Key Benefits

• Check the pituitary hormone that drives egg development and sperm production.
• Spot hormonal imbalance behind irregular periods, missed cycles, hot flashes, or infertility.
• Clarify menopause status or premature ovarian insufficiency when FSH stays high.
• Guide male fertility workup by flagging testicular failure when FSH runs high.
• Distinguish primary from secondary hypogonadism to direct imaging or endocrine tests.
• Support evaluation of delayed or early puberty by assessing gonadal axis activity.
• Guide fertility planning by indicating diminished ovarian reserve when persistently elevated.
• Best interpreted with LH, estradiol/AMH, testosterone/semen analysis, and cycle timing.

What is a Follicle Stimulating Hormone (FSH) blood test?

Follicle Stimulating Hormone (FSH) is a signaling hormone in your bloodstream, made by the front part of the pituitary gland at the base of the brain (anterior pituitary gonadotropin). Specialized pituitary cells release FSH under cues from the brain (gonadotropin-releasing hormone, GnRH). An FSH blood test simply measures how much of this hormone is circulating at a given moment, capturing one piece of the body’s reproductive control system (the hypothalamic–pituitary–gonadal axis).

What it does: In ovaries, FSH drives the growth of fluid-filled follicles and the hormone-making cells that support them (granulosa cells), leading to estrogen (estradiol) production and priming for ovulation. In testes, FSH activates support cells (Sertoli cells) that nurture sperm formation (spermatogenesis) and make inhibin B. Because FSH output changes with feedback from the ovaries or testes (sex steroids and inhibin), its level reflects how the pituitary and gonads are communicating, and the capacity of these tissues to develop eggs or produce sperm.

Why is a Follicle Stimulating Hormone (FSH) blood test important?

FSH is a pituitary “signal” that tells ovaries to mature follicles and make estradiol, and tells testes to support sperm production. Because sex hormones guide bones, brain, metabolism, and cardiovascular tone, FSH is a window into the entire hypothalamic–pituitary–gonadal axis, fertility potential, and overall hormonal balance.

In menstruating adults, FSH naturally fluctuates: low-to-mid single digits through most of the cycle with a modest bump around ovulation. Men usually sit in a steady low-to-mid single-digit range. After menopause it rises substantially, often several-fold above premenopausal values. Children are very low before puberty, then rise into adolescent ranges. In general, “healthy” values live in the context-appropriate middle rather than at extremes.

When values are lower than expected for age and sex, it usually reflects reduced drive from the brain (hypothalamus/pituitary) or suppression by external hormones. That can occur with functional hypothalamic states (stress, undernutrition, intense training), pituitary disorders, high prolactin, or thyroid-related signals; pregnancy also keeps FSH low. Consequences are low estradiol or testosterone: irregular or absent periods, infertility, low libido, erectile issues, low bone density, fatigue, and delayed puberty in youth.

When values are higher than expected, the pituitary is “shouting” because the ovaries or testes aren’t responding (primary gonadal failure). This is typical in natural menopause and can appear with primary ovarian insufficiency, gonadotoxic chemotherapy/radiation, Turner or Klinefelter syndromes, or testicular injury. Effects include infertility, hot flashes, night sweats, vaginal dryness, mood and sleep changes, and in men low libido and reduced muscle mass.

Big picture: FSH integrates with LH, estradiol/testosterone, prolactin, and thyroid status. Tracking it helps explain menstrual patterns, puberty timing, fertility, and the menopausal transition—and signals downstream risks in bone, cardiometabolic health, and quality of life when sex-steroid levels are chronically low.

What insights will I get?

A Follicle Stimulating Hormone (FSH) blood test measures a pituitary signal that stimulates ovarian follicles in women and supports Sertoli cells and sperm production in men. It reflects the health of the hypothalamic–pituitary–gonadal axis and the feedback from sex steroids (estradiol, progesterone, testosterone) and inhibins. Because these hormones influence fertility, bone remodeling, body composition, mood, and cognition, FSH is a window into broader metabolic and reproductive stability.

Low values usually reflect reduced pituitary drive or hypothalamic suppression (secondary hypogonadism). In women, this can mean irregular or absent cycles and anovulation with lower estrogen; in men, reduced spermatogenesis with lower intratesticular testosterone. Common contexts include pituitary disorders, high prolactin, severe stress or illness, under‑nutrition, and exposure to external sex steroids. Pregnancy, lactation, and many hormonal contraceptives physiologically suppress FSH. Low-for-age values are normal before puberty.

Being in range suggests coordinated signaling between brain and gonads with appropriate sex steroid feedback. In cycling women, it supports follicle development and predictable ovulation; in men, steady support of sperm production. For reproductive‑age adults, basal FSH typically sits in the low-to-mid portion of phase‑specific reference ranges outside the ovulatory surge, indicating hormonal stability and balanced bone and metabolic effects.

High values usually reflect reduced ovarian or testicular feedback (primary gonadal dysfunction). In women, this is typical after menopause and in premature ovarian insufficiency, with systemic effects of low estrogen on bones, vasomotor tone, and lipids. In men, high FSH suggests impaired seminiferous tubules (e.g., prior chemotherapy, mumps orchitis, or chromosomal causes) with low fertility and androgen deficiency features. In children, high-for-age values warrant age‑specific interpretation.

Notes: Interpretation depends on age, sex, menstrual cycle day, and assay. FSH is pulsatile and is best interpreted with LH, estradiol or testosterone, and sometimes AMH or inhibin B. Medications, pregnancy, lactation, acute illness, and lab-specific ranges materially affect results.