Infertility
Infertility is a disease of the male or female reproductive system defined by the failure to achieve a pregnancy after 12 months or more of regular unprotected sexual intercourse.[1] It affects both sexes, with causes including impaired gamete production, transport, or fertilization, and can be primary (no prior pregnancies) or secondary (following previous conceptions).[1] Globally, approximately 17.5% of the adult population—roughly one in six people—experiences infertility in their lifetime, with prevalence similar across high- and low-income countries at around 17-18%.[2] Recent studies indicate an increasing burden, with female infertility cases rising over 100% in certain age groups like 30-34 from 1990 to 2021, driven partly by delayed childbearing amid declining natural fertility with age.[3] Causes are multifactorial: in women, ovulatory disorders account for about 25% of cases, tubal blockages around 20-36%, and endometriosis 6%; in men, low sperm count or motility contributes comparably, often 19-50% depending on cohorts; unexplained factors comprise 10-40%.[4][5] Lifestyle elements like obesity, smoking, and environmental exposures exacerbate risks, while age-related oocyte quality decline in women post-35 sharply reduces conception odds, reflecting biological imperatives over modifiable factors alone.[6] Treatments range from lifestyle interventions and medications to assisted reproductive technologies like in vitro fertilization (IVF), which has enabled over 95,000 U.S. births annually by 2023, with live birth rates per cycle around 55% for women under 35 but dropping below 25% after 40.[7][8] Success often requires multiple cycles, highlighting IVF's role as a milestone achievement yet limited by maternal age and underlying pathologies.[9] Controversies persist over access inequities and debates on whether rising rates stem more from deferred reproduction or unproven environmental claims, underscoring the need for empirical focus on causal biology.[2]Definition and Classification
Core Definitions and Physiological Basis
Infertility is defined medically as the failure to achieve a clinical pregnancy after 12 months of regular, unprotected sexual intercourse in couples where the woman is under 35 years of age, or after 6 months if she is 35 or older. This timeframe accounts for the natural monthly fecundity rate of approximately 20-25% in healthy couples during peak reproductive years, allowing for statistical differentiation between subfertility and chance. Clinical pregnancy refers to evidence of embryonic development confirmed by ultrasound or histopathological examination, distinguishing it from biochemical markers alone.[10] Physiologically, human reproduction requires synchronized gamete production, transport, fertilization, and implantation. In females, oogenesis begins in fetal life with a finite pool of primordial follicles (approximately 1-2 million at birth, declining to 300,000-400,000 by puberty), where monthly recruitment yields one dominant oocyte via follicular development driven by pituitary gonadotropins (FSH and LH). Ovulation releases the oocyte into the fallopian tube, where fertilization by sperm must occur within 12-24 hours due to oocyte viability limits. Sperm capacitation—acquiring hyperactivated motility and acrosome reaction—enables zona pellucida penetration, followed by pronuclear fusion and embryonic cleavage. Successful reproduction further demands zygote transport to the uterus (via tubal cilia and contractions), endometrial receptivity for implantation (peaking days 20-24 of a 28-day cycle, regulated by progesterone and integrins), and early trophoblast invasion to establish placentation. Male physiology centers on spermatogenesis, a continuous process in seminiferous tubules yielding 100-200 million sperm per ejaculate, with 40-60% motility and <15% abnormal forms deemed normal per WHO thresholds (2021 criteria). Disruptions at any stage—e.g., anovulation (affecting 25% of female infertility cases), tubal blockage (from pelvic inflammatory disease, impacting 20-30%), or oligospermia (<15 million/mL, in 40-50% of male cases)—yield infertility, often multifactorial with combined male-female contributions in 30-40% of couples.32476-6/fulltext) These processes reflect evolved efficiencies under natural selection, where age-related declines (e.g., oocyte aneuploidy rising from 20% at age 25 to 80% at 40) underscore fertility's temporal constraints.Primary Versus Secondary Infertility
Primary infertility is defined as the inability to achieve a clinical pregnancy after 12 months or more of regular, unprotected sexual intercourse in couples who have never previously conceived.[11][1] This threshold shortens to 6 months for women aged 35 or older due to age-related declines in fertility.[11] The definition applies to both partners, though evaluation often focuses on female factors initially, as they account for approximately 40-50% of cases in primary infertility.[12] In contrast, secondary infertility occurs when a couple has previously achieved at least one pregnancy—resulting in a live birth, miscarriage, or ectopic pregnancy—but cannot conceive again after 12 months of trying under similar conditions.[1][13] Like primary infertility, the timeframe adjusts for women over 35. Secondary cases represent a distinct clinical entity, as prior fertility indicates that baseline reproductive physiology was once functional, but subsequent factors have impaired it.[14] Key differences between primary and secondary infertility lie in etiology and psychological impact. Primary infertility often stems from congenital or longstanding issues, such as untreated ovulatory disorders, tubal blockages from pelvic inflammatory disease, or untreated male factor infertility like low sperm count.[12] Secondary infertility, however, frequently arises from acquired changes post-pregnancy, including uterine adhesions (Asherman's syndrome) from curettage after miscarriage or delivery, age-related ovarian reserve depletion accelerating after the first birth, or complications like endometriosis progression or male age-related sperm DNA fragmentation.[13][12] Hormonal disturbances, such as polycystic ovary syndrome exacerbations or thyroid dysfunction unmasked after childbirth, are more prevalent in secondary cases.[12] Both types share overlapping causes like obesity or smoking, but secondary infertility diagnostic protocols prioritize reviewing obstetric history to identify interval-acquired pathologies.[13] Prevalence data indicate secondary infertility may be more common globally than primary, with estimates from 1990-2010 showing primary rates at 0.6-3.4% and secondary at 8.7-32.6% across regions.[15] In the United States, secondary infertility affects about 11% of couples, matching primary rates, yet it constitutes up to 60% of infertility clinic referrals due to underreporting among parous couples who delay seeking help.[16][17] Worldwide, infertility impacts roughly 1 in 6 people of reproductive age, with secondary cases often linked to rising maternal age at subsequent pregnancies, averaging 30-35 years in developed nations.[1] These patterns underscore that secondary infertility, while biologically similar in mechanisms, carries a higher stigma and diagnostic delay, as affected individuals may attribute failures to chance rather than pathology.[17]Variations Across Definitions
The World Health Organization (WHO) and the International Committee for Monitoring Assisted Reproductive Technology (ICMART), in their 2017 glossary, define infertility as "a disease of the reproductive system defined by the failure to achieve a clinical pregnancy after 12 months or more of regular unprotected sexual intercourse."[1][18] This definition emphasizes physiological impairment and requires empirical evidence of failed conception attempts, distinguishing it from voluntary childlessness or transient delays in fertility.[1] Variations arise in the temporal threshold for diagnosis, particularly with age-related adjustments. While the 12-month benchmark applies broadly, clinical guidelines from organizations like the American Society for Reproductive Medicine (ASRM) recommend initiating evaluation after 6 months for women aged 35 or older, reflecting accelerated age-related declines in oocyte quantity and quality that reduce per-cycle fecundity from approximately 20-25% in the early 30s to under 5% by age 40.[19] This adjustment prioritizes earlier intervention without redefining the core condition, as strict adherence to 12 months could delay treatment in cases where cumulative probability of conception drops sharply after age 35.[20] Epidemiological studies highlight how such definitional flexibility affects prevalence estimates; for instance, unprotected intercourse-based criteria classify more individuals as infertile in younger cohorts (ages 18-29) compared to older ones, potentially inflating early-life rates if not contextualized by attempt duration.[20] Further divergence occurs in inclusivity criteria, moving beyond assumptions of heterosexual intercourse. The ASRM's 2023 committee opinion expands infertility to encompass "the need for medical intervention—including, but not limited to, in vitro fertilization—to achieve a reproductive goal, regardless of age, marital status, sexual orientation, or gender identity," framing it as a disease impairing reproductive function irrespective of partnership dynamics.[21] This shift addresses limitations in intercourse-centric definitions, which exclude same-sex couples, single individuals, or those using donor gametes, while aligning with causal realities of reproductive barriers like gamete dysfunction or uterine factors that necessitate assisted reproduction.[21] In contrast, the WHO definition retains a focus on natural conception attempts, potentially underrepresenting non-traditional pathways in global data.[1] These definitional evolutions reflect ongoing debates between physiological specificity and equitable access to diagnostics, with evidence indicating that broader criteria improve early detection without diluting empirical standards.[20]Causes of Infertility
Female-Specific Biological Factors
Female infertility arises from disruptions in the reproductive tract's biological processes, including ovulatory dysfunction, structural abnormalities in the fallopian tubes or uterus, and age-related decline in oocyte quantity and quality. Ovulatory disorders, which prevent the release of viable eggs, constitute about 25% of diagnosed cases. These include polycystic ovary syndrome (PCOS), the most prevalent endocrine disorder affecting 6-12% of reproductive-age women, where elevated androgens and insulin resistance disrupt follicular development and lead to chronic anovulation. Hyperandrogenism in PCOS inhibits ovulation by altering gonadotropin secretion and promoting cyst formation rather than dominant follicle maturation. Hypothalamic-pituitary axis dysfunction, often from stress-induced hyperprolactinemia, further contributes by suppressing gonadotropin-releasing hormone, resulting in oligo-ovulation or amenorrhea. Age exerts a profound biological effect through diminished ovarian reserve, where the finite pool of primordial follicles—peaking at about 1-2 million at birth and declining to 1,000 by menopause—depletes progressively, accelerating after age 35. By age 40, natural fecundity drops to 5% per cycle from 20-25% in the early 20s, attributable to both quantitative loss and qualitative defects like increased aneuploidy in oocytes due to accumulated meiotic errors and mitochondrial dysfunction. Anti-Müllerian hormone (AMH) levels, a marker of follicular pool size, fall correspondingly, with women over 35 showing threefold higher infertility risk. Premature ovarian insufficiency, affecting 1% of women under 40, mirrors this process earlier via accelerated follicular atresia, often linked to genetic mutations in genes like FOXL2 or BMP15. Tubal factors account for 25-35% of female infertility, primarily from blockages or adhesions that impede sperm transport, fertilization, or embryo migration to the uterus. Proximal tubal occlusion, seen in 10-25% of such cases, often stems from inflammatory scarring post-pelvic inflammatory disease (PID), while distal hydrosalpinx results from chronic obstruction. Endometriosis, present in up to 10% of reproductive-age women, exacerbates tubal issues through ectopic endometrial tissue inducing pelvic adhesions, inflammation, and oxidative stress that impairs oocyte pickup and tubal peristalsis; infertility rates reach 30-50% in affected women, though causation involves multifactorial mechanisms beyond anatomy, including altered peritoneal fluid cytokines reducing sperm motility and embryo implantation potential. Uterine abnormalities, such as leiomyomas (fibroids) in 20-40% of women over 35, distort the endometrial cavity or alter myometrial contractility, hindering implantation; submucosal fibroids particularly elevate miscarriage risk by 20-30% via vascular disruption and inflammatory cytokine release. Congenital anomalies like unicornuate uterus, occurring in 0.1% of women, reduce implantation success by 15-20% due to reduced cavity volume and asymmetric vascular supply. Cervical factors, though rarer (less than 5%), involve hostile mucus from chronic cervicitis that blocks sperm ascent during ovulation. These biological impediments underscore the interplay of hormonal, anatomical, and cellular processes in female reproductive failure.Male-Specific Biological Factors
Male-specific biological factors in infertility encompass disruptions to spermatogenesis, sperm quality, and ejaculatory function, detectable via semen analysis revealing oligospermia (sperm concentration <15 million/mL), asthenospermia (motility <32%), teratospermia (normal morphology <4%), or azoospermia (absence of sperm). These impairments contribute to 20% of cases where males are solely responsible and 30-50% of couples experiencing infertility overall.[22][23] Spermatogenesis, the process of germ cell proliferation and maturation in the seminiferous tubules under hormonal regulation by follicle-stimulating hormone (FSH) and testosterone, fails due to intrinsic testicular defects, leading to reduced sperm output or defective gametes unable to fertilize oocytes.[22] Varicocele, involving unilateral or bilateral dilation of the pampiniform plexus veins within the scrotum, represents the most prevalent surgically correctable biological cause, affecting 15% of adult males generally but 35-40% of those with primary infertility. Elevated scrotal temperature from venous stasis induces oxidative stress, apoptosis of germ cells, and DNA fragmentation in sperm, correlating with lower semen parameters and DNA integrity compared to normospermic men.[24][25] World Health Organization data from large-scale analyses confirm significantly reduced sperm concentration in infertile men with varicocele versus those without, though causality remains debated due to observational study limitations and variable post-treatment fertility gains of 10-30% in pregnancy rates.[25][26] Genetic anomalies account for 15-30% of severe cases, particularly non-obstructive azoospermia or oligozoospermia, by directly impairing germ cell development or meiotic division. Klinefelter syndrome (47,XXY karyotype), the most common sex chromosome aneuploidy with incidence of 1:500-1:000 male births, causes progressive hyalinization of seminiferous tubules, germ cell depletion, and elevated FSH from primary hypogonadism, resulting in azoospermia in 90-100% of untreated cases.[27][28] Y-chromosome microdeletions in azoospermia factor (AZF) regions, detected in 10-15% of men with non-obstructive azoospermia, delete multicopy genes like DAZ essential for spermatogonial proliferation, with complete AZFa or AZFb deletions yielding uniformly absent sperm retrieval while AZFc allows focal spermatogenesis in 50% of cases.[29][28] These deletions arise de novo or inherit maternally but transmit paternally only if sperm is present, raising ethical concerns in assisted reproduction.[29] Endocrine dysregulation at the testicular level, such as primary hypogonadism from Sertoli or Leydig cell failure, manifests as hypergonadotropic hypogonadism with FSH >10 IU/L and low testosterone (<300 ng/dL), signaling defective feedback and spermatogenic arrest.[22] Idiopathic testicular failure, lacking identifiable genetic or structural etiology, predominates in 60-70% of non-obstructive azoospermia cases, potentially involving subtle microvascular or apoptotic pathways that evade routine diagnostics.[30] Congenital conditions like cryptorchidism, if uncorrected post-puberty, reduce ipsilateral spermatogenesis by 40-50% via heat-induced damage, compounding bilateral fertility deficits.[31]Genetic, Immune, and Infectious Causes
Genetic causes of infertility encompass chromosomal abnormalities and monogenic mutations that disrupt gametogenesis, hormonal regulation, or structural development of reproductive organs in both sexes. In females, Turner syndrome (45,X karyotype) is a primary chromosomal cause, occurring in approximately 1 in 2,000 to 2,500 live female births and resulting in ovarian dysgenesis with streak gonads, leading to primary amenorrhea and infertility due to absent or dysfunctional oocytes.[32] X chromosome abnormalities represent the most frequent genetic etiology of female infertility, accounting for about 10% of cases overall.[33] In males, Klinefelter syndrome (47,XXY) affects 1 in 500 to 1,000 males and typically causes non-obstructive azoospermia through testicular dysgenesis and elevated gonadotropins.[28] Y-chromosome microdeletions, particularly in the azoospermia factor (AZF) regions, occur in 7% of men with azoospermia or severe oligozoospermia, impairing spermatogenesis by deleting genes essential for sperm production.[34] Monogenic causes include over 100 validated genes associated with phenotypes such as non-obstructive azoospermia or multiple morphological abnormalities of the sperm flagella, with autosomal recessive inheritance predominant; these account for roughly 4% of diagnosed male infertility cases.[28] Immune-mediated infertility primarily involves antisperm antibodies (ASAs), which bind to sperm antigens and impair motility, capacitation, acrosome reaction, and fertilization capacity. ASAs arise from immune exposure to sperm antigens due to breaches in the blood-testis barrier, such as from testicular trauma, vasectomy (affecting 70-100% of cases), infections, or varicocele, though idiopathic origins occur.[35] Prevalence in infertile men ranges from 2.6% to 6.6%, significantly higher than in fertile controls (0.9-2.5%), with detection via direct assays like mixed antiglobulin reaction (MAR) or immunobead tests showing binding on >50% of sperm indicating clinical relevance.[36] [35] In women, circulating ASAs can similarly hinder sperm transport or penetration, though male-factor immunological infertility predominates; associated conditions include autoimmune disorders like thyroiditis or celiac disease, which may indirectly exacerbate infertility through ovulatory disruption. Diagnosis requires immunological semen analysis per WHO guidelines, as ASAs correlate with reduced natural conception rates but variable IVF success.[35] Infectious agents, particularly sexually transmitted infections (STIs), contribute to infertility via direct gonadal damage or secondary complications like pelvic inflammatory disease (PID). Chlamydia trachomatis and Neisseria gonorrhoeae are leading causes, with untreated chlamydial infections progressing to PID in 10-15% of women, resulting in tubal scarring, adhesions, and obstruction that manifest as tubal factor infertility (TFI).[37] Globally in 2021, chlamydia accounted for 24.87% (4.76 million cases) of infection-attributable female infertility, while gonorrhea contributed 3.82% (0.73 million cases), with TFI representing 11-67% of infertility etiologies depending on region.[38] In men, these pathogens can induce epididymitis or prostatitis, leading to obstructive azoospermia or reduced sperm quality; additionally, non-STI infections like mumps orchitis cause permanent testicular atrophy in 20-30% of post-pubertal cases. Early antibiotic treatment mitigates risks, but asymptomatic infections amplify prevalence, underscoring screening's role in prevention.[39]Lifestyle and Environmental Contributors
Smoking tobacco is associated with reduced fertility in both sexes, with meta-analyses indicating an odds ratio of approximately 1.6 for infertility among female smokers compared to nonsmokers.[40] In men, smoking correlates with lower sperm quality and count, contributing to prolonged time to conception.[41] Excessive alcohol consumption elevates infertility risk, with studies reporting adjusted odds ratios of 2.0 to 2.5 for moderate to high intake levels in both genders.[42] Obesity, often measured by elevated body mass index or relative fat mass, independently increases infertility odds, particularly in women, by disrupting ovulatory function and hormonal balance; one analysis linked higher relative fat mass to significantly elevated risk in women aged 18-45.[43] Dietary patterns and physical inactivity further compound risks, as imbalanced nutrition and sedentary behavior impair gamete quality and reproductive hormone levels, with systematic reviews identifying these as modifiable contributors to infertility prevalence.[44] Chronic stress and poor sleep, often tied to lifestyle, may exacerbate these effects through cortisol-mediated disruptions in reproductive physiology, though causal links require further longitudinal data.[45] Environmental exposures to endocrine-disrupting chemicals (EDCs) such as bisphenol A (BPA) from plastics and phthalates from consumer products are linked to fertility impairment, with human studies showing BPA associated with altered sperm parameters, reduced ovarian reserve, and extended time to pregnancy.[46][47] Pesticide residues, including organophosphates, correlate with decreased semen concentration and quality in exposed populations, based on epidemiological data from agricultural workers and general cohorts.[48] Heavy metals like lead and cadmium, alongside per- and polyfluoroalkyl substances (PFAS), exhibit similar associations with ovulatory dysfunction and spermatogenic defects, as evidenced in reviews of occupational and environmental exposure studies.[49] While some meta-analyses report inconsistent male fertility links for certain EDCs, population-level trends and mechanistic evidence from hormone receptor interference support causal contributions, particularly for female reproductive outcomes.[50][51]Diagnosis and Assessment
Initial Evaluation and Testing
The initial evaluation of infertility involves a systematic assessment of both partners to identify treatable causes efficiently. Guidelines recommend initiating evaluation after 12 months of regular, unprotected intercourse for women under 35 years of age, or after 6 months for those 35 years or older, with earlier assessment warranted in cases of known risk factors such as irregular menses, prior pelvic surgery, or advanced maternal age exceeding 40 years.[52] [53] [54] Concurrent evaluation of male and female partners is standard, as male factors contribute to approximately 40% of cases, female factors to another 40%, and combined issues to 20%.[55][56] A comprehensive history precedes testing, encompassing medical conditions (e.g., diabetes, thyroid disorders), surgical history (e.g., appendectomy, endometriosis excision), reproductive details (e.g., coital frequency, prior pregnancies, menstrual cycle length), family history of genetic disorders, and lifestyle factors (e.g., smoking, alcohol use, body mass index).[57][54] Physical examination focuses on relevant systems: for women, a pelvic exam assesses uterine size, adnexal masses, and signs of hyperandrogenism; for men, genital exam evaluates testicular volume (normal >15 mL per testis via orchidometer) and varicocele presence.[52][58] Semen analysis serves as the cornerstone initial test for male fertility, performed after 2-5 days of ejaculatory abstinence and including measures of volume (normal ≥1.5 mL), total sperm count (≥39 million per ejaculate), concentration (≥15 million/mL), motility (≥40% total, ≥32% progressive), and morphology (≥4% normal forms per strict criteria).[56][59] Abnormal results prompt repeat analysis or further endocrine testing (e.g., testosterone, FSH, LH) only if indicated, as routine hormonal screening lacks evidence for all men.[58] For women, initial testing confirms ovulation through midluteal-phase serum progesterone (>3 ng/mL indicating ovulation) or cycle tracking via basal body temperature or urinary luteinizing hormone kits, as anovulation underlies 25% of female infertility.[52][59] Ovarian reserve assessment typically includes day-3 follicle-stimulating hormone (FSH <10 mIU/mL optimal) and anti-Müllerian hormone (AMH) levels, with AMH providing a more reliable gauge of antral follicle count independent of cycle day.[52][60] Basic screening for thyroid-stimulating hormone and prolactin occurs if history suggests endocrine disruption, given hypothyroidism's prevalence in 2-4% of reproductive-age women and its reversible impact on fertility.[52] Transvaginal ultrasound evaluates uterine anatomy and ovarian morphology, while hysterosalpingography (HSG) or sonohysterography assesses tubal patency and intracavitary lesions if initial findings warrant.[52][60] These steps prioritize cost-effective, non-invasive tests before advancing to laparoscopy or genetic karyotyping.[61]Advanced Diagnostic Techniques
Advanced diagnostic techniques for infertility extend beyond initial evaluations such as semen analysis, ovulation assessment, and basic imaging, employing invasive procedures and molecular analyses to pinpoint structural, genetic, or functional anomalies in reproductive organs or gametes. These methods are typically reserved for cases of unexplained infertility, suspected endometriosis, tubal factors, or severe oligospermia/azoospermia, as they carry procedural risks like infection or anesthesia complications but offer higher diagnostic precision. Evidence from systematic reviews supports their utility in improving subsequent fertility outcomes when abnormalities are identified and treated.[62] In female patients, laparoscopy serves as the gold standard for evaluating tubal patency and pelvic pathology, involving chromopertubation to detect blockages and direct visualization of endometriosis or adhesions. Performed under general anesthesia via small abdominal incisions, it is indicated for suspected stage III/IV endometriosis or hydrosalpinx, with studies showing improved spontaneous pregnancy rates post-resection (e.g., a 2021 JAMA analysis of endometriosis treatment).[62][63] Hysteroscopy, an endoscopic examination of the uterine cavity, identifies intrauterine lesions like polyps or submucosal fibroids that may impair implantation; a 2018 Cochrane review of randomized trials demonstrated higher live birth rates following polypectomy in affected women.[62] Advanced imaging adjuncts, such as sonohysterography (saline-infused ultrasound) or 3D ultrasound/MRI, enhance detection of congenital uterine malformations (e.g., bicornuate uterus) with sensitivities up to 91% for polyps, reserved for recurrent miscarriage or abnormal bleeding.[62] Genetic testing represents a cornerstone of advanced diagnostics across genders, targeting heritable defects contributing to gamete dysfunction or diminished reserve. For women over 35 or with family history of premature ovarian insufficiency, fragile X premutation screening (FMR1 gene, 55-200 CGG repeats) assesses ovarian reserve risks.[62] In men, karyotyping detects chromosomal aberrations like Klinefelter syndrome (prevalent in 15% of azoospermic cases), while Y-chromosome microdeletion analysis via PCR identifies AZF region losses in up to 10-15% of severe oligospermia (<5 million/mL), informing surgical sperm retrieval success rates of 47% per meta-analysis.[64] Fluorescent in situ hybridization (FISH) evaluates sperm aneuploidy rates, elevated in infertile males and predictive of IVF/ICSI outcomes.[64] For male infertility, testicular biopsy provides histopathological insight into spermatogenesis arrest or maturation defects, particularly in obstructive or nonobstructive azoospermia, and facilitates sperm extraction for assisted reproduction; it reveals lower DNA fragmentation in testicular versus ejaculated sperm.[64][65] Specialized semen assays, including sperm chromatin structure assays for DNA integrity or reactive oxygen species measurement (elevated in 40% of infertile samples), correlate with fertilization failure and embryo arrest, guiding prognosis in advanced cases.[64] These techniques, while resource-intensive, enable causal identification over empirical treatment, though their routine application remains debated due to cost-benefit ratios in low-yield scenarios.[62]Treatment Options
Medical and Surgical Interventions
Medical interventions for female infertility primarily target ovulation disorders, which account for approximately 25% of cases. Clomiphene citrate, an oral selective estrogen receptor modulator, induces ovulation by blocking estrogen receptors in the hypothalamus, leading to increased gonadotropin secretion; it has been used for over 40 years and achieves ovulation rates of 60-80% in anovulatory women without polycystic ovary syndrome (PCOS).[66] Letrozole, an aromatase inhibitor, suppresses estrogen production to promote follicular development and has demonstrated comparable live birth rates to clomiphene in women with PCOS, with ovulation rates exceeding 60% in randomized trials.[67] Injectable gonadotropins, such as follicle-stimulating hormone (FSH), are reserved for clomiphene-resistant cases and yield higher multiple pregnancy risks but superior ovulation induction in severe anovulation.[68] Surgical interventions for female infertility address structural issues like tubal blockages or endometriosis. Laparoscopic tubal anastomosis for sterilization reversal restores patency in suitable candidates, with pregnancy rates of 55-75% and live birth rates around 53% reported in retrospective series, influenced by tubal length and patient age under 35.[69] [70] For endometriosis-associated infertility, laparoscopic excision of endometriotic lesions improves spontaneous pregnancy rates by 10-25% compared to diagnostic laparoscopy alone, particularly in mild to moderate stages, though evidence is limited by small trials and potential selection bias.[71] Tubal surgery remains viable when fallopian tube patency is confirmed and IVF is not preferred, but success diminishes with advanced maternal age or severe adhesions.[72] In male infertility, pharmacological options focus on hypogonadotropic hypogonadism or idiopathic oligozoospermia, though evidence for broad efficacy is inconsistent. Clomiphene citrate off-label use elevates endogenous testosterone and improves sperm concentration and motility in meta-analyses of hypogonadal men, with pregnancy rates increasing by 10-20% in select cohorts, but routine application lacks strong support due to variable semen parameter improvements.[73] [74] Exogenous testosterone replacement therapy is contraindicated as it suppresses spermatogenesis via negative feedback on the hypothalamic-pituitary-gonadal axis, reducing sperm counts in up to 90% of users; alternatives like human chorionic gonadotropin (hCG) are preferred for fertility preservation.[75] Surgical treatments for male infertility emphasize varicocele correction, present in 15-20% of infertile men. Microsurgical varicocelectomy improves semen parameters in 60-80% of cases, with spontaneous pregnancy rates of 40-70% at 1-2 years post-procedure, outperforming embolization in recurrence rates (under 1%) and supported by meta-analyses showing odds ratios for conception up to 2.65.[76] [77] Vasectomy reversal via microsurgical vaso-vasostomy achieves patency rates of 90-95% and pregnancy rates of 50-70% within 2 years, declining with obstruction duration over 10 years due to antisperm antibody formation.[78] These interventions prioritize natural conception attempts before advancing to assisted technologies, with outcomes contingent on baseline semen quality and partner fertility.[79]Assisted Reproductive Technologies
Assisted reproductive technologies (ART) encompass medical procedures that handle human eggs, sperm, or embryos outside the body to achieve pregnancy, with in vitro fertilization (IVF) as the predominant method.[80] IVF involves ovarian stimulation to produce multiple eggs, transvaginal oocyte retrieval, laboratory fertilization of eggs with sperm, embryo culture for 3-5 days, and transfer of one or more embryos into the uterus.[80] Intracytoplasmic sperm injection (ICSI), a variant used in about 60% of U.S. IVF cycles, directly injects a single sperm into an egg to address severe male factor infertility or prior fertilization failure.[81] Less common procedures include gamete intrafallopian transfer (GIFT), where eggs and sperm are placed into the fallopian tube, and zygote intrafallopian transfer (ZIFT), involving transfer of a fertilized zygote to the tube, though these have declined due to the efficacy and simplicity of uterine embryo transfer in IVF.[82] Success rates for ART vary significantly by maternal age, underlying infertility causes, and cycle specifics like fresh versus frozen embryo transfer. In the United States, CDC data from 2021 indicate live birth rates per intended egg retrieval of approximately 54% for women under 35 using their own eggs in fresh cycles, dropping to 41% for ages 35-37, 25% for 38-40, and 7% for over 42.[83] For frozen embryo transfers, rates are often higher, reaching 50-60% in younger women due to improved embryo selection and endometrial preparation.[83] Overall, ART resulted in 95,860 live births in the U.S. in 2023, up from 91,771 in 2022, reflecting increased utilization amid rising infertility rates.[7] Preimplantation genetic testing (PGT) for aneuploidy enhances outcomes by selecting euploid embryos, reducing miscarriage rates, though it does not universally improve live birth rates across all patients.[84]| Maternal Age Group | Live Birth Rate per Retrieval (Own Eggs, Fresh Cycles, 2021 CDC Data) |
|---|---|
| <35 years | ~54% |
| 35-37 years | ~41% |
| 38-40 years | ~25% |
| >40 years | ~7% |
Emerging and Experimental Therapies
In vitro gametogenesis (IVG) represents a pioneering approach to address gamete shortages in infertility cases, involving the derivation of functional eggs or sperm from induced pluripotent stem cells (iPSCs) sourced from skin or blood. As of September 2025, researchers successfully generated human eggs containing genetic material from adult skin cells, marking a milestone toward clinical application for infertile individuals or same-sex couples, though full maturation and fertilization in humans remain preclinical.[90] IVG could bypass age-related oocyte decline by producing unlimited gametes, but ethical debates persist regarding safety, epigenetic risks, and potential for non-reproductive uses, with human trials not yet approved.[91] Stem cell therapies aim to rejuvenate ovarian tissue and restore folliculogenesis in conditions like premature ovarian insufficiency (POI). A July 2025 study demonstrated that mesenchymal stem cell injections activated dormant oocytes in 70% of women with ovarian failure, correlating with improved hormone levels and potential conception rates, though long-term efficacy and risks like tumorigenesis require further validation through ongoing trials.[92] Clinical trials, such as those evaluating stem cell-derived exosomes for gonadal failure, have enrolled participants since 2023, reporting preliminary safety but variable fertility restoration, with peak trial activity noted in 2018-2020 before stabilizing at 3-5 annually.[93][94] These interventions leverage stem cells' regenerative potential but face challenges in scalability and integration with existing IVF protocols. Mitochondrial replacement therapy (MRT), or "three-parent IVF," targets mitochondrial dysfunction contributing to age-related infertility and disease transmission by transferring nuclear DNA from a patient's oocyte to a donor oocyte with healthy mitochondria. In July 2025, the United Kingdom reported the birth of eight healthy babies via pronuclear transfer MRT, confirming embryo viability and absence of carryover mitochondrial DNA above 2%, though U.S. regulatory approval lags due to germline modification concerns.[95][96] MRT enhances oocyte quality without altering nuclear genetics but is limited to mitochondrial carriers and requires rigorous preimplantation testing. CRISPR/Cas9 gene editing holds promise for correcting monogenic causes of infertility, such as spermatogenesis defects in non-obstructive azoospermia. Preclinical models as of September 2025 show restoration of fertility via targeted edits in animal germ cells, but human applications remain experimental, confined to research on embryo editing for disease prevention rather than direct infertility resolution, amid debates over off-target effects and ethical germline alterations.[97] No infertility-specific human trials have advanced beyond proof-of-concept, prioritizing safety assessments.[98]Epidemiology and Demographic Trends
Global and Regional Prevalence
Approximately 17.5% of the global adult population—equating to roughly 1 in 6 people of reproductive age—experiences infertility over their lifetime, according to a 2023 World Health Organization (WHO) analysis of 133 population-based studies encompassing 2.6 million participants across 48 countries.[2] This lifetime prevalence reflects the proportion unable to achieve a clinical pregnancy after one year of regular unprotected intercourse or achieve a live birth via medically assisted reproduction, with rates derived from self-reported and clinically verified data. The WHO emphasizes that these figures underscore infertility as a significant public health issue, though measurement challenges persist due to varying definitions (e.g., primary vs. secondary infertility) and underreporting in regions with limited healthcare access.[1] Lifetime infertility prevalence shows minimal disparity by income level, at 17.8% in high-income countries and 16.5% in low- and middle-income countries, per the same WHO report, challenging assumptions of uniformly higher burdens in resource-poor settings.[2] However, 12-month prevalence rates—focusing on current inability to conceive—reveal contrasts: 3.5% to 16.7% in more developed nations, often tied to delayed childbearing and age-related ovarian reserve decline, versus 6.9% to 9.3% in less-developed regions, where infectious etiologies like untreated sexually transmitted infections contribute disproportionately.[99] In the United States, Centers for Disease Control and Prevention (CDC) data from 2015–2019 indicate that 13.4% of women aged 15–49 report impaired ability to get pregnant or carry to term, with 16.3% of married women in that age group exhibiting impaired fecundity.[100][101] Regionally, sub-Saharan Africa exhibits elevated secondary infertility (post-first birth), with rates up to 20–30% in some areas attributable to tubal blockages from pelvic inflammatory disease secondary to gonorrhea or chlamydia, as documented in demographic health surveys from countries like Uganda (prevalence 2% primary, 19% secondary across sampled nations).[102] In contrast, Europe and North America report 12-month infertility around 8–12%, predominantly primary and linked to endometriosis, male factor issues, or lifestyle factors, with national registries like those in the UK showing 1 in 7 couples seeking fertility treatment.[103] Asia displays variability, with lower reported rates in East Asia (e.g., 10–15% lifetime) influenced by cultural delays in family formation, while South Asia sees higher infectious burdens in rural areas. These differences arise from causal factors rather than inherent biology, with developing regions facing amplified rates from inadequate antenatal care and STIs, per a 2021 global burden analysis projecting sustained or rising trends without intervention.[104]| Income/Region Group | Lifetime Prevalence (%) | 12-Month Prevalence Range (%) | Primary Causes Noted |
|---|---|---|---|
| High-Income (e.g., Europe, North America) | 17.8 | 3.5–16.7 | Age, lifestyle, endometriosis[2][99] |
| Low/Middle-Income (Global Aggregate) | 16.5 | 6.9–9.3 | Infections, untreated STIs[2][99] |
| Sub-Saharan Africa | Not specified (elevated secondary) | Up to 19 (secondary) | Pelvic inflammatory disease[102] |