Testosterone was first isolated in 1935, and approved for medical use in 1939.[12][13] Rates of use have increased three times in the United States between 2001 and 2011.[14] It is on the World Health Organization's List of Essential Medicines.[15] It is available as a generic medication.[9] In 2022, it was the 118th most commonly prescribed medication in the United States, with more than 5million prescriptions.[16][17]
The primary use of testosterone is the treatment of males with too little or no natural testosterone production, also termed male hypogonadism or hypoandrogenism (androgen deficiency).[18] This treatment is referred to as hormone replacement therapy (HRT), or alternatively, and more specifically, as testosterone replacement therapy (TRT) or androgen replacement therapy (ART). It is used to maintain serum testosterone levels in the normal male range. Decline of testosterone production with age has led to interest in testosterone supplementation.[19]
A 2020 guideline from the American College of Physicians supports the discussion of testosterone in adult men with age-related low levels of testosterone who have sexual dysfunction. They recommend yearly evaluation regarding possible improvement and, if none, to discontinue testosterone; physicians should consider intramuscular treatments, rather than transdermal treatments, due to costs and since the effectiveness and harm of either method is similar. Testosterone treatment for reasons other than possible improvement of sexual dysfunction may not be recommended.[20][21]
Testosterone deficiency (also termed hypotestosteronism or hypotestosteronemia) is an abnormally low testosterone production. It may occur because of testicular dysfunction (primary hypogonadism) or hypothalamic–pituitary dysfunction (secondary hypogonadism) and may be congenital or acquired.[22]
Notes: Men produce about 3 to 11 mg of testosterone per day (mean 7 mg/day in young men). Footnotes:a = Never marketed. b = No longer used and/or no longer marketed. Sources: See template.
Testosterone levels may decline gradually with age.[23][24] The United States Food and Drug Administration (FDA) stated in 2015 that neither the benefits nor the safety of testosterone supplement have been established for low testosterone levels due to aging.[11] The FDA has required that labels on testosterone include warnings about increased risk of heart attacks and stroke.[11]
A 2014 systematic review and meta-analysis of 35 studies consisting of over 5,000 postmenopausal women with normal adrenal gland function found that testosterone therapy was associated with significant improvement in a variety of domains of sexual function.[38] These domains included frequency of sexual activity, orgasm, arousal, and sexual satisfaction, among others.[38] Women who were menopausal due to ovariectomy showed significantly greater improvement in sexual function with testosterone relative to those who had normal menopause.[38] In addition to beneficial effects on sexual function, testosterone was associated with unfavorable changes in blood lipids.[38] These included decreased levels of total cholesterol, triglycerides, and high-density lipoprotein (HDL) cholesterol, and increased levels of low-density lipoprotein (LDL) cholesterol.[38] However, the changes were small in magnitude, and the long-term significance in relation to cardiovascular outcomes is uncertain.[38] The changes were more pronounced with oral testosterone undecanoate than with parenteral routes, such as transdermal testosterone.[38] Testosterone showed no significant effect on depressedmoodanxiety, bone mineral density (BMD), or anthropomorphic measures like body weight or body mass index.[38] Conversely, it was associated with a significant incidence of androgenic side effects, including acne and hirsutism (excessive facial/body hair growth).[38] Other androgenic side effects, such as weight gain, pattern hair loss, and voice deepening, were also reported in some trials, but were excluded from analyses due to insufficient data.[38] The overall quality of the evidence was rated as low and was considered to be inconclusive in certain areas, for instance on long-term safety.[38]
A subsequent 2017 systematic review and meta-analysis of studies including over 3,000 postmenopausal women with HSDD similarly found that short-term transdermal testosterone therapy was effective in improving multiple domains of sexual function.[39] Androgenic adverse effects such as acne and hirsutism were significantly greater in incidence with testosterone therapy, whereas no significant differences in "increase in facial hair, alopecia, voice deepening, urinary symptoms, breast pain, headache, site reaction to the patch, total adverse events, serious adverse events, reasons for withdrawal from the study, and the number of women who completed the study" were seen relative to controls.[39]
Although testosterone has been found to be effective at improving sexual function in postmenopausal women, the doses employed have been supraphysiological.[40][41] In contrast to these high doses, there is little support for the notion that testosterone is a critical hormone for sexual desire and function in women under normal physiological circumstances.[40][41] Low doses of testosterone resulting in physiological levels of testosterone (<50 ng/dL) have not been found to significantly increase sexual desire or function in women in most studies.[40] Similarly, there appears to be little or no relationship between total or free testosterone levels in the normal physiological range and sexual desire in premenopausal women.[41][40] Only high doses of testosterone resulting in supraphysiological levels of testosterone (>50 ng/dL) significantly increase sexual desire in women, with levels of testosterone of 80 to 150 ng/dL "slightly" increasing sex drive.[40][41] In accordance, men experience sexual dysfunction at testosterone levels of below 300 ng/dL, and men that have levels of testosterone of approximately 200 ng/dL frequently experience such problems.[41] The high doses of testosterone required to increase sexual desire in women may have a significant risk of masculinization with long-term therapy.[41][40] For this reason, and due to the unknown health effects and safety of testosterone therapy, its use may be inappropriate.[41][40] In 2003, the FDA rejected Intrinsa, a 300 μg/day testosterone patch for the treatment of sexual dysfunction in postmenopausal women.[40][41] The reasons cited were limited efficacy (about one additional sexually satisfying event per month), concerns about safety and potential adverse effects with long-term therapy, and concerns about inappropriate off-label use.[40][41] It appears that in women, rather than testosterone, estradiol may be the most important hormone involved in sexual desire, although data on the clinical use of estradiol to increase sexual desire in women is limited.[40][42][43]
There are no testosterone products approved for use in women in the United States and many other countries.[44] There are approved testosterone products for women in Australia, where it is considered a drug of dependence, medicines that are subject to misuse and trafficking, [45] and some European countries.[44] Testosterone pellet implants are approved for use in postmenopausal women in the United Kingdom.[46][47] Testosterone products for men can be used off-label in women in the United States.[44] Alternatively, testosterone products for women are available from compounding pharmacies in the United States, although such products are unregulated and manufacturing quality is not ensured.[48]
Notes:Premenopausal women produce about 230 ± 70 μg testosterone per day (6.4 ± 2.0 mg testosterone per 4 weeks), with a range of 130 to 330 μg per day (3.6–9.2 mg per 4 weeks). Footnotes:a = Mostly discontinued or unavailable. b = Over-the-counter. Sources: See template.
^This table does not include combination products with other medications/hormones. The availability of specific products may vary by country - see Testosterone (medication) § Availability.
^These dosages may be given at varying frequencies - dosages listed are "each" (ex: per tablet, per spray, etc) and not indicative of total daily dose or equivalent.
^Other brand names may be currently or historically marketed.
Testosterone is used as a form of doping among athletes in order to improve performance.[65] Testosterone is classified as an anabolic agent and is on the World Anti-Doping Agency (WADA) List of Prohibited Substances and Methods.[65] Hormone supplements cause the endocrine system to adjust its production and lower the natural production of the hormone, so when supplements are discontinued, natural hormone production is lower than it was originally.[citation needed]
Anabolic–androgenic steroids (AAS), including testosterone and its esters, have also been taken to enhance muscle development, strength, or endurance. They do so directly by increasing the muscles' protein synthesis. As a result, muscle fibers become larger and repair faster than the average person's.[citation needed]
After a series of scandals and publicity in the 1980s (such as Ben Johnson's improved performance at the 1988 Summer Olympics), prohibitions of AAS use were renewed or strengthened by many sports organizations. Testosterone and other AAS were designated a "controlled substance" by the United States Congress in 1990, with the Anabolic Steroid Control Act.[66] Their use is seen as an issue in modern sport, particularly given the lengths to which athletes and professional laboratories go to in trying to conceal such use from sports regulators. Steroid use once again came into the spotlight as a result of Canadian professional wrestlerChris Benoit's double murder-suicide in 2007; however, there is no evidence implicating steroid use as a factor in the incident.[citation needed]
Some female athletes may have naturally higher levels of testosterone than others, and may be asked to consent to sex verification and either surgery or drugs to decrease testosterone levels.[67] This has proven contentious, with the Court of Arbitration for Sport suspending the IAAF policy due to insufficient evidence of a link between high androgen levels and improved athletic performance.[68][69]
Detection of abuse
A number of methods for detecting testosterone use by athletes have been employed, most based on a urine test. These include the testosterone/epitestosterone ratio (normally less than 6), the testosterone/luteinizing hormone ratio and the carbon-13/carbon-12 ratio (pharmaceutical testosterone contains less carbon-13 than endogenous testosterone). In some testing programs, an individual's own historical results may serve as a reference interval for interpretation of a suspicious finding. Another approach being investigated is the detection of the administered form of testosterone, usually an ester, in hair.[70][71][72][73]
The FDA stated in 2015 that neither the benefits nor the safety of testosterone have been established for low testosterone levels due to aging.[11] The FDA has required that testosterone pharmaceutical labels include warning information about the possibility of an increased risk of heart attacks and stroke.[11] They have also required the label include concerns about abuse and dependence.[83]
Injectable forms of testosterone can cause a lung problem called pulmonary oil microembolism (POME). Symptoms of POME include cough, shortness of breath, tightening of the throat, chest pain, sweating, dizziness, and fainting.[84][85] A postmarketing analysis by the manufacturer of Aveed (testosterone undeconate injection) found that POME occurred at a rate of less than 1% per injection per year for Aveed.[86]
Adverse effects of testosterone supplementation may include increased cardiovascular events (including strokes and heart attacks) and deaths based on three peer-reviewed studies involving men taking testosterone replacement.[87] In addition, an increase of 30% in deaths and heart attacks in older men has been reported.[88] Due to an increased incidence of adverse cardiovascular events compared to a placebo group, a Testosterone in Older Men with Mobility Limitations (TOM) trial (a National Institute of Aging randomized trial) was halted early by the Data Safety and Monitoring Committee.[89] On January 31, 2014, reports of strokes, heart attacks, and deaths in men taking FDA-approved testosterone-replacement led the FDA to announce that it would be investigating the issue.[90] Later, in September 2014, the FDA announced, as a result of the "potential for adverse cardiovascular outcomes", a review of the appropriateness and safety of Testosterone Replacement Therapy (TRT).[91][92][93] The FDA now requires warnings in the drug labeling of all approved testosterone products regarding deep vein thrombosis and pulmonary embolism.[94]
Up to the year 2010, studies had not shown any effect on the risk of death, prostate cancer or cardiovascular disease;[95][96] more recent[when?] studies, however, do raise concerns.[97] A 2013 study, published in the Journal of the American Medical Association, reported "the use of testosterone therapy was significantly associated with increased risk of adverse outcomes." The study began after a previous, randomized, clinical trial of testosterone therapy in men was stopped prematurely "due to adverse cardiovascular events raising concerns about testosterone therapy safety."[88]
However, when given to men with hypogonadism in the short- and medium-term, testosterone replacement therapy does not increase the risk of cardiovascular events (including strokes and heart attacks and other heart diseases). The long-term safety of the therapy is not known yet.[98][99]
Benign prostatic hyperplasia
Testosterone therapy for patients with late-onset hypogonadism, in addition to increasing risk of cardiovascular disease and prostate cancer, may exacerbate the risk factors associated with benign prostatic hyperplasia, a condition that involves the noncancerous enlargement of the prostate gland, which can lead to urinary symptoms.[100]
Prostate cancer
Testosterone in the presence of a slow-growing prostate cancer is assumed to increase its growth rate. However, the association between testosterone supplementation and the development of prostate cancer is unproven.[101] Nevertheless, physicians are cautioned about the cancer risk associated with testosterone supplementation.[102]
Testosterone may accelerate pre-existing prostate cancer growth in individuals who have undergone androgen deprivation.[82] It is recommended that physicians screen for prostate cancer with a digital rectal exam and prostate-specific antigen (PSA) level before starting therapy, and monitor PSA and hematocrit levels closely during therapy.[23]
Ethnic groups have different rates of prostate cancer.[103] Differences in sex hormones, including testosterone, have been suggested as an explanation for these differences.[103] This apparent paradox can be resolved by noting that prostate cancer is very common. In autopsies, 80% of 80-year-old men have prostate cancer.[104]
5α-Reductase inhibitors like finasteride and dutasteride can slightly increase circulating levels of testosterone by inhibiting its metabolism.[106] However, these drugs do this via prevention of the conversion of testosterone into its more potent metabolitedihydrotestosterone (DHT), and this results in dramatically reduced circulating levels of DHT (which circulates at much lower relative concentrations).[106][107] In addition, local levels of DHT in so-called androgenic (5α-reductase-expressing) tissues are also markedly reduced,[106][107] and this can have a strong impact on certain effects of testosterone.[51][108] For instance, growth of body and facial hair and penile growth induced by testosterone may be inhibited by 5α-reductase inhibitors, and this could be considered undesirable in the context of, for instance, puberty induction.[108][109] On the other hand, 5α-reductase inhibitors may prevent or reduce adverse androgenic side effects of testosterone like scalp hair loss, oily skin, acne, and seborrhea.[51] In addition to the prevention of testosterone conversion into DHT, 5α-reductase inhibitors also prevent the formation of neurosteroids like 3α-androstanediol from testosterone, and this may have neuropsychiatric consequences in some men.[110]
Aromatase inhibitors
Aromatase inhibitors like anastrozole prevent the conversion of testosterone into estradiol by aromatase.[51] As only a very small fraction of testosterone is converted into estradiol, this does not affect testosterone levels, but it can prevent estrogenic side effects like gynecomastia that can occur when testosterone is administered at relatively high dosages.[51] However, estradiol exerts negative feedback on the hypothalamic–pituitary–gonadal axis and, for this reason, prevention of its formation can reduce this feedback and disinhibit gonadal production of testosterone, which in turn can increase levels of endogenous testosterone.[111] Testosterone therapy is sometimes combined with an aromatase inhibitor for men with secondary hypogonadism who wish to conceive children with their partners.[112]
Notes: In rodents. Footnotes:a = Ratio of androgenic to anabolic activity. Sources: See template.
Testosterone is a high affinityligand for and agonist of the nuclearandrogen receptor (AR). In addition, testosterone binds to and activates membrane androgen receptors (mARs) such as GPRC6A and ZIP9. Testosterone is also potentiated via transformation by 5α-reductase into the more potent androgen DHT in so-called androgenic tissues such as the prostate gland, seminal vesicles, skin, and hair follicles. In contrast to the case of testosterone, such potentiation occurs to a reduced extent or not at all with most synthetic AAS (as well as with DHT), and this is primarily responsible for the dissociation of anabolic and androgenic effects with these agents.[115] In addition to DHT, testosterone is converted at a rate of approximately 0.3% into the estrogenestradiol via aromatase.[116] This occurs in many tissues, especially adipose tissue, the liver, and the brain, but primarily in adipose tissue.[116] Testosterone, after conversion into DHT, is also metabolized into 3α-androstanediol, a neurosteroid and potent positive allosteric modulator of the GABAA receptor, and 3β-androstanediol, a potent and preferential agonist of the ERβ.[117] These metabolites, along with estradiol, may be involved in a number of the effects of testosterone in the brain, including its antidepressant, anxiolytic, stress-relieving, rewarding, and pro-sexual effects.[117] Whereas testosterone produced both anabolic and androgenic effects, despite the lack of clear boundaries between these effects, as there is a great deal of mutual overlap between them,[118] the relative potency of these effects exerted by testosterone can depend on various factors and is a topic of ongoing research.[119][120]
All synthetic AAS are derivatives of testosterone.[127] Prominent examples include nandrolone (19-nortestosterone), metandienone (17α-methyl-δ1-testosterone), and stanozolol (a 17α-alkylated derivative of DHT). Unlike testosterone, AAS that are 17α-alkylated, like metandienone and stanozolol, are orally active. This is due to steric hindrance of C17β-position metabolism during the first-pass through the liver. In contrast, most AAS that are not 17α-alkylated, like nandrolone, are not active orally, and must instead be administered via intramuscular injection. This is almost always in ester form; for instance, in the case of nandrolone, as nandrolone decanoate or nandrolone phenylpropionate.
Testosterone was first isolated and synthesized in 1935.[128] Shortly thereafter, in 1937, testosterone first became commercially available as a pharmaceutical drug in the form of pellets and then in ester form for intramuscular injection as the relatively short-acting testosterone propionate.[51][49][129]Methyltestosterone, one of the first synthetic AAS and orally active androgens, was introduced in 1935, but was associated with hepatotoxicity and eventually became largely medically obsolete.[129] In the mid-1950s, the longer-acting testosterone esters testosterone enanthate and testosterone cypionate were introduced.[129] They largely superseded testosterone propionate and became the major testosterone esters used medically for over half a century.[129] In the 1970s, testosterone undecanoate was introduced for oral use in Europe,[129] although intramuscular testosterone undecanoate had already been in use in China for several years.[130] Intramuscular testosterone undecanoate was not introduced in Europe and the United States until much later (in the early to mid 2000s and 2014, respectively).[8][131]
The history of testosterone as a medication has been reviewed.[132][133][134][135]
In the US in the 2000s, companies and figures in the popular media have heavily marketed notions of "andropause" as something parallel to menopause; these notions have been rejected by the medical community.[136][137] Additionally, advertising from drug companies selling testosterone and human growth hormone, as well as dietary supplement companies selling all kinds of "boosters" for aging men, have emphasized the "need" of middle-aged or ageing men for testosterone.[138] There is a medical condition called late-onset hypogonadism; according to Thomas Perls and David J. Handelsman, writing in a 2015 editorial in the Journal of the American Geriatrics Society, it appears that this condition is overdiagnosed and overtreated.[138] Perls and Handelsman note that in the US, "sales of testosterone increased from $324 million in 2002 to $2 billion in 2012, and the number of testosterone doses prescribed climbed from 100 million in 2007 to half a billion in 2012, not including the additional contributions from compounding pharmacies, Internet, and direct-to-patient clinic sales."[138]
Generic names
Testosterone is the generic name of testosterone in English and Italian and the INNTooltip International Nonproprietary Name, USANTooltip United States Adopted Name, USPTooltip United States Pharmacopeia, BANTooltip BAN, and DCITTooltip Denominazione Comune Italiana of the drug, while testostérone is its French name and the DCFTooltip Dénomination Commune Française.[124][139][140] It is also referred to in Latin as testosteronum, in Spanish and Portuguese as testosterona, and in German, Dutch, and Russian and other Slavic languages as testosteron.[139][140] The Cyrillic script of testosterone is тестостерон.[141]
Brand names
Testosterone is marketed under a large number of brand names throughout the world.[139] Major brand names of testosterone and/or its esters include Andriol, Androderm, AndroGel, Axiron, Delatestryl, Depo-Testosterone, Intrinsa, Nebido, Omnadren, Primoteston, Sustanon, Testim, TestoGel, TestoPatch, Testoviron, and Tostran.[59][115][139]
Unmodified testosterone was also formerly available for intramuscular injection but was discontinued.[57]
Testosterone cypionate and testosterone enanthate were formerly available in combination with estradiol cypionate and estradiol valerate, respectively, under the brand names Depo-Testadiol and Ditate-DS, respectively, as oil solutions for intramuscular injection, but these formulations have been discontinued.[57]
Unlike in Europe, Canada, and much of the rest of the world, oral testosterone undecanoate is not available in the United States.[57]
As of November 2016[update], testosterone is available in Canada in the form of topical gels (AndroGel, Testim), topical solutions (Axiron), transdermal patches (Androderm), and intranasal gels (Natesto).[144] Testosterone cypionate (Depo-Testosterone, Testosterone Cypionate (generic)), testosterone enanthate (Delatestryl, PMS-Testosterone Enanthate), and testosterone propionate (Testosterone Propionate (generic)) are available as oil solutions for intramuscular injection and testosterone undecanoate (Andriol, PMS-Testosterone, Taro-Testosterone) is available in the form of oral capsules.[144] Testosterone buccal tablets and pellet implants do not appear to be available in Canada.[144]
Other countries
Testosterone and/or its esters are widely available in countries throughout the world in a variety of formulations.[139]
As of 2014[update], a number of lawsuits are underway against manufacturers of testosterone, alleging a significantly increased rate of stroke and heart attack in elderly men who use testosterone supplementation.[147][needs update]
Testosterone has been used to treat depression in men who are of middle age with low testosterone. However, a 2014 review showed no benefit on the mood of the men with normal levels of testosterone or on the mood of the older men with low testosterone.[148] Conversely, a 2009 review found that testosterone had an antidepressant effect in men with depression, especially those with hypogonadism, HIV/AIDS, and in the elderly.[149]
Heart failure
Testosterone replacement can significantly improve exercise capacity, muscle strength and reduce QT intervals in men with chronic heart failure (CHF). Over the 3 to 6-month course of the studies reviewed, testosterone therapy appeared safe and generally effective, and (ruling out prostate cancer) the authors found no justification to absolutely restrict its use in men with CHF.[150] A similar 2012 review also found increased exercise capacity and reasoned the benefits generlizable to women.[151] However, both reviews advocate larger, longer term, randomized controlled trials.[150][151]
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