pioglitazone and the role of thiazolidinediones in the case of non-hormone transitional care for male to female transsexuals
introduction
Gender-affirming hormone therapy for male-to-female (MTF) transgender individuals aims to induce feminization, including breast development, reduced muscle mass, and a shift in body fat distribution. A key goal is to move from a typically masculine, visceral (central) fat pattern to a more feminine, subcutaneous (peripheral) fat distribution (the “gynoid” pattern). Estrogen with anti-androgen therapy (e.g. spironolactone or GnRH analogs) usually produces some increase in total body fat and redistribution to hips, thighs, and buttocks over time. However, results vary: some transfeminine patients, especially those who begin HRT later in life or with genetic predispositions, may retain a stubbornly male fat pattern (e.g. visceral abdominal fat) despite optimal estrogen levels. This has prompted interest in adjunct therapies to further promote feminine fat redistribution.
Pioglitazone, a thiazolidinedione class drug used in type 2 diabetes, has emerged as a potential adjunct for this purpose. Its known metabolic effects include PPAR-γ (peroxisome proliferator-activated receptor gamma) activation, leading to increased subcutaneous adipogenesis and insulin sensitization. Clinicians and patients have speculated that pioglitazone could help “shift” body fat from the abdomen to subcutaneous stores, aiding the development of a more feminine body shape. This paper reviews the rationale, effects on fat redistribution, evidence of efficacy, and the risks of pioglitazone in the context of MTF hormone therapy, drawing on peer-reviewed literature and medical sources.
Sex Differences in Fat Distribution and HRT Effects
Cisgender men and women exhibit distinct patterns of adipose distribution. Men tend to accumulate fat viscerally (around abdominal organs and waist), whereas premenopausal women accumulate more fat subcutaneously in the gluteofemoral region (hips and thighs) – leading to “apple” vs. “pear” body shapes. This divergence is driven by hormonal milieu: androgens promote visceral fat accumulation, while estrogens favor subcutaneous deposition in peripheral areas. In transgender women (MTF), estrogen therapy and testosterone suppression recapitulate many of the cisfemale fat distribution traits. Studies show that within 1–2 years of gender-affirming hormone therapy (GAHT), trans women have significantly increased subcutaneous fat (particularly in the thighs and legs) and decreased visceral fat, yielding a shift from a masculine toward a feminine fat distribution. For example, a recent study in transwomen documented a \~37% reduction in visceral fat area after GAHT, accompanied by substantial gains in leg fat mass. In practical terms, transfeminine individuals on HRT often notice shrinking of waist circumference and increased fat around the hips and chest, contributing to a more feminine silhouette.
Despite these changes, not all individuals achieve the degree of fat redistribution they desire. Some may experience persistent central adiposity (“belly fat”) or less development of hip curvature than expected. This can be influenced by age, genetics, baseline body composition, and duration of HRT. Moreover, redistribution is a gradual process – typically occurring over months to years – and plateaus over time. These limitations have led to exploration of additional therapies that might accelerate or enhance the feminization of body fat. One such approach is targeting adipose tissue biology through insulin-sensitizing agents, like pioglitazone, to potentially “reprogram” fat distribution.
Pioglitazone: Mechanism of Action and Metabolic Effects
Pioglitazone is an oral antidiabetic medication in the thiazolidinedione (TZD) family. It is a potent agonist of PPAR-Îł, a nuclear receptor that regulates genes involved in adipocyte differentiation and lipid metabolism. Activation of PPAR-Îł by pioglitazone promotes the formation of new fat cells in subcutaneous adipose tissue and enhances the uptake and storage of free fatty acids into these cells. In essence, pioglitazone expands the capacity of subcutaneous fat depots, allowing fat to be redirected away from visceral and ectopic sites. This mechanism underlies its metabolic benefits in type 2 diabetes: by relocating lipids into safer subcutaneous stores, pioglitazone reduces liver and muscle fat infiltration, improves insulin sensitivity, and lowers blood glucose levels. It also increases adiponectin (an insulin-sensitizing adipokine) and has anti-inflammatory effects on adipose tissue.
A notable effect of pioglitazone and other TZDs is weight gain, which historically was seen as a side effect. However, research has shown that this weight gain is not purely deleterious – it is often due to an increase in subcutaneous fat with a concurrent decrease or no change in visceral fat. In other words, pioglitazone tends to shift fat from central (visceral) stores to peripheral (subcutaneous) depots. Clinical studies in diabetics demonstrate that pioglitazone treatment can increase subcutaneous fat area (particularly in the lower body) while either reducing visceral adipose volume or slowing its gain. This is essentially a transformation from an “apple-shaped” fat distribution to a “pear-shaped” one. Metabolism experts have described this as moving fat “from an apple to a pear”, which is metabolically favorable. Importantly, the drug’s action requires adequate caloric substrate – it redistributes existing or new fat rather than “creating” fat out of nothing. Thus, patients on pioglitazone may experience an increase in total fat mass unless caloric intake is tightly managed; but the location of that fat is shifted in a more benign (and in the case of transfeminine patients, more feminine) direction.
Given this profile, the theoretical rationale for using pioglitazone in MTF HRT is clear: by activating PPAR-γ, pioglitazone could preferentially enhance the subcutaneous fat gains driven by estrogen and help reduce residual visceral fat. Essentially, it might “supercharge” the body’s ability to develop a feminine fat distribution. Thiazolidinediones have already been noted to induce adipogenesis in subcutaneous fat by PPAR-γ activation, mimicking the gynoid fat distribution typically seen in females. The presence of estrogen in transfeminine individuals may further synergize with pioglitazone’s effects, since estrogen promotes gluteofemoral fat deposition. In contrast, in the absence of estrogen (e.g. cisgender men), pioglitazone still increases subcutaneous fat, but the pattern of where that fat goes may differ (more generalized peripheral gain). We hypothesize that in an estrogen-dominant system, pioglitazone’s new fat cells will preferentially fill in female-typical regions (hips, thighs, breasts) to a greater extent. This hypothesis is supported indirectly by observations that cisgender women tend to respond metabolically better to TZDs than men in some studies, and by at least one case report in a trans woman as discussed below. However, it must be noted that no controlled studies to date have specifically examined pioglitazone in transgender patients. The use of pioglitazone in this context is off-label and based on extrapolation from metabolic research and anecdotal evidence.
Evidence of Pioglitazone’s Effect on Feminization Outcomes
The only case report
The idea of using a TZD to enhance feminization first appeared in the medical literature in 2009. Malik et al. reported the first case of a male-to-female transsexual patient treated with a TZD for body shape purposes. This 45-year-old trans woman had been on estrogen therapy for 13 years but remained dissatisfied with her “male” fat distribution (notably central obesity with a 100 cm waist). Pioglitazone was not readily available in that setting, so she was initiated on rosiglitazone (another TZD, 2 mg/day). Over 14 months of therapy, dramatic changes were documented: her waist circumference decreased from 100 cm to 82.5 cm, and her hip circumference reduced modestly from 105 cm to 94.5 cm, while her thigh girth increased substantially (from 44 cm to 45 cm). After 20 months (with continued treatment), her waist stabilized around 82 cm, hips 93 cm, and each thigh grew to \~47–49 cm. These anthropometric changes significantly improved her waist-to-hip ratio and lower body contours, yielding a more traditionally feminine body shape. The patient’s self-image improved as a result of achieving a more “gynoid” fat distribution. Notably, her weight was not explicitly reported before and after; the changes could reflect a combination of weight loss and redistribution. The authors attributed the outcome to rosiglitazone’s known ability to shift adipose from central stores to subcutaneous depots. They concluded that TZD therapy “may have a place” in achieving body shape changes for trans patients who do not get optimal results from estrogen alone. This case provides a proof-of-concept that PPAR-γ agonism can enhance feminization of fat distribution in a transfeminine individual.
Metabolic and Endocrine Interactions
Beyond fat distribution, pioglitazone may exert subtle effects on the hormonal environment that could indirectly influence feminization. In polycystic ovary syndrome (PCOS) – a condition in cisgender women characterized by insulin resistance and elevated androgens – pioglitazone has been shown to increase sex-hormone-binding globulin (SHBG) levels. Higher SHBG can reduce free testosterone, which in PCOS helps restore normal ovulation and estrogen/progesterone production. By analogy, in a trans woman who still has some endogenous testosterone production (e.g. if not on a GnRH analog or post-gonadectomy), pioglitazone-induced increases in SHBG might further lower free testosterone levels. This could theoretically enhance the effectiveness of feminizing HRT by reducing any residual androgenic influence. However, in most MTF patients on adequate anti-androgen therapy, testosterone levels are already very low, and estrogen levels are high, so the clinical significance of SHBG changes is unclear. There is also complex interplay between insulin, IGF-1, and sex hormones; improvements in insulin sensitivity might improve overall endocrine balance, but these effects are secondary to the primary mechanism of fat redistribution.
Crucially, pioglitazone does not substitute for estrogen in feminization. It has no direct feminizing effect on secondary sex characteristics like breast tissue growth (aside from adding some fatty tissue to the breasts). True breast development (glandular component) requires estrogen (and likely is augmented by progestogens), not pioglitazone. Likewise, pioglitazone has no effect on reducing facial/body hair, altering voice, or other non-fat aspects of transition. Its role is purely as an adjunct to potentially improve body shape outcomes. Any feminization beyond what estrogen achieves would be limited to the realm of adipose distribution.
Risks and Safety Considerations
- Edema and Heart Failure: Pioglitazone’s activation of PPAR-γ in the kidney leads to increased sodium reabsorption, causing fluid retention. The resultant edema can be mild in many patients (peripheral ankle swelling) but can be significant in some – occurring in up to \~5% of users. In susceptible individuals (especially those with cardiac dysfunction), this fluid overload can precipitate or worsen congestive heart failure. Indeed, large trials have shown about a 40–50% increase in the risk of heart failure events in patients on pioglitazone. Pioglitazone is contraindicated in patients with NYHA Class III or IV heart failure for this reason. For a transgender patient, this means a thorough cardiac history is needed; those with any history of heart failure or significant heart disease should likely avoid pioglitazone. Even in healthy individuals, monitoring for edema, shortness of breath, or rapid weight gain is prudent during therapy. Notably, the edema-related weight gain is fluid, not fat, and does not contribute to feminization – in fact it can cause uncomfortable swelling and even mask true fat redistribution by bloating the body. If significant edema develops, the drug should be stopped.
- Weight Gain and Fat Gain: By design, pioglitazone tends to increase fat mass – which is the very effect we are seeking in terms of curves. However, total weight gain can be undesirable if excessive. In diabetes trials, patients often gain on the order of 2–4 kg or more over several months of therapy. In a transfeminine person already on estrogen, adding pioglitazone may further boost appetite and fat accrual. Care must be taken to encourage a balanced diet and monitor weight. If caloric intake is not controlled, pioglitazone could lead to generalized obesity (even if the fat is somewhat preferentially subcutaneous). There is also the possibility of fat accumulating in subcutaneous truncal areas (e.g. subcutaneous abdominal fat) rather than the hips/thighs, depending on genetics and lifestyle. Thus, the outcome might not always be a cosmetic positive. Anecdotally, some patients have reported that pioglitazone “made them fatter” without giving them the desired curves. Given that estrogen itself increases subcutaneous fat, adding pioglitazone is best suited for those who remain abnormally apple-shaped despite estrogen; if someone already has a decent hip/thigh fat development, pioglitazone could overshoot the effect and cause an unhealthy weight gain. Regular follow-up of body measurements and composition is advisable. Encouraging physical exercise (especially lower-body resistance training) might help ensure that additional weight goes to muscle and subcut fat in the thighs/buttocks rather than central areas.
- Bone Health (Fracture Risk): A less immediately obvious but serious side effect of pioglitazone is its impact on bone. PPAR-γ activation in mesenchymal stem cells can bias differentiation away from osteoblasts (bone-forming cells) and toward adipocytes. Consequently, long-term TZD use is associated with bone mineral density loss and increased fracture rates, particularly in women. A meta-analysis found that pioglitazone approximately doubled the risk of fractures in women (OR \~2.05) in the populations studied. The typical concern is for postmenopausal women with diabetes, who may already be osteopenic; adding pioglitazone raises fracture risk in that group. For transgender women, especially those who are older or have other osteoporosis risk factors, this is an important consideration. Estrogen has a bone-protective effect (indeed trans women on estrogen usually maintain or improve bone density), but whether estrogen fully counteracts pioglitazone’s pro-adipocyte/anti-osteoblast effect is not well studied. Caution dictates that if pioglitazone is used, one should ensure adequate calcium and vitamin D intake and consider periodic DEXA scans for bone density if therapy is prolonged. Any patient with a history of osteoporosis or fragility fractures should likely avoid pioglitazone.
- Hepatotoxicity: The first TZD (troglitazone) was withdrawn due to idiosyncratic severe liver toxicity. Pioglitazone and rosiglitazone have not shown the same degree of hepatic risk in large studies; however, rare cases of liver enzyme elevations and hepatitis have been reported. The FDA once recommended periodic liver enzyme monitoring during the first year of TZD therapy. In practice, clinically significant liver injury from pioglitazone is very uncommon (if it occurs, it is usually within the first months). Still, given the potentially severe consequence, a physician might check baseline liver function and avoid pioglitazone in those with active liver disease. Routine monitoring (e.g. liver panel every few months) can be done for peace of mind. Patients should be counseled to report dark urine, abdominal pain, or jaundice.
- Bladder Cancer: There has been longstanding controversy regarding pioglitazone and bladder cancer risk. Animal studies showed male rats developed bladder tumors on high-dose pioglitazone. Epidemiological studies in humans initially yielded mixed results, with some suggesting a small increase in bladder cancer incidence after prolonged pioglitazone use. A 2013 meta-analysis concluded that pioglitazone use was associated with a slight increase in bladder cancer risk, and advised caution in prescribing it to patients with risk factors for bladder cancer (such as smokers or those with prior bladder issues). However, more recent analyses, including a 2020 comprehensive meta-review, found no statistically significant increase in bladder cancer with pioglitazone. The current consensus is that if any risk exists, it is likely very small. Nonetheless, regulatory agencies in some countries (e.g. France and Germany) briefly suspended pioglitazone in the past over this concern. For a younger transgender population with presumably lower baseline cancer risk, bladder cancer is not a major contraindication, but it’s worth mentioning. If a patient has a history of heavy smoking or occupational exposures that predispose to bladder cancer, one might lean against using pioglitazone long-term. All patients on pioglitazone should be advised to report urinary symptoms like blood in urine. In summary, bladder cancer risk should be kept in mind but is not definitively proven to be elevated by pioglitazone in recent data.
- Other Side Effects: Pioglitazone can cause mild anemia (dilutional, from plasma volume expansion), which typically isn’t clinically significant but could slightly lower hemoglobin levels. It may cause mild reductions in white cell counts. Some patients report headaches or fatigue. Pioglitazone does not usually cause hypoglycemia when used alone (it doesn’t stimulate insulin secretion), so in a non-diabetic individual there’s minimal risk of blood sugar dropping too low. In diabetic patients, combination of pioglitazone with other meds can cause hypoglycemia, but that scenario is unlikely in the context of HRT unless the person also has diabetes. Pioglitazone is also known to cause macular edema in rare cases (swelling in the retina of the eye), especially in those with diabetes. Transgender patients with pre-existing diabetic retinopathy or macular edema would need ophthalmologic monitoring if on a TZD. Additionally, pioglitazone can interact with certain medications via liver enzyme metabolism (it’s primarily metabolized by CYP2C8). While it doesn’t strongly induce or inhibit other drugs, dose adjustments might be needed if combined with CYP2C8 inhibitors (like gemfibrozil) or inducers (like rifampin).
Discussion: Efficacy and Role in Feminization
- Fat Redistribution: Pioglitazone clearly has the pharmacologic capability to redistribute fat in a way that aligns with feminization goals. The documented case showed substantial improvements in waist/thigh proportions. Metabolic studies in other contexts consistently show decreased visceral fat with pioglitazone. For a transfeminine individual frustrated by a persistent “male belly,” pioglitazone could meaningfully reduce visceral fat stores and facilitate greater fat deposition under the skin of the limbs and hips. Over a course of several months to a year, this might translate to a noticeable change in body shape – a slimmer waist and fuller hips/thighs, as was seen in Malik et al.’s patient. It is reasonable to expect that pioglitazone’s feminizing effects (if any) will manifest gradually; one should not expect dramatic changes in just a few weeks. In the reported case, improvements accumulated over more than a year. This timeline is in line with the drug’s mode of action (slow remodeling of adipose tissue). Thus, any patient using pioglitazone for this purpose must have realistic expectations and patience. Regular measurements (waist, hip, thigh circumferences) and perhaps body composition scans could help track subtle changes over time.
- Magnitude of Effect: How big of a difference can pioglitazone make? It likely depends on the individual’s starting point. Someone with pronounced visceral fat (a high waist-to-hip ratio) might see a significant improvement in that ratio as visceral fat shrinks. On the other hand, a relatively lean person might only notice mild further contouring. It’s also probable that pioglitazone will have more noticeable effects if the person has underlying insulin resistance or metabolic syndrome, as those conditions correlate with excessive visceral fat that pioglitazone can target. In a healthy, insulin-sensitive person, pioglitazone’s impact on fat distribution might be less marked (though it would still promote some additional subQ fat). There is an interesting parallel in polycystic ovary syndrome: women with PCOS (who often have visceral fat excess despite being female) showed improved body composition and metabolic parameters on pioglitazone. By analogy, trans women with PCOS-like metabolic issues (for instance, those who are overweight/obese with central fat) could derive both feminizing and metabolic benefits from pioglitazone. Indeed, some experts suggest considering insulin-sensitizers in trans patients who develop weight gain or dyslipidemia on HRT. Pioglitazone might kill two birds with one stone in such cases: improve lipid/glucose profiles and enhance feminine fat distribution.
- Comparisons and Alternatives: Pioglitazone is not the only approach that has been considered for enhancing fat redistribution. Some clinicians have pondered other metabolic modulators. For example, GLP-1 receptor agonists (like semaglutide or liraglutide) are anti-diabetic/weight-loss drugs that, in PCOS patients, have shown lowered testosterone levels and increased SHBG. GLP-1 agonists primarily cause weight loss (including loss of visceral fat) and might indirectly improve body composition, but they are more likely to reduce overall fat (potentially helpful for health, but perhaps counterproductive if a patient is trying to gain fat in hips). In fact, a GLP-1 drug could be an option for a trans woman who is overweight with a lot of visceral fat – it would reduce visceral stores, though it might also reduce subQ fat, so feminization from an absolute fat standpoint might not improve curves (except via reducing waist). Another agent occasionally mentioned is telmisartan, an angiotensin receptor blocker with mild PPAR-γ activation properties (sometimes dubbed a “PPAR modulator”). Telmisartan can modestly improve insulin sensitivity and has been speculated as a weaker alternative to pioglitazone for fat redistribution without as much weight gain. However, like pioglitazone, there is no direct research on telmisartan for feminization, and any effect would likely be subtle. Diet and exercise remain fundamental: a diet rich in phytoestrogens or certain fats will not magically redistribute fat, but keeping overall calories in check prevents excessive visceral fat accumulation. Targeted exercise can build hip and thigh musculature to enhance shape. In summary, pioglitazone is one pharmacological tool among a spectrum of strategies to address body composition, but it should be considered only after optimizing the standard HRT regimen and lifestyle factors.
ISSUES WITH BREAST GROWTH
Breast tissue in adults is a mosaic of fibroglandular structures (ducts, lobules, connective stroma) embedded in a much larger volume of sub-cutaneous fat; imaging and cadaver studies estimate that 70-90 % of total breast volume is adipose, with the remainder being gland and stroma. Because pioglitazone (PIO) acts primarily by driving PPAR-γ–mediated adipogenesis, its most direct impact on breasts is to increase the fat compartment, potentially adding visible volume and softness. The question often raised is whether PIO’s molecular actions could impair the hormonally driven ductal-lobulo-alveolar growth that estradiol initiates during the first 1-2 years of feminizing HRT.
Molecular data: aromatase suppression vs. adipogenic support Early in-vitro work on human breast adipose explants demonstrated that thiazolidinediones (rosiglitazone, pioglitazone) down-regulate CYP19 (aromatase) transcription and activity by roughly 30–50 %8,9. Follow-up mechanistic studies showed that PPAR-γ agonists repress aromatase through dual pathways (lower PGE₂ signalling and increased BRCA1 expression)10. In cis women, local aromatase supplies a substantial fraction of intramammary estradiol, so such suppression is of interest to oncologists; however, in transfeminine patients already receiving systemic estradiol at physiologic–high female levels, the breast is “bathed” in circulating E₂. Thus, diminished local synthesis is unlikely to limit ductal growth in practice.
Conversely, several rodent and cell-culture studies report that PPAR-γ activation promotes differentiation of mammary pre-adipocytes and expansion of fat pads, mirroring its well-known effects in other sub-cutaneous depots. Clinically, this aligns with anecdotal accounts from gender specialists: breasts often feel fuller and fattier after a few months on PIO, even though nipple–areolar complex size (a proxy for glandular growth) appears unchanged.
Clinical and anecdotal observations No prospective studies have isolated PIO’s effect on breast volume in trans women, but one data streams are informative:
Community/clinician experience. Dr Will Powers, who has prescribed PIO to several hundred transgender patients, reports that starting PIO after the 6-12-month “budding” phase produces net gains in cup size (“90 % fat gains outweigh any theoretical aromatase hit”), whereas starting very early may slightly slow duct development in a minority of users11. Importantly, no patients required dose reduction of estradiol or experienced regression of existing breast tissue.
Breast-cancer and density considerations Large epidemiologic cohorts of diabetic cis women show no increase in breast-cancer incidence with long-term pioglitazone exposure12, and some data hint at a modest risk reduction. Mammographic density effects have not been systematically studied; suppression of aromatase might lower dense (fibroglandular) fraction slightly, but this remains speculative.
In sum, current evidence suggests that pioglitazone does not materially hinder breast development in transfeminine individuals and may even enhance perceived size through adipose expansion. Theoretical concerns about local aromatase suppression are outweighed by systemic estradiol exposure and the drug’s adipogenic effects, especially when PIO is started after the initial budding phase.
Conclusion
pioglitazone—and thiazolidinediones in general—offer a biologically plausible path toward enhancing gynoid fat redistribution for transsexual women. the drug’s ppar-γ–mediated shift of triglyceride storage from visceral to subcutaneous depots aligns mechanistically with the goals of gender-affirming body contouring, and limited clinical observations suggest meaningful waist-to-hip improvements over 6–18 months of use. still, evidence is anchored in one formal case report, scattered clinician experience, and extrapolation from diabetes trials; no randomized data yet quantify the magnitude, durability, or variability of feminizing effects.
for those considering pioglitazone as an adjunct, a cautious, data-driven approach is essential: start low (15 mg/day), titrate to 30 mg/day only if tolerated, and pair the medication with regular monitoring of weight trends, ankle or facial edema, cardiac status, bone density, liver enzymes, and urinary symptoms. community-centered education should emphasize that pioglitazone does not replace estrogen, does not directly drive breast gland growth, and can add overall fat mass—beneficial or not depending on diet, exercise, and individual goals. shared decision-making is critical: patients deserve clear discussions of benefits and uncertainties, especially around heart failure risk, fracture risk, and the still-inconclusive bladder-cancer signal.
a case study is being put forward by @endocrinemoder on twitter (me) attempting to study the use of pioglitazone and lobeglitazone in transsexuals across varying months on hrt, ages, and existing body measurements.
typical dosages (from diabetes usage):
- pioglitazone is usually prescribed in 15 mg, 30 mg, or 45 mg daily doses.
- 45 mg/day is the max approved dose for type 2 diabetes.
off-label use for fat redistribution in trans women (based on anecdotal and limited clinical notes):
- 15–30 mg/day is most common when used experimentally for feminization purposes.
- many start with 15 mg/day to assess tolerability (especially due to fluid retention and weight gain), then increase to 30 mg/day if no adverse effects.
- some people report noticeable effects on fat distribution at 30 mg/day, especially when combined with stable estrogen levels.
important caveats:
- you must monitor for side effects like:
- edema (fluid retention)
- weight gain (especially central vs subQ)
- possible effects on insulin sensitivity, liver enzymes, and bone density
- it’s also contraindicated in people with heart failure or osteoporosis risk, so bloodwork and medical supervision are highly recommended.
- regain phase (if cycling): some people time pioglitazone use specifically during regain periods after weight loss, when new adipocytes are being filled.
summary recommendation:
- start with 15 mg/day
- increase to 30 mg/day if well tolerated
- monitor weight, waist\:hip ratio, and any swelling or fatigue
- combine with stable estrogen therapy for best redistribution potential
References and Citations
1. Malik, I., Barrett, J., & Seal, L. (2009). Thiazolidinediones are useful in achieving female type fat distribution in male-to-female transsexuals. Endocrine Abstracts, 19, P74.
2. Alser, M. & Elrayess, M.A. (2022). From an Apple to a Pear: Moving Fat around for Reversing Insulin Resistance. Int J Environ Res Public Health, 19(21):14251.
3. Zhang, D. et al. (2024). Effects of gender-affirming hormone therapy on body fat: a retrospective case–control study in Chinese transwomen. Lipids in Health and Disease, 23:146.
4. Beal, C. (2023). Pioglitazone, Ozempic, and Weight Cycling. QueerDoc.com.
5. Majbauddin, A. et al. (2020). Assessing the need for pioglitazone in the treatment of type 2 diabetes: a meta-analysis of risks and benefits. Sci Rep, 10:15781.
6. Rubin GL et al. Peroxisome proliferator-activated receptor-Îł ligands inhibit estrogen biosynthesis in human breast adipose tissue. Cancer Res. 2000. PubMed Central
7. Zhao Y et al. Rosiglitazone and pioglitazone alter aromatase kinetic properties in human breast tissue. Endocrinology. 2011. PubMed Central
8. Su F et al. PPAR-Îł agonists target aromatase via PGEâ‚‚ and BRCA1 pathways in mammary cells. Cell Metab. 2013. PubMed Central
9. Powers W. Personal communication posted to /r/DrWillPowers (Dec 2024) describing clinical outcomes of pioglitazone in >100 trans patients. Reddit
10. Tseng C-H. Pioglitazone and breast-cancer risk in female type 2 diabetics: population-based cohort. BMC Cancer. 2022. bmccancer.biomedcentral.com