Anabolic Steroids StatPearls NCBI Bookshelf

Anabolic Steroids: Pharmacology, Clinical Use, and Safety Considerations

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1. What is the mechanism of action for anabolic steroids?

Step	Mechanism	Result
1. Cellular uptake	Lipophilic steroid enters cell via passive diffusion or carrier‑mediated transport.	Steroid reaches cytoplasm.
2. Nuclear binding	Dissociates from heat‑shock protein complexes → binds directly to the intracellular androgen receptor (AR).	AR–steroid complex forms.
3. DNA transcription	Complex translocates to nucleus, attaches to androgen response elements (AREs) on target gene promoters.	Recruitment of co‑activators (p300/CBP), histone acetyltransferases → chromatin remodeling.
4. Gene expression	Initiation of mRNA synthesis for anabolic proteins: IGF‑1, myosin heavy chain, creatine kinase, etc.; suppression of pro‑catabolic genes (myostatin).	Protein translation → muscle hypertrophy.
5. Systemic effects	Upregulation of glucose transporter type 4 (GLUT4) → insulin‑like sensitivity; increased testosterone synthesis via HMG‑CoA reductase activation, aromatization to estradiol for bone health; stimulation of erythropoiesis via EPO up‑regulation.	Enhanced oxygen delivery and performance.

Key points

Anabolic signaling: Testosterone binds androgen receptors → dimerizes with DNA → transcriptional activation.

Protein synthesis vs degradation balance: ↑S6K1, ↑mTORC1; ↓FoxO3a activity; ↓Atrogin‑1/MAFbx expression.

Metabolic shift: Increased glycogen storage and lipid oxidation in muscle fibers.

2. How anabolic steroids affect the male reproductive system

Effect	Mechanism	Clinical consequence
Suppressed spermatogenesis	Exogenous testosterone > LH/FSH → negative feedback on pituitary → ↓LH, ↓FSH. Sertoli cells need FSH; Leydig cells need LH for endogenous testosterone production.	Oligo‑ or azoospermia; reduced sperm count and motility.
Testicular atrophy	Loss of intratesticular hormone production (no testosterone from Leydig cells) → shrinkage of seminiferous tubules.	Reduced testicular volume, infertility.
Gynecomastia	Aromatization of excess testosterone to estrogen in adipose tissue. Estrogen binds ERα → stimulates breast tissue proliferation.	Breast tenderness, enlargement.
Reduced libido & erectile dysfunction	Low endogenous testosterone; altered androgen receptor signaling; possible increased prolactin (due to hypothalamic-pituitary changes).	Decreased sexual desire, impaired erection.
Sleep apnea exacerbation	Hormonal changes affect airway muscle tone; weight gain from anabolic steroid use increases fat deposition around neck.	More frequent apneic events, worsened oxygen desaturation.

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3. Differential Diagnosis

Clinical Feature	Possible Condition	Rationale
Breast enlargement (painless)	Gynecomastia secondary to anabolic steroid use; hyperthyroidism; liver disease	Steroids increase aromatase → estrogen ↑; thyrotoxicosis causes breast edema
Fatigue, weakness	Hypothyroidism (primary or central), anemia, chronic kidney disease	TSH low/normal with high fT4 suggests secondary hypothyroid or thyrotoxic periodic paralysis
Palpitations / tachycardia	Thyrotoxicosis, anxiety, electrolyte imbalance	Thyroid hormone excess → increased HR; hypokalemia also causes palpitations
Weight gain	Hypothyroidism (central), glucocorticoid therapy, lifestyle	Central hypothyroidism leads to metabolic slowdown
Sleep disturbance / insomnia	Anxiety, caffeine intake, thyroid hormone excess	Elevated T4 can disrupt sleep patterns

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2. Differential Diagnoses

Condition	Supporting Features	Opposing Features
Central (hypothalamic/pituitary) hypothyroidism	Low FT4, normal/low TSH, low IGF‑1, low LH/FSH, weight gain, fatigue, cold intolerance.	None; fits all findings.
Primary (T3/T4) hypothyroidism	Usually elevated TSH.	TSH is normal.
Secondary pituitary failure	Low IGF‑1, low gonadotropins.	TSH and FT4 are within reference range.
Syndrome X (hypogonadotropic hypogonadism)	Low LH/FSH with normal or slightly elevated prolactin.	Fits.
Pituitary adenoma	Elevated prolactin, mass effect.	No visual field deficits; prolactin only mildly increased.
Hypothalamic dysfunction	Low GnRH leading to low gonadotropins.	Possible.

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4. Differential Diagnosis

Category	Specific Conditions	Key Features / Rationale
Endocrine Causes	Hypogonadotropic hypogonadism (Sertoli‑cell dysfunction)	Low LH/FSH; low testosterone; normal prolactin; no visual field loss.
	Idiopathic hypogonadotropic hypogonadism	Usually normal pituitary imaging; may have delayed puberty in males.
	Hypothalamic disease (e.g., infiltrative, glioma)	Low gonadotropins; possible other pituitary hormone deficits or neuro symptoms.
	Primary testicular failure	Would present with high LH/FSH, not low.
Neurological Causes	Pituitary adenoma causing hypopituitarism	Visual field loss is typical but can be mild or absent early on.
	Craniopharyngioma	Often presents in children, visual deficits common.
	Hydrocephalus, meningitis, trauma	Could compress pituitary or hypothalamus, affecting hormone release.
Endocrine Disruptors	Thyroid disorders, adrenal insufficiency (secondary)	Might cause low LH/FSH but with other hormonal changes.

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5. How the Two Findings Interrelate

Hypothalamic‑Pituitary Axis:

The hypothalamus secretes gonadotropin‑releasing hormone (GnRH), which drives pituitary secretion of LH and FSH. Any structural or functional lesion affecting the hypothalamus, pituitary stalk, https://itheadhunter.vn or anterior lobe can disrupt GnRH release and consequently lower LH/FSH.

Visual Pathway Involvement:

The optic chiasm is anatomically adjacent to the pituitary stalk. Tumors (e.g., craniopharyngioma, pituitary adenoma), inflammatory processes, or ischemia in this area can compress both visual pathways and the pituitary stalk, explaining simultaneous visual deficits and endocrine dysfunction.

Differential Diagnoses:

- Pituitary Adenoma: Often compresses optic chiasm → bitemporal hemianopsia; can cause hypopituitarism.

- Craniopharyngioma: Benign but tends to involve optic pathways and pituitary stalk.

- Hypothalamic–pituitary Apoplexy: Sudden hemorrhage/ischemia → visual changes + endocrine crisis.

- Inflammatory Disorders (e.g., Lymphocytic Hypophysitis): May affect stalk & chiasm.

- Neurohypophyseal Arteriovenous Malformations: Rare, but can produce similar symptoms.

Thus the clinical picture strongly suggests a lesion at or near the optic chiasm/pituitary region that also involves the pituitary stalk—most commonly a pituitary macroadenoma, especially if it is invasive. Imaging (MRI) and endocrine evaluation would confirm the diagnosis.

Answer: The combined visual disturbance of bitemporal hemianopia with a pituitary stalk‑related headache points to a compressive lesion at the optic chiasm that also involves or displaces the pituitary stalk—most often a large, invasive pituitary macroadenoma (or similarly sized sellar mass).