| Identification | More | [Name]
Testosterone propionate | [CAS]
57-85-2 | [Synonyms]
17-(1-oxopropoxy)-(17b)-androst-4-en-3-one
17BETA-HYDROXY-4-ANDROSTEN-3-ONE 17-PROPIONATE
17BETA-PROPIONYLOXY-4-ANDROSTEN-3-ONE
4-ANDROSTEN-17BETA-OL-3-ONE 17-PROPIONATE
4-ANDROSTEN-17-BETA-OL-3-ONE PROPIONATE
PROPIONIC ACID (8R,9S,10R,13S,14S,17S)-10,13-DIMETHYL-3-OXO-2,3,6,7,8,9,10,11,12,13,14,15,16,17-TETRADECAHYDRO-1H-CYCLOPENTA[A]PHENANTHREN-17-YL ESTER
TESTOSTERON 17-PROPIONATE
TESTOSTERONE 17-PROPIONATE
TESTOSTERONE PROPIONATE
17-(1-oxopropoxy)-(17-beta)-androst-4-en-3-on
17-[(1-Oxopropanoyl)oxy]androst-4-en-3-one
3-Oxoandrost-4-en-17-yl propionate
Agovirin
Androgen
Androlon
Andronate
Androsan
Androst-4-en-3-one, 17-(1-oxopropoxy)-, (17beta)-
Androst-4-en-3-one, 17beta-hydroxy-, propionate
Androsteston | [EINECS(EC#)]
200-351-1 | [Molecular Formula]
C22H32O3 | [MDL Number]
MFCD00003653 | [Molecular Weight]
344.49 | [MOL File]
57-85-2.mol |
| Safety Data | Back Directory | [Hazard Codes ]
T | [Risk Statements ]
R45:May cause cancer.
R22:Harmful if swallowed.
R63:Possible risk of harm to the unborn child. | [Safety Statements ]
S53:Avoid exposure-obtain special instruction before use .
S36/37:Wear suitable protective clothing and gloves .
S45:In case of accident or if you feel unwell, seek medical advice immediately (show label where possible) . | [RIDADR ]
2811 | [WGK Germany ]
3
| [RTECS ]
XA3115000
| [HS Code ]
29372900 | [Safety Profile]
with experimental neoplastigenic, tumorigenic, and teratogenic data. Moderately toxic by ingestion and wintraperitoneal routes. Human male reproductive effects by intramuscular and parenteral routes: changes in spermatogenesis, testes, epid~dpmis, and sperm duct. Human female reproductive effects by intramuscular and parenteral routes: menstrual cycle changes or disorders and effects on ferthty. Experimental reproductive effects. Mutation data reported. When heated to decomposition it emits acrid smoke and irritating fumes. See also TESTOSTERONE. | [Toxicity]
LD50 oral in rat: 1gm/kg |
| Hazard Information | Back Directory | [General Description]
Odorless white or yellowish-white crystals or a white or creamy-white crystalline powder. | [Reactivity Profile]
TESTOSTERONE PROPIONATE(57-85-2) is sensitive to light. Incompatible with alkalis and oxidizing agents. . | [Air & Water Reactions]
Insoluble in water. | [Fire Hazard]
Flash point data for this chemical are not available; however, TESTOSTERONE PROPIONATE is probably combustible. | [Chemical Properties]
White or almost white powder or colourless crystals. | [Uses]
Anabolic steroid. Androgen.
Controlled substance. | [Uses]
androgen, antineoplastic | [Definition]
ChEBI:Testosterone propionate is a steroid ester. | [Brand name]
Andro heart injecta;Androfort;Androlan in oils;Cortrifosal;Durateston v;Encilcort;Galanrent;Gondrone;Gyno-terazol;Hermo m;Jeifer-old;Malogen in oil;Malotrone;Micro-sterandryl;Napionate;Orchisterone-p;Pantesin;Perandern;Pertesis;Sterotest;Sutanone;Tesrina;Testanderogen;Testenat;Testigrmon;Testilen;Testirene;Testoici;Testoidral;Testonate;Testopinate;Testo-retard;Testoviron (ampule);Testoviron-10/-25/-50;Testoviron-depot-50/-100;Testovis;Testron;Tostrina;Triomone;Vantostol-p;Viromon. | [World Health Organization (WHO)]
In 1982, low dosage preparations of testosterone propionate, a
synthetic ester of the naturally-occurring androgen, testosterone, were prohibited
in Bangladesh following their inadmissable promotion as anabolic agents for use
in malnourished children. Higher dosage preparations of testosterone propionate
remain available in many countries, including Bangladesh, for several highly
specific but limited indications including hypogonadism and the palliative
treatment of inoperable breast cancer. | [Biochem/physiol Actions]
Androgens direct the development of the male phenotype during embryogenesis and at puberty. Testosterone is an androgen that is secreted by the testis. This hormone is converted to dihydrotestosterone in the target tissues where it regulates several biological functions. Testosterone propionate has been synthetically derived from a plant. This product has extended and faster-acting functions when compared to other testosterone esters. | [storage]
Store at -20°C | [Purification Methods]
Crystallise the propionate from aqueous EtOH, or Et2O/pet ether (m 121o), and it has max at 240nm (EtOH), and [�] 20 +114o (c 1, CHCl3). Also purify it by HPLC. [Ercol & de Ruggieri J Am Chem Soc 75 650, 652 1953, polymorphism: Brandst.tter-Kuhnert & Kofler Mickokim Acta 847, 850 1959, Beilstein 8 IV 977.] |
| Questions And Answer | Back Directory | [Overview]
Testosterone propionate, sold under the brand name Testoviron among others, is an androgen and anabolic steroid(AAS) medication that is used mainly in the treatment of low testosterone levels in men. Anabolic androgenic steroids(AAS) were originally developed in the late 1930s and used since 1950s to improve athletic performance, male physical attractiveness and improves body image for both sexes[1]. Athletes use AAS to increase strength, lean body mass, and, in some cases, improve physical appearance[2]. Accordingly, AAS increase body weight, fat-free mass, muscle size and strength training in healthy men receiving 600 mg of testosterone weekly for 10 weeks[3-5]. In the absence of strength training the muscle size is increased by higher doses of AAS[3,4].
Figure 1 the chemical structure of testosterone propionate | [Applications]
Testosterone propionate is often used for muscle mass building. The original medical indication is for the treatment of androgen deficiency in male adults either in hypogonadism or andropaus[7]. Nowadays testosterone propionate is indicated for its use in heifers in order to stimulate maximal growth[6].
Hypogonadism(the late puberty and premature termination of adolescent growth, some types of impotence) is the most common indication for AAS therapy in men. At present, The United States Food and Drug Administration(FDA) approved clinical use of AAS for treatment of hypogonadism, anemia accompanying renal and bone marrow failure, endometriosis, cancer and wasting syndrome in human immunodeficiency virus infection[8,9]. The other clinical uses of AAS include treatment of catabolic states and cachexia(i.e chronic obstructive pulmonary disease), corticosteroid therapy, osteoporosis, growth stimulation in male puberty, prophylaxis for hereditary angioedema, hepatic disease, and female to male transsexualism, hypoplastic anemia, multiple sclerosis, sexual dysfunction and depression.
Testosterone is also available in several different pharmaceutical formulations and is recommended for use in veterinary medicine to treat chronic wasting conditions and improve appetite and physical appearance. In addition, veterinary compounding pharmacies offer for sale numerous testosterone ester preparations in oil and testosterone suspension in aqueous vehicle[10-12].
| [Pharmacodynamics]
The administration of testosterone propionate can induce production of proteins related to male sexual development. On the other hand, testosterone itself present an estrogenic activity due to interaction with aromatase enzyme, thus the continuous administration of testosterone propionate may cause the elevation of plasma estrogen. Clinical trials showed as well, a decrease in plasma LH after testosterone propionate administration[13].
| [Mode of action]
Anabolic steroids are thought to exert their actions by several different mechanisms. These mechanisms include modulating androgen receptor expression as a consequence of[i] intracellular metabolism and by[ii] directly affecting the topology of the androgen receptor and thus subsequent interaction with co-activators and transcriptional activity. Other mechanisms include[iii] an anticatabolic effect by interfering with glucocorticoid receptor expression; and[iv] by non-genomic, as well as by genomic pathways, in the CNS resulting in behavioural changes. These mechanisms are discussed herein. Free testosterone[T] is transported into the cytoplasm of target tissue cells, further binding to the androgen receptor, or being reduced to 5alpha-dihydrotestosterone(DHT) by the cytoplasmic enzyme 5alpha-reductase. The binding areas are called hormone response elements(HREs), and influence transcriptional activity of certain genes, producing the androgen effects.[14-16]
| [The relation to obesity]
Several studies have demonstrated an inverse relationship between indicators of obesity(body mass index, waist circumference, a reliable indicator of visceral obesity), and testosterone levels over all age groups[15-17]. Obesity contributes to onset of type II diabetes mellitus(T2DM), dyslipidemia, hypertension and, therefore, MetS. An inverse association between the severity of features of MetS, T2DM and plasma testosterone has been previously reported[18]. In one study, this association was independent of age and body mass index[19], underlining the complexity of the relationship between testosterone and obesity[20]. This became also apparent from another study that verified the prevalence of low testosterone levels in male T2DM patients, related to variations in BMI, waist circumference, neuropathy, triglycerides, CRP, glucose, insulin and HOMAIR, but no increase of silent myocardial ischemia or peripheral arterial disease was established[21]. This is supported by other studies linking low testosterone, cardiovascular risk and insulin resistance(for review[22]). Although age is associated with the prevalence of MetS, young men with features of the MetS exhibit reduced testosterone levels[23, 24] and testosterone treatment in these individuals positively affects weight reduction, with concomitant reduction in insulin resistance(IR). The exact pathophysiological mechanisms responsible for reduced testosterone levels in obesity remain under investigation[15], however, hyperinsulinemia is shown to suppress serum testosterone levels[25]. Testosterone levels are reduced in men with T2DM, with an inverse association between testosterone levels and glycosylated hemoglobin(HbA1c)[26] and this occurs independently of medications, such as statins[27]. In men with low plasma testosterone, the likelihood of T2DM is increased and several large prospective studies have shown that low T testosterone levels predict development of T2DM in men. Low levels of testosterone are associated with a decreased lean body mass, and relative muscle mass is inversely associated with insulin resistance and prediabetes[28].
| [Adverse reactions and precaution]
Testosterone propionate is a kind of AAS. The most common reversible side effect of AAS is cosmetic in nature. The orally used AAS may cause hepatotoxicity. However there is no report describing hepatotoxicity due to use of parenteral AAS preparations, which appear to damage heart muscles in long-term use[29]. There are several side effects of AAS use such as; headaches, gastrointestinal irritation, fluid retention in the extremities, diarrhea, stomach pains, oily skin. Additionally jaundice, menstrual abnormalities, hypertension and infections at injection site may be observed. Acne develops in both sexes at puberty during treatment with AAS due to secretion of the natural oil sebum and growth of sebaceous glands[30]. Males using high doses of AAS may have elevated circulating estrogen levels similar to women during a normal menstral cycle. This effect is result of aromatization of testosterone in part to estrogens. Therefore, gynecomastia and breast pain may be observed in men taking high doses of AAS[31].
Chronic adverse effects associated with AAS abuse include acne, urogenital problems, endocrine abnormalities, neuropsychiatric disorders, hepatic and cardiovascular diseases. Acne is common adverse effect of AAS use seen in almost 50% of the androgen uses. Acne fulminans and acne conglobata are the most common forms of acne associated with AAS[32]. Subjects using AAS should be warned that acne associated with AAS can get worse with vitamin B supplement[32]. Gynecomastia and suppression of spermatogenesis are frequent consequences of AAS use. High dose of AAS suppresses the hypothalamic-pituitary-gonadal axis due to negative feedback and, it may take weeks or months for the axis to recover. Consequently atrophy of the seminiferous tubules during this time may result in subfertility or infertility[33]. Furthermore, subjects may continue to encounter symptoms of hypogonadism[erectile dysfunction, low libido and low vitality] even after discontinuation of AAS until the axis recovers. Recent reports suggest that use of clomiphene citrate may hasten the recovery of gonadal axis[34].
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| Questions and Answers (Q&A) | Back Directory | [References]
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- Sullivan ML, Martinez CM, Gennis P, Gallagher EJ, The cardiac toxicity of anabolic steroids, Prog Cardiovasc Dis, 41, 1–15, 1998.
- Bhasin S, Storer TW, Berman N, Callegari C, Clevenger B, Phillips J, Bunnell TJ, Tricker, R, Shirazi A, Casaburi R, The effects of supraphysiologic doses of testosterone on muscle size and strength in normal men, N Engl J Med, 335, 1–7, 1996.
- Forbes GB, The effect of anabolic steroids on lean body mass: the dose response curve, Metabolism, 34, 571–573, 1985.
- Young NR, Baker HW, Liu G, Seeman E, Body composition and muscle strength in healthy men receiving testosterone enanthate for contraception, J Clin Endocrinol Metab, 77, 1028– 1032, 1993.
- Lapauw B, Goemaere S, Crabbe P, Kaufman JM, Ruige JB: Is the effect of testosterone on body composition modulated by the androgen receptor gene CAG repeat polymorphism in elderly men? Eur J Endocrinol. 2007 Mar; 156(3]: 395-401.
- Yin D, Gao W, Kearbey JD, Xu H, Chung K, He Y, Marhefka CA, Veverka KA, Miller DD, Dalton JT: Pharmacodynamics of selective androgen receptor modulators. J Pharmacol Exp Ther. 2003 Mar; 304(3]: 1334-40.
- Saseen J, MacLaughlin EJ, Appetite stimulants and anabolic steroid therapy for AIDS wasting, AIDS Read, 9, 398, 401–402, 407, 1999.
- Basaria S, Wahlstrom JT, Dobs AS, Clinical review 138: Anabolic androgenic steroid therapy in the treatment of chronic diseases, J Clin Endocr Metab, 86, 5108 –5117, 2001.
- Maher, J., Squires, E., Voss, J. & Shideler, R.[1983] Effect of anabolic steroids on reproductive function of young mares. Journal of American Veterinary Medical Association, 183, 519–524.
- Pitts, S. & Davis, M.[2007] An evidence-based analysis of anabolic steroids as performance enhancers in horses. Equine Veterinary Education, 19, 388–391.
- Fajt, V. & McCook, C.[2008] An evidence-based analysis of anabolic steroids as therapeutic agents in horses. Equine Veterinary Education,20, 542–544.
- Fujioka M, Shinohara Y, Baba S, Irie M, Inoue K: Pharmacokinetic properties of testosterone propionate in normal men. J Clin Endocrinol Metab. 1986 Dec;63(6]:1361-4. doi: 10.1210/jcem-63-6-1361.
- Cato AC, Nestl A, Mink S[2002]. Rapid actions of steroid receptors in cellular signaling pathways. Sci STKE 2002: RE9.
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- Traish AM, Saad F, Guay A. The dark side of testosterone deficiency: II. Type 2 diabetes and insulin resistance. J Androl 2009; 30: 23-32.
- Corona G, Mannucci E, Ricca V, et al. The age-related decline of testosterone is associated with different specific symptoms and signs in patients with sexual dysfunction. Int J Androl 2009; 32: 720-8.
- Dhindsa S, Miller MG, McWhirter CL, et al. Testosterone concentrations in diabetic and nondiabetic obese men. Diabetes Care 2010; 33: 1186-92.
- Corona G, Monami M, Rastrelli G, et al. Testosterone and metabolic syndrome: a meta-analysis study. J Sex Med 2011; 8: 272-83.
- Cattabiani C, Basaria S, Ceda GP, et al. Relationship between Testosterone deficiency and Cardiovascular risk and Mortality in Adult Men. J Endocrinol Invest Nov 8. [Epub ahead of print] 2011.
- Hernandez-Mijares A, Garcia-Malpartida K, Sola-Izquierdo E, et al. Testosterone levels in males with type 2 diabetes and their relationship with cardiovascular risk factors and cardiovascular disease. J Sex Med 2010; 7: 1954-64.
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