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            <strong>📄 Archived:</strong> 2025-08-31 14:35:09 UTC
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            <strong>🔗 Source:</strong> <a href="https://papers.lgbt/papers/igf">https://papers.lgbt/papers/igf</a>
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    <main class="paper-main flex-1 max-w-4xl mx-auto px-10 sm:px-12 md:px-16 lg:px-20 xl:px-28 2xl:px-36 py-8 lg:py-12" style="max-width: 76rem;"><div class="lg:hidden mb-8"><h3 class="text-xs font-medium uppercase tracking-wider text-muted-foreground mb-2">/igf</h3><h1 class="text-2xl font-medium text-foreground mb-2">igf-1 and the use of ghrh analogues in mtf breast development </h1><p class="text-sm text-muted-foreground">by emily/endocrinemoder/adenine</p></div><div class="bg-background p-6 mb-8 border"><h2 class="text-lg font-medium text-foreground mb-3">abstract</h2><p class="text-foreground leading-relaxed">exogenous insulin-like growth factor 1 (igf-1), a downstream mediator of growth hormone (gh), has gained attention as a potential adjunct to gender-affirming hormone therapy (gaht) in transsexual women seeking enhanced breast development. this review examines the biological rationale for igf-1 supplementation in the context of estrogen-driven breast growth, focusing on the synergistic roles of estradiol and gh/igf-1 during pubertal mammogenesis. while estradiol initiates ductal formation, igf-1 is required for terminal end bud expansion and epithelial proliferation—processes that may be blunted in adults initiating hrt later in life, when endogenous gh and igf-1 are diminished. the paper (i) outlines the physiologic role of igf-1 in breast development, (ii) reviews limited but suggestive data from ghd models, and community reports supporting its use in trans women, (iii) evaluates experimental strategies for raising igf-1 (including direct injections, gh analogs, and ghrh mimetics like mk-677 or igf lr3, and (iv) discusses risks including hypoglycemia, soft tissue overgrowth, cancer promotion, and unwanted masculinization via acromegaly-like effects. community physicians and anecdotal case reports point to a subset of older trans women with low baseline igf-1 who achieve renewed breast growth following targeted igf-1 elevation, especially after early budding has occurred. while promising, this approach remains off-label and requires cautious, time-limited use under medical supervision. early evidence suggests igf-1 does not impair estrogen-induced breast development and may modestly augment final volume when introduced during plateau phases. further research is needed to quantify outcomes and define safe protocols</p></div><div class="lg:hidden mb-8"><div class="flex flex-wrap gap-2"><span class="px-3 py-1 bg-secondary text-secondary-foreground text-sm">hrt</span><span class="px-3 py-1 bg-secondary text-secondary-foreground text-sm">igf</span><span class="px-3 py-1 bg-secondary text-secondary-foreground text-sm">hormones</span><span class="px-3 py-1 bg-secondary text-secondary-foreground text-sm">hopefuel</span></div></div><div class="paper-container bg-background border mx-auto max-w-3xl px-6 md:px-10 lg:px-14 py-10" style="max-width: 70rem;"><article class="prose prose-neutral prose-lg max-w-none [&amp;_*]:break-words [&amp;_table]:prose-table [&amp;_thead_th]:uppercase [&amp;_thead_th]:tracking-wide [&amp;_thead_th]:text-xs [&amp;_h1]:scroll-mt-24 [&amp;_h2]:scroll-mt-24 [&amp;_h3]:scroll-mt-24 [&amp;_h4]:scroll-mt-24 [&amp;_h5]:scroll-mt-24 [&amp;_h6]:scroll-mt-24 [&amp;_a]:text-blue-600 hover:[&amp;_a]:text-blue-700 dark:[&amp;_a]:text-blue-400 dark:hover:[&amp;_a]:text-blue-500 underline-offset-4" style="--para-space: 0.5em;"><h1>igf-1 and the use of ghrh analogues in mtf breast development</h1><p><strong>Introduction</strong> hrt for female transsexual individuals aims to induce feminization of the body, with breast development being one of the most desired changes. Typical regimens of high-dose estrogen (often with an anti-androgen or gonadotropin-releasing hormone analog) lead to some degree of breast growth in most transsexual female patients. However, the outcomes are highly variable. Research indicates that many trans women achieve only modest breast development – one study reported a median increase of \~19&nbsp;cm in chest circumference (similar to cisgender female averages), which on a broader male chest yields roughly an A-cup bra size. Consequently, a large proportion remain dissatisfied with their breast size; by two years into HRT, approximately 60% of trans women seek or plan breast augmentation surgery. Several factors contribute to suboptimal breast growth in this population. Age at start of HRT is critical: trans adolescents can develop breasts comparable to cisgender peers, whereas those initiating HRT in their 30s or later often see limited growth. Clinicians have long noted that <strong>younger trans women tend to have significantly better breast outcomes than older trans women, even on similar hormone regimens</strong>. This disparity suggests that something beyond just estrogen levels influences breast tissue responsiveness. Indeed, a likely factor is the <strong>hormonal growth milieu</strong> – specifically the levels of growth hormone and IGF-1, which peak in the late teens and decline with age. In natal female puberty, breast development is orchestrated not only by rising estrogen and progesterone, but also by a concurrent surge in GH and IGF-1; both estrogen and GH/IGF-1 are <strong>essential</strong> for normal mammary growth. If either is absent or deficient, breast development is markedly impaired.</p><p>In transgender women undergoing HRT later in life, exogenous estradiol can induce breast growth, but it does not recreate the pubertal GH/IGF-1 surge. Studies show that while estradiol therapy in adults may modestly raise IGF-1 levels in the first few months, it does not achieve the high IGF-1 concentrations typical of adolescence. Additionally, growth hormone secretion in adults is far lower than in teenagers. For example, a trans woman in her 50s will have baseline IGF-1 levels only a fraction of what a 15-year-old girl’s would be. This age-related GH/IGF deficit could help explain why even optimal estradiol therapy often yields smaller breast size in older transitioners. It follows that <strong>there is theoretical appeal in augmenting the growth factor environment</strong> to more closely mimic puberty. The idea has emerged that <strong>exogenous IGF-1 (or GH) administration might boost breast development</strong> in trans women whose own GH/IGF axis is past its peak. By increasing IGF-1 activity during the window of breast growth on HRT, one might prolong or amplify the tissue response to estrogen.</p><p><strong>Hormonal and Growth Factor Influences on Breast Development</strong> In cisgender females, breast development (thelarche) is a process beginning at puberty, driven by an interplay of hormones and local growth factors. Estradiol from the ovaries stimulates ductal growth and fat deposition in the breasts, while progesterone (produced after ovulation begins) promotes lobuloalveolar maturation. However, these sex steroids do not act alone. <strong>Growth hormone (GH) and its downstream effector IGF-1 are crucial permissive factors</strong> for pubertal breast development. GH, secreted in high amounts during the adolescent growth spurt, acts on the liver and also locally in breast tissue to induce IGF-1 production. IGF-1, in turn, directly stimulates the proliferation of mammary epithelial cells and the formation of terminal end buds – the structures from which new ducts sprout. In fact, experiments have shown that <strong>without IGF-1, estrogen cannot effectively form these ductal structures</strong>: mice lacking IGF-1 or its receptor have almost no mammary development even if given estrogen, whereas administering IGF-1 can rescue mammary growth in GH-deficient models. One seminal study found that IGF-1 is <em>indispensable</em> for ductal morphogenesis during puberty. Thus, estrogen and IGF-1 work in tandem – estrogen primes the breast tissue (for example, by upregulating estrogen and progesterone receptors and perhaps other growth factor receptors), and IGF-1 drives the expansion of the mammary gland architecture. They are <strong>synergistic</strong>, each amplifying the other’s effects on breast tissue development.</p><p>SECTION UNDER REWORK</p><p>Under hrt, the endocrine environment differs from puberty in several ways. Trans women typically receive steady doses of estradiol (often achieving mid-to-high female range levels) and often a progestogen after some months. These can increase IGF-1 modestly – for example, a study in the Netherlands noted about a <strong>16% rise in serum IGF-1 on average during the first 3 months of estrogen therapy in adult trans women</strong>. This is thought to result from estrogen’s effects on liver production of IGF-1 or changes in insulin sensitivity. However, after this initial bump, IGF-1 levels may plateau or even decline slightly over longer treatment, especially if weight gain or other metabolic changes occur. Moreover, the absolute IGF-1 levels in a 30- or 40-year-old trans woman on HRT are still far lower than those of a 15-year-old girl undergoing puberty – simply because the pituitary GH output cannot be fully “rejuvenated” by exogenous sex steroids in an older body. Additionally, adult GAHT protocols do not include the <strong>massive GH pulse amplitude</strong> that adolescents have. Some clinicians, such as Dr. Will Powers, have hypothesized that this GH/IGF gap is a key reason for the observed age differences in breast outcome. He notes that in his practice, <strong>no teenage MTF patients had subpar breast growth</strong>, whereas many of his older patients did, despite comparable estrogen regimens. The primary biochemical difference, in his view, is the <strong>“difference in growth hormone levels” between an actively growing teen and a mature adult.</strong> While younger bodies are essentially primed to grow (high IGF-1, high tissue responsiveness), older bodies prioritize maintenance and have fewer active growth signals.</p><p>This has led to what we might call the “second puberty” concept: deliberately introducing growth factors to mimic the pubertal hormonal synergy. IGF-1 is a prime candidate because it is the end-point mediator that directly stimulates mammary cell proliferation. Another approach could be using GH itself (to raise IGF-1 endogenously), but IGF-1 therapy (e.g., mecasermin injections) could bypass some complexities of GH and allow more controlled dosing. It is worth noting that <strong>some increase in IGF-1 likely already occurs with HRT</strong>, and further increments might have diminishing returns or unpredictable effects. Moreover, <strong>breast growth in adults is slower and tends to plateau</strong> within 2–3 years of HRT – possibly as the available mammary stem/progenitor cells are exhausted or as estrogen receptors downregulate. The hope with IGF-1 is to either <em>extend</em> this window of growth or <em>amplify</em> the growth before the plateau is reached.</p><p><strong>IGF-1 Mechanism of Action and Potential Impact on Breast Tissue</strong> IGF-1 is a peptide growth factor structurally similar to insulin. It circulates bound to IGF-binding proteins, with bioavailability regulated by these carriers. Most IGF-1 is produced by the liver in response to GH, but many tissues (including the breast) also produce IGF-1 locally. In the breast, IGF-1 acts primarily on the mammary epithelium and stroma via the IGF-1 receptor (a tyrosine kinase receptor), triggering intracellular pathways (MAPK, PI3K/AKT) that lead to <strong>cell proliferation, survival, and differentiation</strong>. During puberty, IGF-1 stimulates the formation and elongation of ducts and the creation of terminal end buds – the bulbous growing tips of ducts that drive expansion into the fatty tissue. It also likely promotes the development of lobules (milk-producing glands) in synergy with prolactin and progesterone in later stages. Essentially, <strong>IGF-1 provides the mammary gland with a strong “grow” signal</strong>, telling cells to divide and structures to enlarge.</p><p>When exogenous IGF-1 is introduced (such as via injection), it can have both local and systemic effects. Systemically, IGF-1 will engage receptors in many organs. In the context of breast development, the concern and opportunity are two sides of the same coin: IGF-1 can <em>nonspecifically</em> stimulate growth in various tissues, but if breast tissue is one of those tissues (and is concurrently exposed to estrogen), it stands to reason that the breast could grow more. Empirical evidence from animal studies and clinical observations supports this: <strong>administration of GH or IGF-1 causes diffuse mammary gland enlargement</strong> (hyperplasia) in rodents, and in humans, high IGF-1 states correlate with increased breast tissue mass and density. Notably, GH/IGF-1 also increases fat accretion in subcutaneous tissue to some extent, so some of the breast size effect could be through adding fat as well (GH tends to reduce visceral fat but can increase peripheral fat in the presence of estrogen). However, the primary sought effect is on glandular tissue.</p><p>Mechanistically, IGF-1 in the breast works in concert with estrogen: estrogen receptor activation in stromal cells induces the expression of growth factors (including IGF-1 itself and epidermal growth factor), and IGF-1 from stromal cells acts on epithelial cells to cause them to proliferate and form ducts. Estrogen also upregulates IGF-1 receptors and downstream signaling components in breast tissue, <strong>enhancing the tissue’s sensitivity to IGF-1</strong>. Thus, when both estrogen and IGF-1 are abundant, the growth signaling in the breast is maximized. Progesterone further contributes by branching the ducts and forming lobules, a process also aided by growth factors (and likely requiring IGF-1 as well). In summary, <strong>IGF-1 can be thought of as the “fertilizer” that allows estrogen (the “seed”) to fully bloom into breast tissue</strong> – without enough IGF-1, estrogen’s effect is blunted; with plenty of IGF-1, estrogen’s effect is amplified.</p><p>If one administers IGF-1 exogenously to a trans woman on estrogen therapy, the expectation is that it would <strong>increase the rate or extent of breast cell proliferation</strong>. This might translate to faster growth (e.g. achieving in 6 months what might otherwise take 12) and/or greater final size. Importantly, IGF-1 would not initiate breast development on its own – if a trans woman had no estrogen, giving IGF-1 would not cause meaningful breast growth (there would be no ductal structures to expand, as estrogen is needed to form the framework). IGF-1 is an adjunct, not a primary driver of feminization.</p><p>One theoretical concern is whether introducing IGF-1 at the wrong time could cause <strong>premature differentiation or closure of growth potential</strong>. In skeletal growth plates, for example, excess IGF-1 can accelerate maturation and lead to early epiphyseal fusion. In the breast, there isn’t an “epiphyseal plate” per se, but there might be parallel concerns: if high IGF-1 causes rapid differentiation of terminal end buds into mature ducts too quickly, it might curtail the overall growth period. This is speculative, but some experts argue that a slower, prolonged breast development (mimicking normal puberty) may yield better results than an intense burst. This underpins protocols like “The Beal Method,” which advocate <strong>initial low-dose estrogen to elongate the development phase</strong>. Adding IGF-1 early, when estrogen levels are low, might be counterproductive or unnecessary. Therefore, timing is a consideration: one might choose to introduce an IGF-1 adjunct <em>after</em> initial breast budding has occurred (i.e., Tanner stage 2 or 3), to then amplify further growth, rather than at the very start of HRT. This approach mirrors the recommendation for other adjuncts (e.g., Dr. Powers has suggested not introducing certain metabolic agents until after the budding phase, to avoid interfering with initial glandular organization).</p><p>Another mechanistic point: <strong>IGF-1 has metabolic and endocrine effects</strong> beyond the breast. It can influence insulin sensitivity, androgen levels, and other hormones indirectly. For instance, IGF-1 feeds back on the pituitary to reduce GH secretion (a negative feedback loop), though in an adult on exogenous IGF-1, lowering their own GH might not matter much. IGF-1 also can increase sex-hormone binding globulin (SHBG) levels slightly, due to its insulin-like actions that reduce insulin (and high insulin tends to suppress SHBG). A higher SHBG could actually reduce free estradiol a bit, potentially a minor counter-effect (though trans women often have plenty of estradiol, and a small SHBG rise might not be significant). There’s also interplay with prolactin: GH and IGF-1 can raise prolactin levels or sensitivity (GH is actually a lactogen in some species). Elevated prolactin can contribute to breast growth too, though in adults it more often causes galactorrhea rather than true growth unless combined with estrogen. So IGF-1 might indirectly increase prolactin or its effect, which could be a bonus or a side effect. Overall, the endocrine interactions are complex, but the net effect intended is an anabolic one in the breast.</p><p><strong>Evidence and Anecdotes of IGF-1’s Effect on Breast Growth</strong> <em>Formal clinical studies.</em> To date, <strong>no randomized trials or published clinical studies</strong> have evaluated IGF-1 or GH supplementation specifically to enhance breast development in transgender women. The use of IGF-1 in this context is entirely off-label and experimental. We must therefore rely on indirect evidence and analogies:</p><ul class="list-disc pl-6"><li><strong>Community anecdotes:</strong> Within transgender health forums and clinics, there are scattered reports of attempting to boost GH/IGF-1 to enhance breast growth. One prominent voice, Dr. Will Powers, shared an informal experiment from his practice: He identified patients with poor breast development after years on HRT and found many had low IGF-1 levels (1–3 standard deviations below the mean for age). In an attempt to “naturally” raise their IGF-1, he advised a group of these patients to significantly increase their protein intake and engage in high-intensity interval and resistance training – both known stimuli for GH secretion. The outcome was intriguing: several of these individuals reported that a day or two after intense workouts, they experienced breast tenderness or swelling, something they had not felt in a long time. In some cases, <strong>after months of stagnation, they noticed renewed modest breast growth coincident with periods of rigorous exercise</strong>. While subjective and uncontrolled, this pattern is consistent with the hypothesis that <em>short-term spikes in GH/IGF-1 (from exercise) re-triggered breast tissue activity</em>. One patient in her 50s even credited a regimen of slight weight gain and heavy compound weightlifting with achieving “surprisingly good” breast enlargement for her age. These reports bolster the idea that the IGF-1 axis is involved in ongoing breast responsiveness, even later in transition.</li></ul><ul class="list-disc pl-6"><li><strong>Indirect metabolic clues:</strong> Transsexual hormone therapy itself interacts with the GH/IGF axis. A study of transgender adolescents found that during GnRH agonist puberty blockade, IGF-1 levels rose slightly (perhaps due to unopposed GH), and upon introducing estradiol, IGF-1 levels tended to decrease a bit over time. In adult trans women, one study noted a moderate increase in IGF-1 in the first 3–6 months of HRT, as mentioned. Interestingly, high estrogen levels can sometimes suppress IGF-1 if liver production is affected (in acromegaly treatment, estrogen is used to lower IGF-1). So it’s possible that extremely high estradiol doses (sometimes used historically) might actually lower IGF-1 and paradoxically impede breast growth. This could be one reason <strong>recent protocols favor moderate estrogen dosing</strong>; excessively high estradiol might saturate estrogen receptors but also cause counterproductive metabolic changes. There is speculation that <strong>steady lower estrogen (mimicking puberty) might keep IGF-1 more optimized for growth</strong>, whereas a blast of high estrogen could shut down some GH output or increase IGF-binding proteins that reduce free IGF-1. These nuances are areas for future research. What they mean for exogenous IGF-1 use is: one would want to maintain estrogen in a physiologic range alongside IGF-1, rather than pushing estrogen to extreme levels. The synergy seems best in a balanced physiologic window, not with either hormone in excess.</li></ul><p><strong>Potential Endocrine Interactions and Considerations</strong> If IGF-1 is added to a trans woman’s regimen, how might it interact with other aspects of her hormone therapy? First, IGF-1 is not expected to alter estradiol or testosterone levels directly. A trans woman on estradiol and an androgen blocker (or post-gonadectomy) will remain in the same hormonal milieu; IGF-1 isn’t a sex hormone and does not feed back on gonadotropins in a meaningful way. Some nuances:</p><ul class="list-disc pl-6"><li><strong>Prolactin:</strong> Both estrogen and increased IGF-1/GH can elevate prolactin levels. IGF-1 itself doesn’t directly stimulate prolactin, but GH has lactogenic properties, and IGF-1 can indirectly signal the pituitary. There have been cases where adding GH therapy in adults led to slight prolactin rises. An elevated prolactin in a trans woman could cause breast symptoms (tenderness, possibly a bit of lobule growth, or rarely galactorrhea). This is not necessarily harmful unless prolactin goes very high (risking prolactinoma). Monitoring prolactin could be wise, though significant issues are unlikely unless massive doses are used. Some theorize that a moderate prolactin elevation might even aid breast development (since prolactin in pregnancy causes gland maturation), but this is speculative and high prolactin can carry its own risks (e.g. mood effects, sexual side effects, tumor stimulation).</li></ul><ul class="list-disc pl-6"><li><strong>Timing with Progesterone:</strong> Many trans women start progesterone after \~1–2 years of estrogen, aiming to improve breast maturity. Progesterone could synergize with IGF-1 in developing lobules. Notably, progesterone itself might increase IGF-1 locally in breast tissue – pregnancy hormones like human placental lactogen and IGF-1 spike together, and progesterone levels correlate with mammary IGF-1 expression. If a patient is on progesterone, adding IGF-1 might particularly enhance the lobuloalveolar (i was rereading this and thought it said labubualveolar for a second) component of breast growth (the glandular tissue that progesterone helps form). No data exists on this combination, but it’s worth considering that a “triad” of estrogen + progesterone + IGF-1 mimics a pregnancy-like state in some ways. Could that yield more breast tissue? Possibly, though pregnancy-level changes are also transient and often regress postpartum. We must be careful not to assume permanent gains from a short-term pregnancy simulation.</li></ul><ul class="list-disc pl-6"><li><strong>Insulin and Metabolism:</strong> IGF-1 can lower blood glucose (discussed below under risks). This insulin-like action could in turn affect appetite, weight, and energy. If a patient experiences hypoglycemia, they may eat more to compensate, potentially gaining weight. Weight gain might increase breast fat, confounding assessment of glandular growth. On the flip side, improved insulin sensitivity from IGF-1 could help overall metabolic health if not causing frank hypoglycemia. A balanced diet and consistent meal schedule are important if on IGF-1 to avoid sugar crashes.</li></ul><ul class="list-disc pl-6"><li><strong>Feedback on GH:</strong> Exogenous IGF-1 will likely suppress the patient’s own GH secretion via negative feedback on the hypothalamus and pituitary. In an adult, baseline GH is already low, and many trans women on estrogen have slightly lower GH output than men of similar age (estrogen route can modulate GH axis). By giving IGF-1, you might reduce nocturnal GH pulses further. This isn’t clinically significant as long as IGF-1 levels are maintained by the therapy. But one should be aware that after stopping IGF-1, the body’s GH might be a bit slow to ramp back up, potentially leading to a temporary dip in IGF-1 levels below baseline. Tapering off might be prudent rather than abrupt cessation, to let the endogenous GH axis recover.</li></ul><p>In essence, adding IGF-1 is not like adding a new sex hormone; its interactions are mostly metabolic. It “plugs into” the existing HRT by amplifying tissue responses rather than changing hormone concentrations. The key is to <strong>use IGF-1 as a short-to-medium-term adjunct, not as a standalone or indefinite therapy</strong>, thereby minimizing systemic disruptions.</p><ul class="list-disc pl-6"><li><strong>Acromegaly-like effects:</strong> Perhaps the most concerning risk is inducing features of acromegaly. Acromegaly results from chronic excess GH/IGF-1 exposure (e.g., from a pituitary tumor) and leads to <strong>enlargement of many tissues</strong> – not just the intended ones. This includes bones of the face and jaw (causing prognathism and brow prominence), hands and feet (ring and shoe size increase), and soft tissues like the nose, tongue, and heart (leading to cardiomyopathy). The irony is that these changes are masculinizing in appearance – <em>the opposite</em> of what a trans woman wants. Enlarged jaw and brow ridges, big hands, etc., would be distressing and could worsen gender dysphoria. <strong>It is crucial to emphasize that using high doses of GH or IGF-1 without medical guidance is extremely dangerous in this regard.</strong> Dr. Powers explicitly cautions patients against “go buy some HGH and start shooting it up,” noting that <strong>excess growth hormone will cause acromegalic changes and a “hyper-masculine” appearance</strong>. The goal, if IGF-1 were to be used, would be to <em>carefully titrate to a modest increase</em> – likely aiming for high-normal IGF-1 levels for age, not supraphysiological levels. Even then, individuals may vary in sensitivity. Monitoring for early signs of acromegaly would be necessary: e.g., periodic measurements of ring size or shoe size, facial feature changes in photographs, and symptom review (joint pain, jaw soreness, carpal tunnel symptoms). If any hint of unwanted tissue growth appears, therapy should be halted immediately. Generally, short-term, mild elevation of IGF-1 (on the order of months) is less likely to cause irreversible bone changes; acromegaly in patients usually develops over years of hormone excess. Nonetheless, this is a <strong>major risk that cannot be overstated</strong> – the specter of giving a trans woman a masculinizing complication while trying to feminize her is frightening. For this reason alone, many clinicians refrain from any GH/IGF use in this population, unless it’s part of a controlled study.</li></ul><ul class="list-disc pl-6"><li><strong>Cancer risk:</strong> IGF-1 is a potent mitogen and anti-apoptotic agent for many cell types, and has been implicated in cancer development. <strong>Epidemiological studies have linked higher IGF-1 levels to increased risks of breast, colorectal, and prostate cancers</strong>. In the context of breast tissue, IGF-1 can not only promote normal growth but also potentially the growth of abnormal cells. Women with acromegaly have about a 2-3 fold higher incidence of breast cancer compared to the general population. The combination of estrogen and high IGF-1 is considered especially mitogenic – indeed, models of breast cancer prevention are exploring blocking IGF-1 to reduce estrogen-driven tumor formation. For an older trans woman (who might already be in an age range where breast cancer becomes a concern), intentionally elevating IGF-1 raises theoretical risk. While trans women have, so far, shown breast cancer rates more similar to cis men than cis women (i.e., relatively low, likely due to shorter lifetime estrogen exposure), as they age and if on decades of HRT, their risk approaches that of cis women. Adding IGF-1 could conceivably accelerate any early malignant changes. There is no direct evidence on this yet, but it must be considered. A patient with a strong family history of cancer or known mutations (e.g., BRCA) should almost certainly avoid IGF-1 therapy. If IGF-1 were used, <strong>strict screening and short duration</strong> would be prudent – perhaps limiting use to 6-12 months to achieve some growth and then stopping, rather than maintaining high IGF-1 chronically. It’s worth noting that in children treated with IGF-1 for growth failure, no significant increase in malignancies has been reported in the short term; however, children generally have “room to grow” and are not at immediate cancer-prone ages. In an adult, any latent precancerous lesions could, in theory, be stimulated by IGF-1. Regular breast exams and imaging (MRI or mammogram, though mammography is less sensitive in very small breasts or when glandular tissue is still developing) should accompany any IGF-1 use. If a patient has had any cancer in the past (even say, a resolved testicular cancer or other), IGF-1 would be contraindicated due to fear of reactivating tumor growth.</li></ul><ul class="list-disc pl-6"><li><strong>Metabolic effects – hypoglycemia:</strong> IGF-1 can bind insulin receptors (albeit with lower affinity than insulin) and promote glucose uptake by cells. Especially when given in pharmacological doses, IGF-1 often causes <strong>low blood sugar</strong>. In clinical trials of mecasermin (rhIGF-1) in children, up to half of the patients experienced at least one episode of hypoglycemia. Typically, this is managed by always administering IGF-1 shots with a meal or snack. For an adult, hypoglycemia can manifest as dizziness, sweating, heart palpitations, confusion, or even loss of consciousness and seizures in severe cases. A transgender woman using IGF-1 would need to monitor her blood glucose, or at least be very attuned to symptoms. If she’s also on any diabetes medications (some trans women have type 2 diabetes, for example), those might need adjusting. It would be wise to keep a fast-acting sugar source (like glucose tablets or juice) on hand. Over time, the body partially adapts (muscles may increase uptake but liver gluconeogenesis might adjust), and fractionating the dose can help (e.g., smaller twice daily doses rather than one big dose). Nonetheless, hypoglycemia is a <strong>common acute side effect</strong> that can be dangerous – imagine a patient driving or operating machinery and suddenly getting a hypoglycemic blackout. This is another reason any IGF-1 therapy should be done with medical supervision, at least initially, to determine safe dosing. Starting low and slowly increasing while checking glucose can mitigate risk. The goal would be to find a dose that raises IGF-1 but doesn’t cause significant drops in blood sugar (often the maximal IGF-1 stimulation dose is higher than needed for just a moderate increase). Using bedtime dosing can also be a strategy (to sleep through any mild hypoglycemia, though one risks nocturnal low sugar if too high a dose is given).</li></ul><ul class="list-disc pl-6"><li><strong>Fluid retention and edema:</strong> Both GH and IGF-1 cause the body to retain sodium and water. IGF-1 can lead to <strong>edema</strong> in extremities or the face. In children on high-dose IGF-1, facial coarsening and puffiness is seen (part of why they may resemble acromegalic features). In adults, edema can put strain on the heart and kidneys if severe. One might expect a few pounds of water weight gain and perhaps some ankle swelling on IGF-1 therapy. This side effect is usually dose-dependent and reversible upon stopping. However, if a trans woman has any underlying heart issue (like borderline heart failure or uncontrolled hypertension), fluid retention could exacerbate it. Careful monitoring of blood pressure and any signs of shortness of breath or swelling is needed. Diuretics are not a great solution because they can worsen hypoglycemia (volume depletion reduces glucose delivery and can trigger stress hormones). Usually, the approach is to reduce the IGF-1 dose if edema is problematic.</li></ul><ul class="list-disc pl-6"><li><strong>Local reactions and practicality:</strong> Mecasermin (rhIGF-1) is given by subcutaneous injection, often twice daily. <strong>Injection site reactions</strong> (redness, lumps) are common. For someone already possibly injecting estradiol weekly or biweekly (if on injectables), adding a twice-daily shot is a significant inconvenience. Some might attempt using IGF-1 analogs like IGF-1 LR3 which are long-acting and could be once daily or every other day; however, those are not pharmaceutically approved and carry uncertainties of dose consistency. There’s also the cost – IGF-1 is extremely expensive (mecasermin can cost thousands of dollars a month out-of-pocket). Insurance is very unlikely to cover it for this off-label use. GH is similarly pricey. Due to cost, some might turn to grey-market sources, which introduces purity and dosing risks (and legal risks). Any sign of injection site infection or allergic reaction (which can happen, as IGF-1 is a recombinant protein) would need prompt attention. Signs of allergy might include rash, itching, or more severe anaphylaxis symptoms – though true allergy to IGF-1 is rare, since it’s nearly identical to human protein, the preservatives or delivery compounds could cause issues.</li></ul><p><strong>Impact on Breast Tissue Quality and Developmental Course</strong> One specific question is whether introducing IGF-1 could alter the <em>type</em> of breast tissue that develops. Normally, breasts that develop on HRT in trans women consist of both glandular components (ducts, lobules) and fat, much like cisgender breasts. The proportion can vary; many trans women end up with a higher fat-to-gland ratio than cis women who went through puberty, partly because initial development is less robust and subsequent size increase is often through fat. If IGF-1 successfully stimulates growth, we would hope it mainly increases the glandular component (since that’s what IGF-1 primarily targets). This could lead to a more “dense” breast (higher fibroglandular tissue content). On a mammogram, high density is actually a risk factor for breast cancer and can make detection harder. That’s another trade-off: more gland tissue might mean a slightly higher long-term cancer risk than just fatty tissue, but that’s inherent to having larger breasts in general. Some trans women might welcome a denser, fuller breast (as it could feel more substantial). There’s anecdotal suggestion that trans women who had minimal growth then got implants often had mostly just an empty skin envelope; if IGF-1 could instead have led them to grow more gland tissue, perhaps they could avoid implants or get by with smaller implants. The <strong>timing</strong> of IGF-1 introduction could be critical for quality: If done while breasts are still in early development (Tanner stage 2-3), it might promote more ductal branching (good for shape and fullness). If done late (after 3-4 years on HRT, when breasts may have essentially finished growing), it might mostly expand fat and any residual tissue, possibly causing more of a generalized swelling rather than structured growth.</p><p>Dr. Powers has speculated about <em>when not to use</em> growth factors: he implies that doing anything to alter local estrogen conversion (like high dose PPARγ drugs) in the <strong>first year (budding stage) might slow duct formation</strong>. By analogy, blasting IGF-1 from day one could cause some inefficient growth – perhaps more fibro-fatty tissue without proper ductal organization. Therefore, a reasonable approach might be: allow 6–12 months of estrogen-driven breast budding (Tanner I → II → III progression) without interference. After that point, if the patient is dissatisfied with the pace, consider adding IGF-1 for a defined period (e.g., 6 months) to spur additional growth, then cease and let the tissue mature. This also aligns with Dr. Beal’s method of low-and-slow estrogen then gradually up, which hints that the <strong>patience of a multi-year process</strong> yields the best final results.</p><p>Another aspect is <strong>regression after stopping</strong>. If IGF-1 is given and then withdrawn, will the gained breast tissue remain? In theory, new ducts and lobules formed should stay (though they might atrophy slightly if not sustained by high estrogen – but the patient would still be on normal HRT, so that should maintain structures). Breast adipose gained might reduce if the IGF-1 had caused weight gain and then that weight is lost. But it’s not like muscle where stopping lifting makes muscles shrink quickly; breast changes tend to be more lasting unless there’s a major hormonal shift (like stopping estrogen entirely). So one hopes any achieved development would be permanent as long as baseline HRT is continued. Indeed, one reason to <em>not</em> continuously administer IGF-1 is that you probably don’t need it forever – once the breast has grown to a new level, maintaining it just requires normal hormone levels. <strong>Using IGF-1 as a short-term accelerator</strong> might achieve the goal without continuous exposure to risk.</p><p><strong>Practical Approach and Monitoring</strong> If despite the cautions, an individualized decision is made to trial IGF-1 augmentation in a trans woman for breast development, the following practical plan could be considered (drawing from pediatric IGF-1 therapy guidelines and expert opinion):</p><ul class="list-disc pl-6"><li><strong>Baseline evaluation:</strong> Check IGF-1 levels, IGF binding protein-3 (to ensure the IGF system is intact), and screen for any contraindications. Baseline cancer screening as appropriate for age (e.g., breast exam, mammogram if age &gt;50 or strong risk factors, colonoscopy if over 50, etc.), liver function tests, fasting glucose/HbA1c (to see if hypoglycemia risk is higher or if undiagnosed diabetes is present, since IGF-1 could mask diabetes by lowering glucose). Possibly an echocardiogram if there’s any history of heart issues, because GH/IGF can affect heart muscle. Document baseline breast size (measurements, photos with consent perhaps, or at least patient’s subjective rating).</li></ul><ul class="list-disc pl-6"><li><strong>Starting dosage:</strong> For <strong>mecasermin (Increlex)</strong>, the pediatric starting dose is 0.04 mg/kg twice daily. In an adult, a weight-based dose might overshoot since adults may be more sensitive to side effects. Some clinicians might start at a flat low dose like 20&nbsp;μg/kg once daily (rather than twice) – for a 70&nbsp;kg person, that’s \~1.4&nbsp;mg per dose. To put in context, children often escalate to \~0.12&nbsp;mg/kg BID (\~8.4&nbsp;mg BID in a 70&nbsp;kg person, which is \~17&nbsp;mg/day total) – that’s a full replacement for a child with no IGF. An adult likely doesn’t need that much to go from a mid-range IGF-1 to high-normal. So one strategy: <strong>start at \~1&nbsp;mg subcutaneously once daily with a meal</strong>. Measure blood glucose at 1 and 2 hours post-injection initially (or at least ensure no symptoms). If tolerated, after a week, consider increasing to twice daily 1&nbsp;mg (morning and evening with meals). Titrate in 1&nbsp;mg increments per dose weekly as tolerated, with target perhaps to double the IGF-1 level or reach high-normal range. Suppose baseline IGF-1 was 150&nbsp;ng/mL (normal \~100-250 for age); one might target \~250-300&nbsp;ng/mL. It would be wise not to exceed the upper limit of normal by more than, say, 20%.</li></ul><ul class="list-disc pl-6"><li><strong>Monitoring during treatment:</strong> Very frequent check-ins at first (weekly calls or messages to assess symptoms, especially hypoglycemia signs, edema, joint pain). Come for clinic visit monthly. Check IGF-1 level after \~1 month at a stable dose to see where it stands – adjust dose to aim for a particular IGF-1 range (e.g., 250-300&nbsp;ng/mL). Monitor fasting glucose or A1c after a couple months to ensure not inducing a pre-diabetic state (GH can in the long run cause insulin resistance; IGF-1 can mask high sugar by lowering it, but net effect in acromegaly is often diabetes from GH’s counteraction; the interplay is complex). Do a breast exam at each visit to feel for any unusual masses (since rapid growth could sometimes create benign fibroadenomas or cysts, but also we want to ensure no suspicious lumps). Every 3–6 months, one might consider imaging (ultrasound) to measure any change in glandular tissue or detect any focal lesions early.</li></ul><ul class="list-disc pl-6"><li><strong>Patient diary:</strong> The patient should be encouraged to keep a diary of breast symptoms (tenderness, swelling episodes), as well as systemic symptoms (headaches, how often they feel shaky from low sugar, any musculoskeletal pains). They should also track their bust circumference or bra fit changes monthly – objective data to correlate with the intervention.</li></ul><ul class="list-disc pl-6"><li><strong>Duration of therapy:</strong> Predefine this. For example, plan for a 6-month trial. The expectation is not that breasts will grow overnight – but if IGF-1 is working, one might see a noticeable change in 3–6 months (maybe an increase of a half cup or more, or a qualitatively fuller shape). If nothing has changed by 6 months, further IGF-1 is likely futile (or the dose was not sufficient, but raising dose would raise risk). If there is improvement, one could stop at 6 months and see if gains hold. Or continue a bit longer (maybe up to 12 months total). But <strong>longer exposures increase risk of insidious side effects</strong> (like insidious facial changes or cancer risk), so it is not advisable to stay on high IGF-1 for years on end just for marginal gains. Most breast growth in any scenario occurs in spurts, not continuously forever. The idea would be to spur a spurt, then back off.</li></ul><ul class="list-disc pl-6"><li><strong>Stopping criteria:</strong> Establish clear criteria to discontinue early: e.g., if patient experiences severe hypoglycemia that is hard to manage, persistent significant edema or blood pressure rise, any signs of acromegaly (e.g., sudden shoe size increase, or jaw feeling different, etc.), severe headaches suggesting intracranial hypertension, or discovery of any breast lump or other tumor. If any blood tests go awry (e.g. unexplained rise in liver enzymes – IGF-1 can rarely cause liver strain, though that’s more GH in high doses; or severe hyperglycemia from GH’s insulin resistance effect), those would also prompt discontinuation.</li></ul><p>It should be noted that in many jurisdictions, obtaining IGF-1 or GH for an off-label use will be challenging outside of a research protocol. Enthusiastic patients sometimes source peptides online, but the purity and dosing accuracy of such products (like IGF-1 LR3 from research chem companies) are unreliable, and they might not come with proper medical guidance. This underscores the importance of involving a healthcare provider. There is some ongoing research interest: for example, anecdotally, a small group of providers and patients are discussing case series or observational trials of GH or related agents in transgender care. If those proceed, we may have published data in the coming years.</p><p><strong>Discussion: Efficacy vs. Risk and the Role of IGF-1 in Feminization</strong> The prospect of using IGF-1 to enhance breast growth sits at the cutting edge (and fringe) of transgender medicine. On one hand, it is grounded in solid biology – IGF-1 is indeed a linchpin of breast development, and logically, more of it should lead to more development. On the other hand, the <strong>uncontrolled nature of IGF-1’s effects</strong> and the serious risks make it a double-edged sword.</p><p>How <strong>effective</strong> might it be? If we hazard a guess from the pieces of evidence: A trans woman in her 40s on HRT for 2 years with an A-cup might, with IGF-1 therapy for 6-12 months, progress to a B-cup – perhaps gaining a few centimeters in bust circumference and noticeable fullness. It’s unlikely to miraculously create a C or D cup if one was destined for an A; genetic and other factors also limit growth. But for someone on the cusp (e.g., lots of underdeveloped gland that just needs a push), IGF-1 could make the difference between needing surgery or not. In some cases, the effect might be more about <em>quality</em> than quantity – firmer, more projected breasts due to more gland tissue, rather than just slightly bigger mounds of fat. Some patients might value even small improvements if it means avoiding implants or feeling more confident.</p><p>Dr. Powers’ exercise and protein experiment suggests that lifestyle changes can indeed boost IGF-1 enough to potentially matter. Before jumping to injections, it would be reasonable to ensure a patient is optimizing her own GH/IGF-1: weight training (especially legs and back exercises which provoke GH release), high-protein diet (protein provides amino acids like arginine which is involved in GH release, and prevents IGF-1 from dropping due to malnutrition), adequate sleep (most GH is secreted during deep sleep, so poor sleep can blunt IGF-1), and avoiding excess sugar (chronically high insulin can downregulate the GH-IGF axis). Even intermittent fasting or high-intensity interval training can acutely raise GH. These methods have none of the cost and little risk, aside from maybe muscle soreness. The downside is they require discipline and may not dramatically raise IGF-1 if someone’s baseline is very low – e.g., a 60-year-old could do all this and still have IGF-1 on the lower end because of age. But any improvement could help. And those behaviors themselves (exercise, nutrition) can improve body composition, which might indirectly improve breast appearance (e.g., building the pectoral muscle under the breast can give better lift and shape).</p><p>One more interesting note: <strong>Estradiol route</strong> might influence IGF-1 levels. Oral estradiol passes through the liver and tends to raise SHBG and possibly affect IGF-1 production more (some studies in cis women showed oral estrogen can reduce IGF-1 levels, whereas transdermal estrogen has less effect on IGF-1). So a trans woman on high-dose oral estrogen might inadvertently be suppressing IGF-1. Switching to transdermal or injection estradiol could increase IGF-1 and GH levels (since lack of first-pass may avoid the suppression). This is a simpler switch that might improve breast growth potential. Indeed, <strong>some trans women report better breast growth after switching from oral to injections</strong>, possibly due to more stable estrogen levels and perhaps higher IGF-1 as a side effect. Data: one study showed trans women on transdermal E had slightly higher IGF-1 than those on oral. This suggests that one basic step before exotic therapies is ensuring the estrogen delivery method isn’t hindering growth factor levels.</p><p><strong>Conclusion</strong> much like pioglitazone, igf-1 is good.</p><p>typical dosing and usage: cjc-1295 w/ dac medication and formulation: cjc-1295 with dac (drug affinity complex) is a synthetic analog of growth hormone-releasing hormone (ghrh) designed to stimulate the body’s own release of growth hormone (gh), which in turn increases insulin-like growth factor 1 (igf-1). unlike cjc-1295 without dac (aka mod-grf 1-29), the dac version has a long half-life (~5–8 days), allowing for infrequent injections (1–2 times per week). cjc-1295 alone can significantly raise igf-1 levels over time.</p><p>you can source it from the A tier site on this website: https://www.finnrick.com/products/cjc-1295</p><p>starting dose: a common experimental dose is 100–300 mcg of cjc-1295 w/ dac once weekly, injected subcutaneously. some protocols use 250–500 mcg once every 5 to 7 days, depending on body weight and goals. doses above 500 mcg do not appear to proportionally increase igf-1 and may raise risk of side effects (e.g. edema, joint pain). start at 100–200 mcg/week and titrate up if tolerated and desired effects are not seen after ~4–6 weeks.</p><p>administration: subcutaneous injection (abdomen or thigh), using insulin syringe. inject once weekly, ideally at the same time of day. it does not need to be timed with meals, but consistency helps maintain steady igf-1 elevation. due to the long half-life from dac binding, daily injections are unnecessary.</p><p>titration: if no side effects occur, one may increase to 250 mcg/wk after 2–3 weeks. most users stabilize at 250–300 mcg weekly, which yields modest but consistent increases in igf-1 (often 50–100 ng/mL above baseline). monitor igf-1 labs to avoid exceeding upper normal limits.</p><p>monitoring: check baseline igf-1, and again after 4–6 weeks. goal is to stay in upper-normal physiologic range (not supraphysiologic). monitor for edema, joint aches, or signs of carpal tunnel. optional labs include fasting glucose/insulin, since gh can cause transient insulin resistance. blood pressure and body weight should also be monitored. periodic breast measurements can track changes if used for feminization.</p><p>duration: run in 3–6 month cycles. if effective (e.g. increased breast growth, improved skin quality, or subjective changes), a second cycle can follow after a break. avoid continuous year-round use to minimize long-term risks like tissue overgrowth or gh/igf-1 receptor desensitization.</p><p>adjuncts: cjc-1295 w/ dac works best when paired with:</p><p>adequate estradiol levels (target 100–200 pg/mL). diet rich in protein, especially arginine and glycine, which support gh production. good sleep hygiene, since natural gh pulses occur mostly during deep sleep. optionally: combine with resistance training, which enhances gh release and may synergize with cjc for better tissue remodeling. contraindications: avoid in patients with:</p><p>active or previous cancer, especially hormone-sensitive types. diabetes, unless well-controlled. uncontrolled hypertension or heart disease (gh can cause sodium retention and cardiac remodeling). any signs of acromegaly or unexplained high igf-1 levels at baseline. patient education: patients should understand that cjc-1295 raises igf-1 indirectly, and effects may be subtle and slow (weeks to months). they should be instructed to:</p><p>track any breast changes, including soreness, fullness, or visible volume increase. report any signs of joint pain, facial bloating, or tingling in fingers. understand that breast growth is not guaranteed, and results may be modest compared to surgical augmentation. summary recommendation: for trans women who prefer a lower-maintenance and possibly safer alternative to direct igf-1 injection, cjc-1295 with dac offers a feasible way to raise igf-1 modestly. it avoids daily shots and has a more gradual onset, reducing hypoglycemia risk. it may be suitable for those who have:</p><p>poor breast response to hrt alone low baseline igf-1 no contraindications to gh stimulation willingness to track changes and monitor labs this peptide remains experimental and unapproved for breast development or transgender care, but when used cautiously, it may be one of the more accessible and tolerable growth axis modulators available.</p><h3>References and Citations</h3><p>1. Seal L.J. <em>et al.</em> (2012). <strong>Predictive markers for mammoplasty and a comparison of side effect profiles in transwomen taking various hormonal regimens.</strong> <em>J. Clin. Endocrinol. Metab.</em> 97(12):4422-4428. doi:10.1210/jc.2012-2030. – <em>Reported that despite hormone therapy, about 60% of trans women sought breast augmentation, highlighting limitations of HRT alone.</em></p><p>2. Ruan W. &amp; Kleinberg D.L. (1999). <strong>Insulin-like growth factor I is essential for terminal end bud formation and ductal morphogenesis during mammary development.</strong> <em>Endocrinology</em> 140(11):5075-5081. – <em>Demonstrated that IGF-1 is required for pubertal mammary gland development in animal models, as estrogen alone could not induce ductal growth without IGF-1.</em></p><p>3. Kleinberg D.L. <em>et al.</em> (2009). <strong>Growth hormone and insulin-like growth factor-I in the transition from normal mammary development to preneoplastic lesions.</strong> <em>Endocrine Reviews</em> 30(1):51-74. – <em>Comprehensive review showing that estrogen and progesterone actions in the breast are dependent on GH-induced IGF-1; systemic GH or IGF-1 causes mammary hyperplasia in rodents and blocking IGF-1 action prevents mammary development.</em></p><p>4. Biro F.M. <em>et al.</em> (2021). <strong>Pubertal growth, IGF-1, and windows of susceptibility: Puberty and future breast cancer risk.</strong> <em>J. Adolesc. Health</em> 69(2)\:S13-S20. – <em>Reported that IGF-1 levels correlate with pubertal milestones and that high IGF-1 is associated with greater breast density and elevated breast cancer risk. Notes that women with acromegaly (excess GH/IGF-1) have increased breast cancer incidence.</em></p><p>5. Powers, W. (2022). Personal communication on Reddit (/r/DrWillPowers). – <em>Dr. Will Powers shared clinical observations that younger trans women with naturally higher GH/IGF-1 have “stellar” breast development, whereas older patients often do not. He cautioned strongly against unmonitored HGH/IGF use due to acromegaly risks, and noted that physically active patients (who likely boost GH/IGF) tend to have better breast outcomes. He also found that patients with poor breast growth often had IGF-1 levels 1–3 SD below average, suggesting a link.</em></p><p>6. Beal C. (2023). <strong>“The Beal Method” – Optimizing Breast Development in Trans People.</strong> QueerDoc online article. – <em>Proposes a pubertal tempo hormone approach; acknowledges IGF-1 and GH contribute to breast development and notes a study in Turner syndrome where GH treatment improved satisfaction with breast development. Dr. Beal has considered adding GH to her protocol in the future once dosing and safety can be determined.</em></p><p>7. Nota N.M. <em>et al.</em> (2016). <strong>Increase in insulin-like growth factor-1 levels during cross-sex hormone treatment in transgender persons.</strong> <em>Endocrine Abstracts</em> 41: EP961. – <em>Found that in 89 transgender adults, mean IGF-1 levels increased moderately (by \~16% in MtF and \~10% in FtM) during the first 3 months of hormone therapy. This suggests GAHT itself has an effect on the GH/IGF axis.</em></p><p>8. Berlière M. <em>et al.</em> (2022). <strong>Effects of hormones on breast development and breast cancer risk in transgender women.</strong> <em>Cancers (Basel)</em> 15(1):245. – <em>A recent review discussing how cross-sex hormones influence breast tissue in trans women. Notes the complexity of hormone interactions (estrogen, progesterone, prolactin, IGF-1) on breast development and the importance of monitoring breast health in this population.</em></p><p>9. <strong>Mecasermin (recombinant IGF-1) – Prescribing Information and Safety.</strong> – <em>Common side effects include hypoglycemia (often requiring co-administration with meals), injection site reactions, headaches, tonsillar hypertrophy, arthralgias, and in rare cases intracranial hypertension. Patients on IGF-1 should be monitored for signs of low blood sugar and other adverse effects.</em></p><p>10. van de Grift T.C. <em>et al.</em> (2019). <strong>Breast development and satisfaction in women with disorders of sex development.</strong> <em>Human Reproduction</em> 34(12):2410-2417. – <em>Studied breast outcomes in women with DSD (including Turner syndrome). Reported that those treated with GH (as is common in Turner) had better breast development/satisfaction. Highlights the role of early and adequate hormone (including GH) treatment in achieving typical breast development.</em></p></article></div><footer class="mt-16 pt-8 border-t"><div class="flex flex-col sm:flex-row justify-between items-center gap-4"><p class="text-sm text-muted-foreground">published 23/07/2025</p><a class="text-sm text-foreground hover:opacity-70 underline" href="/">view all papers</a></div></footer></main>
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