the achievement of supraphysiological testosterone levels (compared to faster testosterone esters) and a strong anabolic effect.

Administration (Women):

Testosterone buciclate has not been studied in women. This drug is not recommended for women for physique or performanceenhancing purposes due to its strong androgenic nature, tendency to produce virilizing side effects, and very slow-acting characteristics (making blood levels difficult to control).

Availability:

As testosterone buciclate is still really a research drug in Europe, it is not readily available on the black market at this time. It will not be seen in volume until it is adopted for prescription use in a steroids source country, or the various underground labs decide to take an interest in it. Until then, it remains a drug of academic interest only.

1 Testosterone buciclate (20 Aet-1) in hypogonadal men: pharmacokinetics and pharmacodynamics of the new long-acting androgen ester. Behre HM, Nieschlag E. J Clin Endocrinol Metab. 1992 Nov;75(5):1204-10.

2 New injectable testosterone ester maintains serum testosterone of castrated monkeys in the normal range for four months. Weinbauer GF, Marshall GR, Nieschlag E. Acta Endocrinol (1986) 113:128-32.

3 Potential of testosterone buciclate for male contraception: endocrine differences between responders and nonresponders. Behre HM, Baus S, Kliesch S, Keck C, Simoni M, Nieschlag E. J Clin Endocrinol Metab. 1995 Aug;80(8):2394-403.

4 Enzyme induction by oral testosterone. Johnsen SG, Kampmann JP, Bennet EP, Jorgensen F. Clin Pharmacol Ther (1976) 20:233-237.

5 High-density lipoprotein cholesterol is not decreased if an aromatizable androgen is administered. Friedi K, Hannan C et al. Metabolism 39(1) 1990:69-74.

6 Testosterone dose-response relationships in healthy young men. Bhasin S, Woodhouse L et al. Am J Physiol Endocrinol Metab (2001) 281:E117281.

7 The effects of varying doses of T on insulin sensitivity, plasma lipids, apolipoproteins, and C-reactive protein in healthy young men. Singh A, Hsia S, et al. J Clin Endocrinol Metab (2002) 87:136-43.