Exposure to Hazardous Substances and Male Reproductive Health: A Research Framework.The discovery in the mid-1970s that occupational exposures to pesticides could diminish or destroy the fertility of workers sparked concern about the effects of hazardous substances on male reproductive health. More recently, there is evidence that sperm quantity and quality may have declined worldwide, that the incidence of testicular cancer testicular cancer Malignant tumour of the testis, or testicle. Although relatively rare, testicular cancer is the most common malignancy for men between the ages of 20 and 34. It typically affects men between 15 and 39 years old. has progressively increased in many countries, and that other disorders of the male reproductive tract such as hypospadias hypospadias /hy·po·spa·di·as/ (-spa´de-is) a developmental anomaly in which the urethra opens inferior to its normal location; usually seen in males, with the opening on the underside of the penis or on the perineum. and cryptorchidism cryptorchidism /crypt·or·chid·ism/ (krip-tor´kid-izm) failure of one or both testes to descend into the scrotum.cryptor´chid Cryptorchidism may have also increased. There is growing concern that occupational factors and environmental chemical exposures, including in utero in utero (in u´ter-o) [L.] within the uterus. in u·ter·o adj. In the uterus. in utero adv. and childhood exposures to compounds with estrogenic activity, may be correlated with these observed changes in male reproductive health and fertility. We review the evidence and methodologies that have contributed to our current understanding of environmental effects on male reproductive health and fertility and discuss the methodologic issues which confront investigators in this area. One of the greatest challenges confronting researchers in this area is assessing and comparing results from existing studies. We elaborate recommendations for future research. Researchers in the field of male reproductive health should continue working to prioritize hazardous substances; elucidate the magnitude of male reproductive health effects, particularly in the areas of testicular cancer, hypospadias, and cryptorchidism; develop biomarkers of exposure to reproductive toxins and of reproductive health effects for research and clinical use; foster collaborative interdisciplinary research; and recognize the importance of standardized laboratory methods and sample archiving. Key words: hazardous substances, male reproductive health, research, semen quality semen quality Urology The measurable parameters of semen–eg, sperm concentration, total sperm count per ejaculate, % of motile sperm, number of abnormal and immature sperm . Environ Health Perspect 108:803-813 (2000). [Online 21 July 2000] http://ehpnet1.niehs.nih.gov/docs/2000/108p803-813moline/abstract.html Paternal exposure to solvents, pesticides, and metals has been associated in animals and humans with the occurrence of spontaneous abortion spon·ta·ne·ous abortion n. A naturally occurring termination of a pregnancy. Also called miscarriage. spontaneous abortion , low birth weight, birth defects birth defects, abnormalities in physical or mental structure or function that are present at birth. They range from minor to seriously deforming or life-threatening. A major defect of some type occurs in approximately 3% of all births. , childhood leukemia, brain cancer, change in the male:female sex ratio of offspring, and other end points related to growth and development. Certain paternal occupations--rubber worker, petroleum worker, agricultural chemical worker, painter, welder, and janitor--have been particularly implicated im·pli·cate tr.v. im·pli·cat·ed, im·pli·cat·ing, im·pli·cates 1. To involve or connect intimately or incriminatingly: evidence that implicates others in the plot. 2. as detrimental to the reproductive health of men (1). The reproductive hazards of occupational exposure have been recognized by the National Institute for Occupational Safety and Health National Institute for Occupational Safety and Health, n.pr an institute of the Centers for Disease Control and Prevention that is responsible for assuring safe and healthful working conditions and for developing standards of safety and health. (NIOSH NIOSH National Institute for Occupational Safety & Health, see there NIOSH Recommendations for Safety & Health Standards Agent NIOSH REL*/OSHA PEL† Health effects ) as a priority area in need of further study. The National Occupational Research Agenda, coordinated by NIOSH, was established in 1996 to outline the research priorities that can lead to improved worker safety and health in 21 key areas of occupational health (2). One of the 21 priority research areas is fertility and pregnancy abnormalities, which includes male reproductive health. However, exposure to environmental hazards is not limited to the workplace. Potential sources of exposure include food, air, water, soil, and hobbies. Individuals may have multiple exposures that in many cases occur chronically and at low doses. The reproductive health implications of chronic exposures to reproductive toxicants are not well documented and, in general, the mechanisms of toxicity are either poorly understood or unknown. Reports of declining sperm counts over the past 50 years and other disturbing trends alerted scientists to the possibility that exposure to chemicals in the environment may damage male reproductive health. Testicular cancer, the most common malignancy in men 15-44 years of age (3), has increased markedly in incidence in this century in virtually all countries studied. The incidence of hypospadias, a developmental malformation malformation /mal·for·ma·tion/ (-for-ma´shun) 1. a type of anomaly. 2. a morphologic defect of an organ or larger region of the body, resulting from an intrinsically abnormal developmental process. of the male urethra urethra (y  rē`thrə), canal in most mammals that carries urine from the bladder to the outside of the body; in the male it also serves as a genital duct. , appears to be increasing worldwide.
Cryptorchidism (undescended testicle un·de·scend·ed testiclen. An undescended testis. Undescended testicle A testicle that is still in the groin and has not made its way into the scrotum. ), another developmental defect, may have increased in some human populations and appears to be increasing in wildlife (4,5). The causes of these trends have not been identified and relevant toxicologic data about male reproductive effects of environmental toxicants are limited. Recent research efforts have focused on the possibility that exposures to hormonally active compounds, particularly during childhood and in utero, are to blame, at least in part, for changes in semen quality, increasing rates of testicular cancer, and malformations of the male urogenital urogenital /uro·gen·i·tal/ (-jen´i-tal) genitourinary. u·ro·gen·i·tal or u·ri·no·gen·i·tal adj. Genitourinary. tract. The ability to investigate environmental determinants of these indicators of male reproductive health is currently limited by available methodologies and data. Male reproductive health is not measurable by any one variable. The male reproductive system reproductive system, in animals, the anatomical organs concerned with production of offspring. In humans and other mammals the female reproductive system produces the female reproductive cells (the eggs, or ova) and contains an organ in which development of the fetus is complex; its development is hinged on precisely timed events and full reproductive capacity is dependent on disparate physiologic processes. For example, an accurate picture of male reproductive capacity and function cannot be obtained solely through the measurement of a single sperm count. It is more correctly characterized by a variety of biologic markers, which together provide a more comprehensive picture than any outcome would on its own (6). In considering the state of male reproductive health, researchers must look broadly at relevant outcomes in addition to fertility, including disturbances in neuroendocrine neuroendocrine /neu·ro·en·do·crine/ (-en´do-krin) pertaining to neural and endocrine influence, and particularly to the interaction between the nervous and endocrine systems. neu·ro·en·do·crine adj. hormone profiles, alterations in sexual functioning, the occurrence of cancers, and congenital defects of the male reproductive tract. As more information about the toxic effects of hazardous substances emerges, male reproductive health may expand to include additional as yet unidentified variables. Semen quality, in particular, should be considered in a more comprehensive manner. Research studies in the past have looked at sperm count (millions of sperm per milliliter milliliter /mil·li·li·ter/ (mL) (-le?ter) one thousandth (10-3) of a liter. mil·li·li·ter n. Abbr. of ejaculate ejaculate /ejac·u·late/ (e-jak´u-lat) to expel suddenly, especially semen. ejaculate /ejac·u·late/ (e-jak´u-lat ) as the single measure of male reproductive health. Although sperm count is an important measure, there is a need to examine semen quality as a whole. Semen quality includes ejaculate volume, sperm motility, sperm morphology, functional variables, and tests of genetic integrity or damage. An important and emerging understanding in this field is that semen quality varies within and between individuals. There are seasonal variations in semen quality, and male fertility decreases somewhat with age. Abstinence preceding collection of a semen specimen plays a role in semen quality, with days of abstinence correlated to sperm count, sperm motility, and ejaculate volume. Subjective evaluation of some relevant outcomes, such as sperm morphology, limits precise comparisons of sperm quality. As automated systems are developed for measuring such outcomes, straightforward, reliable, and truly comparable data will be generated. A comprehensive approach to exposure assessment is also important because men are exposed to complex combinations of potential reproductive toxicants and not simply to isolated hazards. Most exposures are multiple and overlapping. Moreover, chemicals might interact with the male reproductive system in different ways depending on other toxicants present in the body. Until methods to examine the effects of complex chemical mixtures are developed, research that examines one compound exclusively provides an incomplete picture of reproductive health effects. On 14-15 May 1998, the National Institute of Environmental Health Sciences/Superfund Basic Research Program and the Mount Sinai School of Medicine
Mount Sinai School of Medicine is a medical school found in the borough of Manhattan in New York City. convened a conference, Hazardous Substances and Male Reproductive Health, to develop strategies for understanding the importance of environmental effects on male reproductive health and fertility and to draft an international research agenda. Other sponsors of the conference were the U.S. Environmental Protection Agency Environmental Protection Agency (EPA), independent agency of the U.S. government, with headquarters in Washington, D.C. It was established in 1970 to reduce and control air and water pollution, noise pollution, and radiation and to ensure the safe handling and (U.S. EPA EPA eicosapentaenoic acid. EPA abbr. eicosapentaenoic acid EPA, n.pr See acid, eicosapentaenoic. EPA, n. ), the National Institute for Occupational Safety and Health, the Agency for Toxic Substances and Disease Registry The United States Agency for Toxic Substances and Disease Registry, (ATSDR) is an agency for the U.S. Department of Health and Human Services that is directed by a congressional mandate to perform specific functions concerning the effect on public health of hazardous , and the New York Academy of Medicine The New York Academy of Medicine was founded in 1847 by a group of leading New York City metropolitan area physicians as a voice for the medical profession in medical practice and public health reform. . The research findings and recommendations arising from the conference provided a foundation on which the following framework for research was developed. Ecoepidemiology: The Complementary Evidence of Reproductive Toxicity reproductive toxicity Any adverse effect attributable to exposure to a chemical, directed against the reproductive and/or related endocrine systems Adverse effects Altered sexual behavior, fertility, pregnancy outcomes, or modifications in other functions that in Wildlife Environmental pollutants environmental pollutants, n.pl the substances and conditions, including noise, that adversely affect the health and well-being of the people within a community. have been linked to adverse male reproductive effects in wildlife species in classes from invertebrates to mammals (7). Although such reproductive outcomes have been studied most intensively in amphibians amphibians members of the animal class Amphibia. Includes frogs, toads, newts, salamanders and cecilians all capable of living on land or in water. and reptiles, related male reproductive disorders occur in many species of wildlife. The causes of many of these disorders are unknown, but exposure to hormonally active agents in the environment is one possible explanation. The methods of ecoepidemiology address the challenges of evaluating the contributions of environmental pollutants to specific disease states in wildlife not living in controlled conditions (8). An ecoepidemiologic approach allows for the distinction between genetic causes (which may be enhanced by inbreeding inbreeding, mating of closely related organisms. Inbreeding is chiefly used as a means of insuring the preservation of specific desired traits among the offspring of purebred animals (see breeding). in isolated populations resulting from isolation of subpopulations) and environmental causes of disease. Such an approach must begin with field evaluation, move into the laboratory, and then look at compounds on a mechanistic level. The Lake Apopka alligator is one of the best-known wildlife species in which environmental xenoestrogens appear to have damaged the male reproductive system. The freshwater Lake Apopka in Florida is adjacent to the former Tower Chemical Company, which is now a Superfund site. From 1970 to 1980, a pesticide mixture containing high levels of DDT DDT or 2,2-bis(p-chlorophenyl)-1,1,1,-trichloroethane, chlorinated hydrocarbon compound used as an insecticide. First introduced during the 1940s, it killed insects that spread disease and feed on crops. and its metabolites Metabolites Substances produced by metabolism or by a metabolic process. Mentioned in: Interactions contaminated the area. Research comparing alligators from Lake Apopka to those in other Florida lakes found that Lake Apopka juvenile alligators have significantly smaller penis size as well as abnormalities in gonadal gonadal pertaining to or arising from a gonad. See also testicular, ovarian. gonadal cords cords formed by epithelial cells which migrate from the mesonephric tubules in the embryo to the gonadal ridge and establish the indifferent morphology and lower concentrations of plasma testosterone (9). Although the exact cause has not been determined, these alligators have significantly elevated serum concentrations of organochlorine or·gan·o·chlo·rine n. Any of various hydrocarbon pesticides, such as DDT, that contain chlorine. pesticides compared to alligators at other lakes in Florida. The Lake Apopka alligators also have the breakdown product of DDT (DDE (Dynamic Data Exchange) A message protocol in Windows that allows application programs to request and exchange data between them automatically. DDE - Dynamic Data Exchange ) stored in their body fat. Environmental xenoestrogens and antiandrogens such as these may contribute to abnormal or subnormal subnormal /sub·nor·mal/ (-nor´m'l) below normal. subnormal below or less than normal. reproductive system development, and appear to act on the males specifically during embryonic development (10,11). The Florida panther is another species in which environmental pollutants may be the cause of significant male reproductive effects (11). The endangered Florida panther suffers from inbreeding and vastly reduced habitat. The remaining population, estimated at only 30-50 individuals in 1995, exhibits a variety of problems, including reproductive and endocrine disorders (11). The males have an extremely high rate of cryptorchidism (estimated as 90% in 1995), as well as low ejaculate volume; low sperm concentration; poor sperm motility; and high proportion of sperm with morphologic abnormalities. Because of the small population size and the reduced habitat area, researchers have hypothesized that inbreeding may be the cause of the myriad health problems, but another possible explanation is exposure to environmental xenoestrogens. Florida panthers eat hogs, deer, armadillos, and raccoons. Raccoons are suspected to account for much of the exposure to environmental xenoestrogens. In that area raccoons, which eat fish, bioaccumulate mercury as well as endocrine-disrupting pesticides (12,13). Although the causes of the reproductive problems in the Florida panther have not been identified, estrogen mimics and antiandrogens in the environment are emerging as a strong possibility. This has significant implications for other wildlife species as well as for humans. Male reproductive problems in wildlife provide a complementary picture to human health effects. Such trends are helpful in evaluating environmental threats to human reproductive health, and have enabled researchers to focus on substances that, because of their effects on wildlife, are likely to pose reproductive health hazards in men. Evidence of Environmental Impact on Male Reproductive Health in Humans During the past decade, significant attention has focused on reported trends of declining male reproductive health. Almost all cancer registries in the Western world have noted remarkable increases in testicular cancer incidence (3). Several indications of decreasing semen quality have been noted (14-18). There are also data to suggest that the incidence of certain urogenital abnormalities, including hypospadias and cryptorchidism, have become more common (19). The fact that these reported changes in male reproductive health occurred concurrently within a relatively short period of time suggests that common environmental factors may be of importance. Normal sexual differentiation sexual differentiation See Hermaphroditism, hirsutism, Müllerian ducts, Precocious puberty, Pseudoprecocious puberty, Tanner staging, Testis-determining factor, Virilization, Wolffian ducts, XXX, XXY, XXXY, XYY syndromes, Y Chromosome. , normal development of the gonads The prenatal development of the gonads is a part of the development of reproductive system and sultimately forms the testes in males and ovaries in females. They initially develop from the mesothelial layer of the peritoneum. , and normal postnatal postnatal /post·na·tal/ (-na´t'l) occurring after birth, with reference to the newborn. post·na·tal adj. Of or occurring after birth, especially in the period immediately after birth. development are essential for normal reproductive function in adulthood; therefore, it has been suggested that a common fetal factor could play a role in all of the observed trends (19). Based on epidemiologic evidence from studies of children of mothers who were exposed to diethylstilbestrol diethylstilbestrol: see DES. in early pregnancy early pregnancy Obstetrics First trimester of pregnancy (20,21) and experimental evidence from the administration of synthetic estrogens Estrogens Hormones produced by the ovaries, the female sex glands. Mentioned in: Acne, Polycystic Ovary Syndrome estrogens (es´trōjenz), n. to pregnant animals (22-26), it is hypothesized that hormonally active agents, which are ubiquitously distributed in the environment, could play an etiologic role. Researchers from several countries, including Denmark, the United Kingdom, and the United States, have published reports that delineate the current state of knowledge and provide suggestions for further research to address these hypotheses (19). Testicular cancer. Testicular cancer is the most common malignancy among men 15-44 years of age, with a peak incidence between 18 and 35 years of age (27,28). Environmental influences are likely to play an important causal role in this disease, which has shown marked geographic variation (29). Testicular cancer incidence is highest in Denmark (30,31), Switzerland (32), and New Zealand New Zealand (zē`lənd), island country (2005 est. pop. 4,035,000), 104,454 sq mi (270,534 sq km), in the S Pacific Ocean, over 1,000 mi (1,600 km) SE of Australia. The capital is Wellington; the largest city and leading port is Auckland. (33), with incidence rates of up to 8 per 100,000 per year, and the evidence is overwhelming that testicular cancer incidence has increased rapidly in virtually all countries studied (3). The increases in incidence cannot be attributed to improvements in diagnosis or surveillance because the observed increases are too consistent and too large and because the principal means of diagnosis has been and remains the detection of a testicular testicular /tes·tic·u·lar/ (tes-tik´u-lar) pertaining to a testis. tes·tic·u·lar adj. Of or relating to a testicle or testis. testicular pertaining to the testis. mass on direct physical examination. In the United States, for example, the testicular cancer incidence rate among white active-duty servicemen 17-44 years of age increased by 61% from the 1970s to the 1990s (34). This increase in incidence was most striking for those 30-34 years of age, in whom testicular cancer rates doubled during a time in which there was no change in procedures for diagnostic detection. The rising incidence is particularly disturbing given the otherwise careful physical screening and good health of this young adult male population. Increases in the incidence of testicular cancer have not been uniformly reported among all men. The incidence of testicular cancer in Nigeria, for example, is 0.1 per 100,000 per year (35). African Americans in the United States also have had consistently low incidence over time. Between 1973 and 1996, for example, rates of testicular cancer increased 51.2% in white men and the rates for black men increased 17.3% (36). Although genetics almost certainly plays a major role in the etiology of the disease, other etiologies, including environmental factors, need to be elucidated to explain why, for example, major differences in testicular cancer rates exist among the relatively genetically homogenous homogenous - homogeneous Scandinavian countries. Increases in testicular cancer rates are not recent phenomena. A doubling in incidence was documented in Denmark within 25 years after the initiation of cancer registration in 1943 (3). Mortality data from Great Britain show an increase in mortality due to testicular cancer beginning in the 1920s (37). These mortality data raise an important distinction: if environmental risk factors play a role in testicular cancer incidence, relevant exposures must therefore have existed since the turn of the century. This would make it less likely that organochlorines organochlorines see chlorinated hydrocarbons. organochlorines poisoning cause excitement and irritability, tremor, ataxia, weakness, paralysis, convulsions. such as DDT and other endocrine-disrupting chemicals are possible etiologic agents. Because testicular cancer occurs in young adults, major etiologic factors may operate early in life, perhaps even in utero (3). Trends in testicular cancer suggest that lifetime exposure to environmental risk factors appears more strongly related to birth cohort than to year of diagnosis (3), implying that early exposures may be most relevant for the development of cancer. Such an observation has important implications for prevention. Efforts would have to be aimed toward women and men of childbearing age, pregnant women, and neonates. Possible etiologic agents for testicular cancer include abnormal sex hormone sex hormone n. Any of various steroid hormones, such as estrogen and androgen, affecting the growth or function of the reproductive organs and the development of secondary sex characteristics. exposure related to endocrine disruptors in the environment, maternal parity (38) and age (39), high or low birth weight (40), age at puberty (41), use of the pesticides atrazine atrazine a triazine herbicide; it is not poisonous at levels of intake likely to be encountered in agriculture. atrazine Toxicology A nonphytoestrogenic herbicide. See Phytoestrogen. (42) and N,N-diethyl-m-toluamide (43), and exposure to workplace hydrocarbon (44) and polyvinyl chloride polyvinyl chloride (PVC), thermoplastic that is a polymer of vinyl chloride. Resins of polyvinyl chloride are hard, but with the addition of plasticizers a flexible, elastic plastic can be made. (45). Testicular cancer disproportionately affects men with undescended testis undescended testis n. A testis that has remained in the abdomen or inguinal canal and not descended into the scrotum. Also called retained testis. undescended testis see cryptorchidism. (cryptorchidism), Klinefelter syndrome Klinefelter syndrome Chromosomal disorder that occurs in one out of 500 males. With an extra X chromosome in each cell (XXY), patients look male, with firm, small testes, but they produce no sperm and may have enlarged breasts and buttocks and very long legs. , hypospadias, and infertility. The risk of developing testicular cancer rises dramatically in men with disorders of sexual gonadal development (46). These include mixed gonadal dysgenesis Mixed gonadal dysgenesis is to a condition of unusual and asymmetrical gonadal development leading to an unassigned sex differentiation. A number of differences have been reported in the karyotype, most commonly a mosaicism 45,X/ 46, XY. , androgen insensitivity, and male pseudohermaphrodism (47). Nearly all of these conditions are also characterized by delayed differentiation of the testicle testicle /tes·ti·cle/ (tes´ti-k'l) testis. tes·ti·cle n. A testis, especially one contained within the scrotum. testicle testis. and infertility. Epidemiologic studies have reported the relative risk of testicular cancer in men with cryptorchidism as 3-14 times the normal expected incidence (39). In men with unilateral cryptorchidism, the contralateral contralateral /con·tra·lat·er·al/ (-lat´er-al) pertaining to, situated on, or affecting the opposite side. con·tra·lat·er·al adj. normally descended testicle is also at an increased risk of developing testicular cancer. Between 5 and 10% of men with unilateral cryptorchidism develop testicular cancer in the contralateral testicle and in nearly 50% of men with bilateral testicular cancer, a history of cryptorchidism is present. This observation is consistent with the hypothesis that the inciting events resulting in cryptorchidism have a negative impact on the normal development of both testes testes or testicles Male reproductive organs (see reproductive system). Humans have two oval-shaped testes 1.5–2 in. (4–5 cm) long that produce sperm and androgens (mainly testosterone), contained in a sac (scrotum) behind the penis. (47). Testicular cancer patients have much poorer semen quality than other cancer patients, and a recent epidemiologic study shows that men who have testicular cancer are subfertile even before they develop clinically detectable cancer (48). This suggests causal factors shared by both subfertility and testicular cancer (49). Research is ongoing to explore new genetic markers for early detection of carcinoma in situ carcinoma in situ n. A neoplasm whose cells are localized in the epithelium and show no tendency to invade or metastasize to other tissues. Carcinoma in situ cells in semen, as well as to define the role of hormonal assays (e.g., inhibin-B) as screening tools for testicular cancer and carcinoma in situ. Hypospadias and cryptorchidism. Two male genital birth defects, hypospadias and cryptorchidism, both apparently representing mild degrees of feminization feminization /fem·i·ni·za·tion/ (fem?i-ni-za´shun) 1. the normal development of primary and secondary sex characters in females. 2. the induction or development of female secondary sex characters in the male. , have become important in the ongoing debate regarding the significance of endocrine disruptors or other environmental influences on male development (50). Several researchers have reported increases in each of these defects in the past three decades (4,51). To evaluate the hypothesis of common etiologies, pre- and perinatal determinants of hypospadias, cryptorchidism, testicular cancer, and infertility are under investigation. Abnormal sex hormone exposure during critical periods of development has been postulated as a likely shared pathologic mechanism (19). Hypospadias is a developmental malformation in which the urethra opens on the underside of the penis or on the perineum perineum /peri·ne·um/ (-ne´um) 1. the pelvic floor and associated structures occupying the pelvic outlet, bounded anteriorly by the pubic symphysis, laterally by the ischial tuberosities, and posteriorly by the coccyx. . If untreated, hypospadias can lead to urinary stricture stricture /stric·ture/ (strik´chur) stenosis. stric·ture n. A circumscribed narrowing of a hollow structure. , infection, and difficulties with ejaculation ejaculation /ejac·u·la·tion/ (e-jak?u-la´shun) forcible, sudden expulsion; especially expulsion of semen from the male urethra. . Reports of increasing rates of hypospadias during the 1960s, 1970s, and 1980s have raised concerns about the dependability of surveillance systems, especially regarding inconsistencies in diagnosis due to a classification scheme that depends on the distance of the urethra opening to the tip of the penis. Hypospadias, particularly in the mildest degree, may be incorrectly classified by clinicians. Despite the difficulties of using surveillance system data, however, it appears that rates of hypospadias are increasing worldwide. The increasing rates do not solely reflect improvements in reporting and diagnosis, because there are increases for severe hypospadias as well as for mild cases. Data from a large number of countries address the questions of whether increases in hypospadias are continuing and whether the direction of trend lines is correlated with increasing industrialization industrialization Process of converting to a socioeconomic order in which industry is dominant. The changes that took place in Britain during the Industrial Revolution of the late 18th and 19th century led the way for the early industrializing nations of western Europe and . The International Clearinghouse of Birth Defects Monitoring Systems (Rome, Italy), which collects data from 29 countries on five continents, has assembled data that form the basis of an analysis of global trends in hypospadias. The incidence of hypospadias does not appear to be associated with industrialization (as measured by gross domestic product), although there has been an increase in reported hypospadias rates in recent decades in the majority of international surveillance systems. Hypospadias rates increased in 18 of 29 systems (62%) and declined in 11 systems, although the increases may have slowed or stopped since 1985. Whereas improved reporting and diagnosis cannot account for the increases, possible causes of the upward trend in hypospadias rates include demographic changes and endocrine disruption, among others (52). Cryptorchidism, another male developmental defect, is characterized by the failure of one or both testicles Testicles Also called testes or gonads, they are part of the male reproductive system, and are located beneath the penis in the scrotum. Mentioned in: Testicular Cancer, Testicular Surgery, Vasectomy to descend into the scrotum scrotum: see testis. . Cryptorchidism is a well-established risk factor for subfertility and testicular cancer, strongly suggesting a common etiology affecting germ cell germ cell n. An ovum or a sperm cell or one of their developmental precursors. Also called sex cell. Germ cell One of the cells that ordinarily develop into eggs or sperm (also sperm and eggs). development. Because the defect resolves spontaneously by the first birthday in [is greater than] 70% of affected infants, there are inconsistencies in its diagnosis. If the condition is diagnosed before the first birthday, or if gestational age ges·ta·tion·al age n. See estimated gestational age. Gestational age The estimated age of a fetus expressed in weeks, calculated from the first day of the last normal menstrual period. is miscalculated in premature babies, there may be an overestimation of the incidence rate. Although the incidence of cryptorchidism does not appear to be increasing worldwide in humans, data on this defect are limited, and two U.S. surveillance systems have shown marked increases (52). The defect does appear to be rising in wildlife populations such as the Florida panther (11), and demasculinization and feminization have been linked in other wildlife populations to environmental exposure to endocrine disruptors (7). Semen quality. Reports suggesting that sperm counts have declined in certain areas of industrialized in·dus·tri·al·ize v. in·dus·tri·al·ized, in·dus·tri·al·iz·ing, in·dus·tri·al·iz·es v.tr. 1. To develop industry in (a country or society, for example). 2. countries throughout the world (14,16-18,53-56) have contributed to concern about a possible worldwide decline in human semen quality. A meta-analysis by Carlsen et al. (14) in 1992 reported a worldwide decline in sperm counts over the preceding 50 years, concluding that mean sperm concentrations had decreased by almost 50% from 1940 to 1990. A 1995 study reported a 30% decrease in sperm concentration in Paris over a 20-year period among fertile sperm donors from a single sperm bank sperm bank Reproduction medicine A registered tissue bank that collects, stores, tests, and sells frozen sperm to be used for artificial insemination. See Artificial insemination. (53). Numerous researchers have attempted to determine whether this apparent decline is real or due to unrecognized biases in data collection and analysis (18,57). Confounding variables may account for the observed findings. Potential confounders include increasing donor age, duration of abstinence, frequency of ejaculation, and even the season of sample collection, all of which influence sperm variables. Other suggested confounders include smoking, radiation exposure, stress, ethnicity, and a variety of physical conditions including varicocele varicocele /var·i·co·cele/ (var´i-ko-sel) 1. varicosity of the pampiniform plexus of the spermatic cord, forming a scrotal swelling that feels like a “bag of worms.” 2. , infection, and genital abnormalities such as hypospadias and cryptorchidism. In addition, differences in methodology used to perform the semen analysis Semen Analysis Definition Semen analysis evaluates a man's sperm and semen. It is done to discover cause for infertility and to confirm success of vasectomy. may produce inaccuracies. For example, there is interobserver variability when comparing sperm counts from different databanks, and there are measurement inaccuracies of up to 30% depending on the counting chamber counting chamber n. A standardized glass slide used for counting cells, especially red blood cells and white blood cells, and other particulate material in a measured volume of fluid; a hemocytometer. (58). In a 1996 paper, Fisch et al. (58) examined geographic variability as a potential confounding variable that may significantly affect reported temporal trends in sperm counts. The authors observed that sperm count within the United States depended on geographic location, with the highest counts occurring in New York City New York City: see New York, city. New York City City (pop., 2000: 8,008,278), southeastern New York, at the mouth of the Hudson River. The largest city in the U.S. samples, and suggested that the observed differences in semen quality may simply reflect the clustering of significant geographic determinants. Theories explaining the apparent geographic disparities in sperm counts are currently only speculative, and include environmental, socioeconomic, racial, and methodologic differences (18,59). Fisch et al. (58) reported yearly fluctuations in mean sperm counts and birth rates (60), suggesting that this may be a more important variable than previously considered. Methods of Assessing Male Reproductive Capacity Toxicants can affect the male reproductive system at one of several sites or at multiple sites. These sites include the testes, the accessory sex glands, and the central nervous system, including the neuroendocrine system. There is no single all-encompassing marker of reproductive capacity in men, and there is no consensus among researchers about what constitutes an appropriate battery of validated and interpretable variables of male reproductive function for use in research and clinical settings. We review the state of the science and the methodologies with greatest promise from three areas--experimental toxicology, epidemiology, and chromosomal or genetic toxicity. The contribution of experimental models. The usefulness of experimental animal models is usually perceived as limited to hazard identification using the test protocols specified by regulatory agencies. However, animal models can also provide valuable support to reproductive risk assessment on many other fronts. If the focus is on human exposure, animal studies can be designed to confirm reproductive toxicity when initial observations in exposed humans are suggestive of suggestive of Decision making adjective Referring to a pattern by LM or imaging, that the interpreter associates with a particular–usually malignant lesion. See Aunt Millie approach, Defensive medicine. an adverse effect. Furthermore, such observations can be extended across a wide range of exposures in animals, using any route of exposure and any specified dose versus time scenario. For example, when human exposure is likely to be acute or intermittent, animal models are ideal for defining critical exposure windows based on developmental stage or for revealing the pathogenesis of an effect at various times after exposure through recovery. This is particularly important with respect to male reproductive effects because alterations in semen quality or fertility may not become evident until some time after the exposure, particularly if an early stage of spermatogenesis is targeted. A rodent model is most commonly used for the study of reproductive and developmental toxicity (61). To use toxicology data derived from animal studies to advantage in risk assessment, it is critical to identify and understand species-specific differences in physiology and metabolism that may affect the response to the toxicant toxicant /tox·i·cant/ (tok´si-kant) 1. poisonous. 2. poison. tox·i·cant n. 1. A poison or poisonous agent. 2. An intoxicant. adj. in question. It is also important to recognize that the genetic homogeneity of rodents, although advantageous in its lack of potential confounding factors, makes it difficult to study susceptible subpopulations unless different strains are studied. Nevertheless, rodent studies provide valuable information about hazard identification, dose response, and critical thresholds for fertility, and are often helpful for developing paradigms for human studies. Rodent models have, for example, been used to determine the relationship between sperm end points and function (fertility) (62). Determining that a substance is toxic to the male reproductive system is only the first step: The next step is to examine its mechanisms of toxicity. Mechanistic information allows for predictions about the potential toxicity of individual compounds or complex mixtures in humans, for better understanding of the windows of vulnerability in the development of the male reproductive system, and for developments of possible preventive or curative measures. Acute short-term exposure models combined with serial exposure models give a complete picture of the range of effects (61). Exposing animals over a long period of time allows for the detection of transgenerational effects from chemicals, such as male-mediated developmental effects. If developmental effects appear, researchers can go back and administer a dose during that critical period of development to refine knowledge about how such problems occur. Early developmental end points measurable in animal research include anogenital a·no·gen·i·tal adj. Relating to the anus and the genitals. anogenital relating to the region of the anus and the genitalia, especially the external genitalia. distance at birth, testis testis (tĕs`tĭs) or testicle (tĕs`tĭkəl), one of a pair of glands that produce the male reproductive cells, or sperm. position, genital malformations, secondary sex characteristics, and serum hormone levels. Acute short-term exposures, on the other hand, can be useful for identifying critical windows of exposure. Acute exposures followed over time can help identify the pathogenesis of a lesion, isolate the cell type that is susceptible to damage (germ cells, spermatocytes, or spermatid spermatid /sper·ma·tid/ (sper´mah-tid) a cell derived from a secondary spermatocyte by fission, and developing into a spermatozoon. sper·ma·tid n. ), and determine genetic effects, including the repair capability of affected genes. Serial sacrifice studies are best used for identifying the earliest detectable pathologic changes in target organs, cells, or processes. Multigeneration studies, in particular continuous breeding studies, yield the most thorough assessment of the many complex processes that result in reproductive and developmental toxicity. Epidemiologic approaches. Epidemiologic methods for assessing the impact of hazardous substances on male reproductive health include a) questionnaires to determine reproductive history reproductive history Obstetrics A set of 4 numbers that may be used to define a woman's obstetric Hx–eg, 4-3-2-1, would mean 4 term infants delivered, 3 preterm infants, 2 abortions, 1 child currently living and sexual function, b) reproductive hormone profiles, and c) semen analysis. The choice of appropriate methodologies to study the effects of reproductive toxicants is predicated on the investigators' understanding of several factors: the nature of the exposed population; the source, the levels, and the known routes of exposure; the organ systems in which a toxicant exerts its actions; the hypothesized mechanisms of a toxicant's actions; and the techniques available to assess the effects of toxicants in the relevant organ systems (63,64). Table 1 outlines the methods currently available for assessing the principal targets of male reproductive toxicants in humans--the testes, the accessory sex glands, the neuroendocrine system, and sexual function. Researchers and clinicians interested in male reproductive health and fertility are using increasingly sophisticated methods adapted from the fields of assisted reproductive technology Assisted reproductive technology (ART) is a general term referring to methods used to achieve pregnancy by artificial or partially artificial means. It is reproductive technology used in infertility treatment, which is the only application routinely used today of and reproductive toxicology, including assays of sperm function, genetic integrity, and biomarkers of DNA DNA: see nucleic acid. DNA or deoxyribonucleic acid One of two types of nucleic acid (the other is RNA); a complex organic compound found in all living cells and many viruses. It is the chemical substance of genes. damage. For population-based studies involving occupational groups or communities with environmental exposures, issues related to the cost, validity, precision, and utility of these methods must be carefully considered.
Table 1. Assessment of male reproductive capacity in humans.
Endocrine
Method of assessment system Testes
Luteinizing hormone [check] --
Prolactin [check] --
Testosterone [check] --
Inhibin-B [check] --
Sperm density -- [check]
Sperm morphology and morphometry -- [check]
Sperm motility (% motile and velocity) -- [check]
Sperm viability (vital stain and HOS) -- --
Semen volume -- --
Semen pH -- --
Marker chemicals from accessory glands -- --
Sperm function assays(b) -- [check]
Sperm genetic analyses(c) -- [check]
Nocturnal penile measurements -- --
Personal reproductive history(d) [check] [check]
Posttesticular Sexual
Method of assessment events(a) function
Luteinizing hormone -- --
Prolactin -- --
Testosterone -- --
Inhibin-B -- --
Sperm density -- --
Sperm morphology and morphometry [check] --
Sperm motility (% motile and velocity) [check] --
Sperm viability (vital stain and HOS) [check] --
Semen volume [check] --
Semen pH [check] --
Marker chemicals from accessory glands [check] --
Sperm function assays(b) [check] --
Sperm genetic analyses(c) [check] --
Nocturnal penile measurements -- [check]
Personal reproductive history(d) -- [check]
Adapted from Schrader (67)and Schrader and Kesner (86). HOS, hyperosmotic swelling. (a) Includes production of seminal plasma components by sex accessory glands and maturation of sperm in the epididymis epididymis /ep·i·did·y·mis/ (-did´i-mis) pl. epididy´mides [Gr.] an elongated cordlike structure along the posterior border of the testis; its coiled duct provides for storage, transit, and maturation of spermatozoa and is . (b) Includes acrosome reaction, hemizona assay of sperm binding, and sperm penetration assays. (c) Includes sperm chromatin chromatin: see chromosome. stability assay, Comet assay, and assessment of chromosomal aneuploidy aneuploidy /an·eu·ploi·dy/ (an?u-ploi´de) any deviation from an exact multiple of the haploid number of chromosomes, whether fewer or more. an·eu·ploi·dy n. and nuclear microdeletions. (d) Includes pubertal development, paternity (pregnancy timing and outcomes), sexual function (erection, ejaculation, orgasm, and libido). The testis, the site of sperm cell production and the target organ for genetic damage, is most often studied. Occupational exposures to lead, dibromochloropropane, ethylene dibromide di·bro·mide n. A chemical compound containing two bromine atoms bound to another element or radical. , and glycol ethers affect sperm production in humans (1,65-68). To establish the extent of toxicity to the testis, researchers can measure the size of the testis, obtain a semen sample, or take a testicular biopsy. Standard semen analyses (including semen volume, sperm concentration, total sperm count, motility motility /mo·til·i·ty/ (mo-til´ite) the ability to move spontaneously.mo´tile Motility Motility is spontaneous movement. , and morphology) have been the primary research tools for studying the effects of toxicants on the male reproductive system. Epidemiologic studies have successfully utilized semen quality as a marker of fertility (60,69) although not without problems (70-74) (e.g., potential selection bias due to low compliance rates and substantial intraindividual variability in semen variables resulting in misclassification based on the static results of a single analysis). In contrast to longitudinal studies longitudinal studies, n.pl the epidemiologic studies that record data from a respresentative sample at repeated intervals over an extended span of time rather than at a single or limited number over a short period. as well as clinical evaluations where more than one semen sample is required (75), research has shown that in cross-sectional epidemiologic investigations, a single semen sample from each participant generally is sufficient if obtained under defined conditions and according to a set protocol (72,73,76). Methodologic questions regarding intraindividual variation and the precision and reliability of assessment techniques can be addressed to some extent. Individual semen samples can be split and replicate measurements made. The mean value from multiple aliquots can be used and intraclass correlation and coefficients of variation can be determined. Individualized contact and follow up with the study subjects, the provision of financial incentives, and the use of mail-in containers that allow men to collect the semen sample at home are factors that may increase response rates in epidemiologic studies (77). As much as any other factor, uncertainty in the results of studies addressing threats to male reproductive health stems from debate about the definition of normal semen quality and whether or not expected fluctuations are distinguishable from diminished reproductive capacity resulting from hazardous exposures (72,73,78,79), In epidemiology studies conducted to investigate effects of an accidental exposure, it may be difficult to enroll an appropriate unexposed control group. In such cases, results obtained from exposed populations can be interpreted with respect to the reference values ref·er·ence values pl.n. A set of laboratory test values obtained from an individual or from a group in a defined state of health. established for routine semen measures by the World Health Organization methods (80) and other well established criteria (81). It has proved more difficult, however, to resolve questions about the validity of using semen measures to assess human fertility (59,69,82). Which semen variables are the most sensitive with respect to perturbation perturbation (pŭr'tərbā`shən), in astronomy and physics, small force or other influence that modifies the otherwise simple motion of some object. The term is also used for the effect produced by the perturbation, e.g. by toxicant exposure, and which are the most predictive of human fertility? Can threshold levels associated with impaired fertility be defined? Are shifts in sperm quantity and quality within populations related to measurable decreases in normal live births? Some relevant information about these questions has been provided by animal models (62). However, because these models rely on observations of the group as a whole, they have not been as useful in elucidating intraindividual variability, which impedes our ability to apply results from these models to humans. The uncertainties associated with traditional semen measures have led to the recent development of assays of sperm function and genetic integrity; these assays may prove more sensitive and more specific reflections of toxicant-induced effects (e.g., aneuploidy or reduced sperm motility) in individuals (76,83). Although any of the commonly used epidemiologic study designs can be used to study male reproductive health (e.g., case-control studies of occupational risk factors for congenital defects or other adverse pregnancy outcomes and retrospective cohort studies for cancers of the genitourinary genitourinary /gen·i·to·uri·nary/ (jen?i-to-u´ri-nar-e) pertaining to the genital and urinary organs. gen·i·to·u·ri·nar·y adj. Abbr. tract), the most promising current and future initiatives use prospective cohort studies that are designed to test specific exposure-outcome hypotheses (84). Currently, several ongoing studies are addressing relationships among measures of semen quality, fertility, pregnancy outcomes, and exposures. These investigations have been designed to take into account potential confounders such as geographic variability; factors related to the female partner including abnormal menstrual cycle menstrual cycle n. The recurring cycle of physiological changes in the uterus, ovaries, and other sexual structures that occur from the beginning of one menstrual period through the beginning of the next. , previous treatment for infertility, and parity; contraception status; and abstinence interval (85). The accessory sex glands, which include the epididymis, prostate, and seminal vesicle seminal vesicle n. Either of a pair of pouchlike glands situated on each side of the male urinary bladder that secrete seminal fluid and nourish and promote the movement of spermatozoa through the urethra. , may also be targets of toxicants (67). Ethylene dibromide is one substance that affects the accessory sex glands after occupational exposure (68). Alterations in sperm viability, as measured by eosin eosin /eo·sin/ (e´o-sin) any of a class of rose-colored stains or dyes, all being bromine derivatives of fluorescein; eosin Y, the sodium salt of tetrabromofluorescein, is much used in histologic and laboratory procedures. stain exclusion or by hypoosmotic swelling (86) or alterations in sperm motility variables (72), suggest a problem with the accessory sex glands. Biochemical analysis of seminal plasma provides insights into glandular glandular /glan·du·lar/ (glan´du-ler) 1. pertaining to or of the nature of a gland. 2. glanular. glan·du·lar adj. 1. function by evaluating marker chemicals secreted by each respective gland (67). For example, the epididymis is represented by glycerylphosphorylcholine, the seminal vesicles by fructose fructose (frŭk`tōs), levulose (lĕv`yəlōs'), or fruit sugar, simple sugar found in honey and in the fruit and other parts of plants. , and the prostate gland by zinc. Measures of semen pH and volume provide additional general information on the nature of seminal plasma, reflecting posttesticular effects. A toxicant or its metabolite metabolite, organic compound that is a starting material in, an intermediate in, or an end product of metabolism. Starting materials are substances, usually small and of simple structure, absorbed by the organism as food. may act directly on accessory sex glands to alter the quantity or quality of their secretions. Alternatively, the toxicant may enter the seminal plasma and affect the sperm or may be carried to the site of fertilization by the sperm and affect the ova ova (o´vah) plural of ovum. Ova Eggs. Mentioned in: Stool O & P Test ova plural of ovum. or conceptus conceptus /con·cep·tus/ (-tus) the product of the union of oocyte and spermatozoon at any stage of development from fertilization until birth, including extraembryonic membranes as well as the embryo or fetus. . The presence of toxicants or their metabolites in seminal plasma can be analyzed using atomic absorption spectrophotometry spectrophotometry Branch of spectroscopy dealing with measurement of radiant energy transmitted or reflected by a body as a function of wavelength. The measurement is usually compared to that transmitted or reflected by a system that serves as a standard. or gas chromotography/mass spectrometry. Impact on the neuroendocrine system is another mechanism whereby toxicants can disturb the male reproductive system. Lead, stilbene stil·bene n. A colorless or yellowish unsaturated crystalline hydrocarbon compound that is the chemical basis for diethylstilbestrol and other synthetic estrogenic compounds. , and kepone affect the endocrine system endocrine system (ĕn`dəkrĭn), body control system composed of a group of glands that maintain a stable internal environment by producing chemical regulatory substances called hormones. in occupationally exposed men (87). To establish the extent of endocrine dysfunction, hormone levels can be measured in blood and urine. The profile recommended by NIOSH to evaluate endocrine dysfunction associated with reproductive toxicity consists of assessing serum concentrations of follicle-stimulating hormone follicle-stimulating hormone (FSH): see gonadotropic hormone. (FSH FSH follicle-stimulating hormone. FSH abbr. follicle-stimulating hormone Facioscapulohumeral muscular dystrophy (FSH) ), luteinizing hormone lu·te·in·iz·ing hormone n. Abbr. LH A hormone produced by the anterior lobe of the pituitary gland that stimulates ovulation and the development of the corpus luteum in the female and the production of testosterone by the interstitial (LH), testosterone, and prolactin prolactin /pro·lac·tin/ (-lak´tin) a hormone of the anterior pituitary that stimulates and sustains lactation in postpartum mammals, and shows luteotropic activity in certain mammals. pro·lac·tin n. (67). Because of the pulsatile pulsatile /pul·sa·tile/ (pul´sah-til) characterized by a rhythmic pulsation. pul·sa·tile adj. Undergoing pulsation. pulsatile characterized by a rhythmic pulsation. secretion of LH, testosterone, and to a much lesser extent FSH, and the variability in the evaluation of reproductive hormones, it is recommended that three blood samples be drawn at set intervals in the early morning and the results pooled or averaged for clinical assessment (88,89). In epidemiologic field studies, however, multiple blood samples are impractical and may decrease participation rates (90). Alternatively, LH and FSH can be measured in urine, providing indices of gonadotropin gonadotropin /go·nado·tro·pin/ (-tro´pin) any hormone that stimulates the gonads, especially follicle-stimulating hormone and luteinizing hormone. levels that are relatively unaffected by pulsatile secretion. However, if an exposure can affect hepatic metabolism hepatic metabolism Therapeutics The constellation of chemical alterations to drugs or metabolites that occur in the liver, carried out by microsomal enzyme systems, which catalyze glucuronide conjugation, drug oxidation, reduction and hydrolysis. See Metabolism. of sex steroid hormones (91), urinary measures of excreted testosterone metabolite (androsterone androsterone /an·dros·ter·one/ (an-dros´ter-on) an androgen degradation product that in some species exerts weak androgenlike effects. an·dros·ter·one n. ) or estradiol metabolite (estrone-3-glucuronide) are not recommended. Future assessment of reproductive hormones may extend to inhibin in·hib·in n. A peptide hormone secreted by the follicular cells of the ovary and the Sertoli cells of the testis that inhibits secretion of follicle stimulating hormone from the anterior pituitary. , activin activin /ac·ti·vin/ (ak´ti-vin) a nonsteroidal regulator synthesized in the pituitary glands and gonads that stimulates the secretion of follicle-stimulating hormone. ac·ti·vin n. , and follistatin, polypeptides that are secreted primarily by the gonads and that act on the pituitary pituitary /pi·tu·i·tary/ (pi-too´i-tar?e) 1. hypophysial. 2. pituitary gland; see under gland. anterior pituitary adenohypophysis. to increase (activin) or decrease (inhibin and follistatin) FSH synthesis and secretion. Within the gonads, these peptides regulate steroid hormone steroid hormone n. See steroid. synthesis and may also directly affect spermatogenesis. Ongoing studies are investigating the utility of serum inhibin-B level as an important marker of Sertoli cell Ser·to·li cell n. Any of the elongated striated cells in the seminiferous tubules to which spermatids attach during spermiogenesis. Sertoli cell function and in utero developmental toxicity (92,93). Other indicators of central nervous system toxicity are reported alterations in sexual function, including libido, erection, and ejaculation. There is not much literature on occupational exposures causing sexual dysfunction sexual dysfunction Inability to experience arousal or achieve sexual satisfaction under ordinary circumstances, as a result of psychological or physiological problems. in men (67); however, there are suggestions that lead, carbon disulfide carbon disulfide, CS2, liquid organic compound; it is colorless, foul-smelling, flammable, and poisonous. It can be prepared by direct reaction of carbon, e.g., as charcoal, with sulfur. It is a widely used solvent, e.g. , stilbene, and cadmium can affect sexual function. These outcomes are difficult to measure because of the absence of objective measures and because sexual dysfunction can be attributed to and affected by psychologic or physiologic factors (67). Biomarkers of genetic damage. Biomarkers of chromosomal and genetic damage are increasingly used in the search to understand abnormal reproductive health outcomes, in part because of the possibility that there may be identifiable genetic polymorphisms which make an individual more susceptible to the adverse reproductive effects from exogenous substances. These assays provide promising and sensitive approaches for investigating germinal Germinal conflict of capital vs. labor: miners strike en masse. [Fr. Lit.: Germinal] See : Riot Germinal portrays the sufferings of workers in the French mines. [Fr. Lit. and potentially heritable her·i·ta·ble adj. 1. Capable of being passed from one generation to the next; hereditary. 2. Capable of inheriting or taking by inheritance. effects of exposures to agents and for confirming epidemiologic observations on smaller numbers of individuals. Efficient technology for examining chromosomal abnormalities in sperm has only been developed recently. Chromosomal abnormalities are primarily of two types: numerical and structural. Both kinds can be attributed in some cases to paternal factors. Karyotype studies have shown that although oocytes demonstrate a higher frequency of numerical chromosomal abnormalities, human sperm demonstrate a higher frequency of structural abnormalities with less frequent numerical abnormalities (94). In assessing sperm exposure to toxicants, it is therefore imperative to assess DNA structural integrity and not just chromosomal count. Aneuploidy is a chromosomal abnormality that causes pregnancy loss, perinatal death, congenital defects, and mental retardation mental retardation, below average level of intellectual functioning, usually defined by an IQ of below 70 to 75, combined with limitations in the skills necessary for daily living. . Aneuploidy, a disorder of chromosome count, is observed in approximately 1 in 300 newborns (95). It is speculated that of all species, humans experience the highest frequency of aneuploidy at conception, with estimates ranging from 20 to 50% (95). Spontaneous abortions occur in at least 10-15% of all clinically recognized pregnancies. Of these, 35% contain chromosomal aneuploidy. Despite such a high frequency, there is little information about what causes this abnormality in humans. Paternal origins of aneuploidy and other genetic abnormalities can be analyzed by studying chromosome complements in human sperm. Two types of analyses provide data on chromosomal abnormalities in human sperm: sperm karyotype analysis and fluorescence in situ hybridization Fluorescence in situ hybridization (FISH) A technique for diagnosing DiGeorge syndrome before birth by analyzing cells obtained by amniocentesis with DNA probes. FISH is about 95% accurate. (FISH) (94). Each technique has advantages and disadvantages. Sperm karyotyping Karyotyping A laboratory test used to study an individual's chromosome make-up. Chromosomes are separated from cells, stained, and arranged in order from largest to smallest so that their number and structure can be studied under a microscope. is performed after sperm have fused with hamster oocytes. It provides precise information on numerical and gross structural abnormalities of all chromosomes from a given spermatozoon spermatozoon: see sperm. . However, only a limited number of sperm can be evaluated in each assay, and only those sperm that fertilize the oocytes are analyzable. Furthermore, this assay is technically difficult, labor intensive Labor Intensive A process or industry that requires large amounts of human effort to produce goods. Notes: A good example is the hospitality industry (hotels, restaurants, etc), they are considered to be very people-oriented. See also: Capital Intensive, Trading Dollars , expensive, and requires the use of animals (96). Also, it is better suited for clinical than for field studies because it must be performed on fresh semen. FISH, on the other hand, relies on the use of chromosome-specific probes to detect extra chromosomes (aneuploidy) or chromosome breaks or rearrangements in sperm. It is performed directly on sperm cells, eliminating the need for the use of animals. Although information is gained only for several chromosomes at a time, slides can be reprobed to increase the number of chromosomes evaluated. Furthermore, FISH can be conducted on archived sperm (either frozen or dried on slides), making it ideal for use in field studies. However, because the incidence of sperm aneuploidy is low, many cells (up to 10,000 per semen sample) must be evaluated, which requires significant scoring times. In comparison to karyotype analysis, however, FISH is relatively inexpensive and technically simpler, and data are obtained on all sperm, not just the ones that are capable of fertilization. These two techniques complement each other, with FISH providing information on large numbers of cells and karyotyping providing more precise and detailed information (94,97-99). Several risk factors have been identified for increasing sperm chromosomal abnormalities. A sperm karyotype study of radiotherapy patients before and after treatment demonstrated a significant increase in the frequency of both numerical and structural chromosomal abnormalities up to 3 years after treatment (83). Assessing aneuploidy rates using FISH in men who received chemotherapy has yielded varying results based on agent, dose, timing of specimen collection, and type of cancer studied. Male infertility is also associated with an increased frequency of chromosomally abnormal sperm karyotypes (94). These findings are of concern because infertile in·fer·tile adj. Not capable of initiating, sustaining, or supporting reproduction. infertile, adj unable to produce offspring. men may be candidates for intracytoplasmic sperm injection Intracytoplasmic sperm injection (ICSI) is an in vitro fertilization procedure in which a single sperm is injected directly into an egg; this procedure is most commonly used to overcome male infertility problems. (ICSI ICSI - International Computer Science Institute at Berkeley, CA. ), and therefore may be at increased risk of having children with chromosomal abnormalities. Paternal age is another risk factor (96). Although increasing maternal age maternal age, n the age of the mother at the period of conception. is irrefutably associated with an increased risk of nondisjunction nondisjunction /non·dis·junc·tion/ (-dis-junk´shun) failure either of two homologous chromosomes to pass to separate cells during the first meiotic division, or of the two chromatids of a chromosome to pass to separate cells during in the oocyte oocyte /oo·cyte/ (-sit) the immature female reproductive cell prior to fertilization; derived from an oogonium. It is a primary o. prior to completion of the first maturation division, and a secondary o. , the relationship between paternal age and the frequency of nondisjunction has not been clearly elucidated. The father's influence on the fetus, however, may begin long before conception. Fetal development may be affected if the male has been exposed to lifestyle and/or occupational hazards. For example, recent studies show that smoking and/or alcohol consumption are associated with an increased risk of sperm aneuploidy (100, 101). Multivariate analyses of national data by the March of Dimes
Preliminary data from a study sponsored by the Czech Ministry of the Environment and the U.S. EPA (103) demonstrated a significant association between exposure to air pollutants and aneuploidy in sperm. FISH was used to detect chromosomes X, Y, and 8 in spermatozoa spermatozoa see spermatozoon. of nonsmoking non·smok·ing adj. 1. Not engaging in the smoking of tobacco: nonsmoking passengers. 2. Designated or reserved for nonsmokers: the nonsmoking section of a restaurant. men 18 years of age. Men exposed to the heaviest air pollution had an elevated level of sperm with an extra Y chromosome Y chromosome, n a sex chromosome that in humans and many other species is present only in the male, appearing singly in the normal male. It is carried as a sex determinant by one half of the male gametes. None of the female gametes contain a Y chromosome. (YY8), although other disomies were not increased (103). These examples illustrate how genetic markers are starting to be used in the evaluation of male reproductive health to highlight subtle but important effects of environmental risk factors. Recommendations for the Future Despite extensive research into environmental influences on male reproductive health, the scope of the problem is still unknown. Standardized epidemiologic investigations, including collaborative international studies of reproductive health parameters in general populations, may help to improve knowledge; however, defining optimal strategies for collecting relevant data presents a significant challenge for researchers and clinicians working in all areas of male reproductive health. The determinants of the various end points of male reproductive health and dysfunction--including infertility, sexual dysfunction, sperm characteristics, and birth outcomes--are poorly understood. There is abundant evidence that the male reproductive system can be influenced by exposure to hazardous substances during development, requiring the incorporation of preconception pre·con·cep·tion n. An opinion or conception formed in advance of adequate knowledge or experience, especially a prejudice or bias. Noun 1. periods in both human and in vivo in vivo /in vi·vo/ (ve´vo) [L.] within the living body. in vi·vo adj. Within a living organism. in vivo adv. experimental animal studies. However, there is also limited information about the mechanisms and the impact on male reproductive function of specific environmental exposures. It is therefore important that clinical researchers and epidemiologists work with basic scientists to strategize about what substances to focus on and how exposures to these substances can be prevented. The five recommendations for the future assume that a vital collaboration across disciplines and between government and academic institutions will be the most efficient and effective way to fill in the many gaps in knowledge. Moreover, collaborative international research will increase the capacity of researchers to make reliable comparisons of study populations. Prioritize hazardous substances. Limited information is available about the relationship between environmental exposures and reproductive risk in humans. Most of our knowledge on this subject comes from studies of occupational exposures. To design studies and collect data that will have the greatest potential to identify and characterize reproductive risks to humans, it is important to prioritize known or suspected reproductive toxicants. The evaluation of chronic, intermittent, and multiple exposures poses some of the most significant problems in all areas of environmental research. These kinds of exposures are difficult to specify and quantify, and the data needed to elucidate mechanisms of action for many chemicals and physical agents are often absent or inadequate. Although short-term exposure to environmental contaminants may cause dysfunction in the maturation process of the spermatozoa, for example, long-term exposures may disrupt neuroendocrine function, making it difficult to determine the initial cellular target and mode of causality in adverse male reproductive health outcomes. Assessing cumulative risks of exposure to multiple toxicants is more difficult than evaluating chemicals individually. Methods to examine the effects of complex chemical mixtures to protect human health in the real world must be developed. There are gaps in our understanding of the risks of chronic exposure to low levels of toxicants such as pesticides. The U.S. EPA is required to evaluate reproductive risks of exposures to pesticides and other toxic substances, as well as to develop tests to screen for chemicals with potential to disrupt the endocrine system. The U.S. EPA multigeneration reproductive toxicity test was recently modified (1998) to add more specific indicators of reproductive organ function such as sperm measures (104). The revised test is better suited to detect more subtle effects on spermatogenesis and sperm maturation that might not be of sufficient magnitude to alter fertility in rodents but could be relevant to assessing risks in humans. The revised test also includes evaluation of sexual differentiation and maturation and is therefore better able to detect environmental endocrine disruptors (104). This test and similar tests used by the U.S. National Toxicology Program National Toxicology Program Environment A program that conducts toxicologic tests on substances frequently found at the EPA's National Priorities List sites, which have the greatest potential for human exposure are suitable for hazard identification and are therefore important sources of information for prioritizing chemicals for further research including determination of the mode of action and cellular/molecular mechanisms of action. The U.S. EPA reproductive toxicity tests and harmonized protocols recommended for use by the Organisation for Economic Cooperation and Development (104, 105) are being applied voluntarily by industry to the large group of high-production volume (HPV HPV human papillomavirus. HPV abbr. human papilloma virus Human papilloma virus (HPV) ) chemicals for which reproductive toxicity data are often lacking. HPVs, which number more than 3,000, are defined as chemicals produced at a rate of more than one million pounds per year. A recent evaluation of U.S. EPA chemical data showed that nearly half (43%) of these HPVs have not been screened adequately for toxicity (106). Therefore, the U.S. EPA, albeit a valuable source of toxicity data, cannot be the only source of information about priority substances. Researchers and other government agencies must endeavor to define and explore other potential hazards. Evidence of reproductive effects derived from observations and studies in wildlife species may provide additional valuable clues about risks in humans despite interspecies differences among reproductive systems. Thus all sources of toxicologic information, whether obtained in humans, test species, or wildlife species, should be considered when prioritizing chemicals for further research. Elucidate the magnitude of male reproductive health effects. Testicular cancer. The rising incidence rate of testicular cancer among young men seems to indicate that new risk factors have arisen or that influences from previous factors have intensified. Because testicular cancer occurs in young men, any hypothesis about testicular carcinogenesis car·ci·no·gen·e·sis n. The production of cancer. carcinogenesis production of cancer. biological carcinogenesis viruses and some parasites are capable of initiating neoplasia. must consider major etiologic factors that may operate before conception, in utero, and early in life. New analytical studies are needed to further assess risk factors for this cancer, including assessment of early infections, low fertility and infertility, occupational exposures, dietary factors, and early exposure to abnormal levels of exogenous or endogenous hormones. It is important that researchers and clinicians assess the incidence and increase awareness of the risk of testicular cancer and carcinoma in situ in infertile men. Furthermore, it is essential to establish which of the available screening tools (e.g., manual testicular exams, scrotal scrotal /scro·tal/ (skro´t'l) pertaining to the scrotum. scrotal pertaining to scrotum. scrotal abscess ultrasonography ultrasonography /ul·tra·so·nog·ra·phy/ (-so-nog´rah-fe) the imaging of deep structures of the body by recording the echoes of pulses of ultrasonic waves directed into the tissues and reflected by tissue planes where there is a change in , and cytogenetic cytogenetic /cy·to·ge·net·ic/ (-je-net´ik) 1. pertaining to chromosomes. 2. pertaining to cytogenetics. cytogenetic pertaining to or originating from the origin and development of the cell. assays) are feasible and effective for early detection of testicular cancer and carcinoma in situ. Hypospadias and cryptorchidism. More standardized diagnostic criteria must be developed so that hypospadias and cryptorchidism can be uniformly recognized and enumerated This term is often used in law as equivalent to mentioned specifically, designated, or expressly named or granted; as in speaking of enumerated governmental powers, items of property, or articles in a tariff schedule. around the world. This will allow researchers to move toward an understanding of the causes of these disorders. For their investigation of male reproductive health, researchers depend not only on laboratory results but also on clinical diagnoses. It is critical that diagnostic procedures and classification be comparable around the world. For example, cryptorchidism, which resolves spontaneously in 70% of affected infants by their first birthday, should not be included in surveillance systems until the first birthday. Moreover, clinicians should be made aware of the importance of developmental age developmental age n. 1. The age of a fetus from conception to any point in time prior to birth. Also called fetal age. 2. Abbr. when evaluating infants born prematurely because it will affect the morphology of the testes. Researchers should also continue to identify and use existing reliable data sources and develop additional surveillance systems for tracking the incidence of these anomalies temporally and geographically. Clinical applications. Urologists, reproductive endocrinologists, and other clinicians can play a significant role in advancing biomedical research and prevention of adverse reproductive outcomes. They are on the front lines in the evaluation and treatment of male reproductive dysfunction; therefore they can also play a significant role in the collection of data important for studying male reproductive health. Clinicians should incorporate assessment of environmental risk factors into their examination protocol when they evaluate infertile couples or treat men with reproductive dysfunction or diseases (75). When men present with sexual dysfunction, for example, clinicians can develop objective means of differentiating the influences of environmental factors on sexual functioning from the influences of psychologic or physiologic factors. Currently, methods for such differentiation do exist; for example, by monitoring the frequency and quality of nocturnal erections. When exposure to an environmental toxicant is suspected, clinicians should initiate a physical examination including assessment of testicular size and abnormalities; a semen analysis; a hormonal profile; measurements of specific toxicants; and, in extreme cases, a testicular biopsy. Before the initiation of assisted reproductive techniques such as in vitro fertilization in vitro fertilization (vē`trō, vĭ`trō), technique for conception of a human embryo outside the mother's body. Several ova, or eggs, are removed from the mother's body and placed in special laboratory culture dishes (Petri dishes); or ICSI, the man should have a complete work-up, involving, as needed as needed prn. See prn order. , a urologist, andrologist, geneticist ge·net·i·cist n. A specialist in genetics. geneticist a specialist in genetics. geneticist , and occupational medicine physician, to investigate the etiology of the dysfunction or disease. Clinicians should also initiate prevention or minimization of known hazards by counseling patients to avoid exposure, to protect themselves during exposure, and to seek treatment after exposure. Clinicians can be the driving force behind public education on known reproductive hazards. Because of the clinicians' critical role, it is essential that medical schools devote more teaching time to environmental health issues and make students aware of the growing specialty of environmental and occupational medicine (107). Clinicians also need accurate information about environmental toxicants available in an efficient format. A centralized source of reliable information needs to be established and publicized for physicians who treat male reproductive dysfunction. An example of this type of resource has recently been developed for pediatricians, obstetricians, and other family care providers. The Handbook of Environmental Health for Children (108) is a comprehensive review of known environmental hazards affecting children, as well as guidance for evaluating, treating, and preventing these exposures. Develop biomarkers of exposures and male reproductive health for research and clinical use. Resources must be invested in developing more advanced biomarkers of exposure to reproductive toxicants and of reproductive health outcomes. Advanced biomarkers would allow for the development of toxicant-specific tests (e.g., polycyclic polycyclic having two or more usually fused chemical ring structures in their molecule. polycyclic hydrocarbons thyroid initiators, i.e. they increase the incidence of thyroid tumors. aromatic hydrocarbon--DNA adducts) and the detection of subclinical subclinical /sub·clin·i·cal/ (sub-klin´i-k'l) without clinical manifestations. sub·clin·i·cal adj. Not manifesting characteristic clinical symptoms. Used of a disease or condition. changes that might have significant health implications but which now go unnoticed by current measures. New biomarkers of semen quality are advantageous in that they can both describe male reproductive capacity and indicate toxic effects independent of the female partner's reproductive health. New tests could more accurately measure sperm function, fertilization potential, and the transmission of an intact male genome. Genetic testing Genetic Testing Definition A genetic test examines the genetic information contained inside a person's cells, called DNA, to determine if that person has or will develop a certain disease or could pass a disease to his or her offspring. may provide valuable tools for researchers and clinicians. For example, the sperm chromatin stability assay and FISH are used to assess genetic structure after exposure to a potential toxicant. Recently, single nucleotide polymorphisms have been used in the assessment of gene-environment interactions. Another key element of future research is the development of a standardized panel of relevant biomarkers. Individual biomarkers are often used in isolation to test for one specific exposure or type of outcome. However, a panel of biomarkers may, in combination, provide a more powerful lens through which to examine male reproductive capacity and evaluate toxicity. Therefore, researchers need to systematically examine correlation among existing biomarkers and develop standardized panels of complementary biomarkers. With the current tools it is possible to paint a more detailed picture of the relationship between environmental exposures and male reproductive health than has been previously understood. When prospective studies are designed with this approach in mind, epidemiologic models can provide data on the complex kinds of exposure patterns that undoubtedly have an impact on male reproductive health. Foster interdisciplinary research. Wildlife populations. The discoveries made by ecologists of reproductive abnormalities in wildlife populations have, in the past, alerted medical scientists to the possibility of correlated adverse health outcomes in humans (108). There are major differences in the endocrine system across species, so wildlife species must be studied first without extrapolation (mathematics, algorithm) extrapolation - A mathematical procedure which estimates values of a function for certain desired inputs given values for known inputs. If the desired input is outside the range of the known values this is called extrapolation, if it is inside then to humans in mind. However, information about wildlife can be used to guide studies in laboratory animal models, the results of which can be used to guide human research and policy development. The link between ecologic and biomedical research scientists needs to be strengthened so that the adverse health effects of environmental toxicants can be identified and studied quickly, with the goal of prevention. To that end, funding should be earmarked for collaborative multidisciplinary research projects that will bring specialized diverse researchers together to focus on common goals. In addition to establishing collaborative research, funding should be invested to improve wildlife surveillance. This will benefit the field of wildlife biology as well as, ultimately, characterization of wildlife sentinels for human health. Experimental models. Multigenerational mul·ti·gen·er·a·tion·al adj. Of or relating to several generations: multigenerational family traditions. studies with experimental animals, particularly continuous breeding studies, should be used to develop paradigms for human studies. Although animal research is limited in its correlation to human health outcomes, it is a critical component of gaining a better understanding of male reproductive health. Animal studies are beneficial because researchers can control the route and dose of exposure to the suspected toxicant as well as mixtures of toxicants, researchers can look at a wide variety of specific end points, the studies have fewer confounding factors than in human populations, and laboratory animals are genetically homogenous. Animal research thus allows for the determination of a toxicity threshold that can then be extrapolated to humans. It is not enough to know that a substance is toxic to the male reproductive system. Scientists must also examine the mechanisms of toxicity. Mechanistic understanding facilitates making predictions about the potential toxicity of individual compounds or complex mixtures, enhances our understanding of the windows of vulnerability in the development of the male reproductive system, and contributes to the development of improved screening tests (including in vitro in vitro /in vi·tro/ (in ve´tro) [L.] within a glass; observable in a test tube; in an artificial environment. in vi·tro adj. In an artificial environment outside a living organism. tests). Animal research is an important means of determining the mechanisms of toxicity, and research must proceed in this area. Furthermore, animal data can be used to help formulate hypotheses and design epidemiologic studies in humans, and in turn, human studies can inform toxicology experiments. Epidemiology. The evidence generated from studies of wildlife and experimental models should guide the development of prospective epidemiologic studies that focus on specific outcomes and measure specific toxicants. Epidemiologists should aim to study populations that are consistent geographically and over time, so that they may avoid confounding factors which can dilute observed associations. Appropriate prospective studies are needed to address geographic variability while taking into consideration or controlling other important variables. These include methods of selecting the study population and methods of semen analysis; seasonal variation; ethnic variation; and measurable environmental factors. One of the barriers to research in male reproductive health is the perceived or actual difficulty in obtaining semen samples. Epidemiologists should aim to increase response rates in their studies through individualized contact with the study subjects, limited financial incentives, and convenient collection methods. Existing surveillance systems may be valuable data sources for occupational reproductive health research. Exposure registries for workers exposed to known reproductive toxicants such as heavy metals heavy metals, n.pl metallic compounds, such as aluminum, arsenic, cadmium, lead, mercury, and nickel. Exposure to these metals has been linked to immune, kidney, and neurotic disorders. , pesticides, and radiation, for example, could be used to develop epidemiologic cohorts. Ongoing examination of available data will clarify the extent to which existing surveillance systems can be used. Standardized birth information forms would greatly aid epidemiologic research in the area of male reproductive health. There is a need to convene a working group to a) develop standardized data collection to ensure that equivalent data on potential parental exposures or risk factors are obtained worldwide and b) more reliably evaluate environmental exposures or other risk factors during critical periods of development. The development and implementation of uniform computerized records will allow for a more precise understanding of routinely collected data in the future. The systems used in Scandinavian countries can serve as a model for this kind of standardization (109). It is also important to increase the type of information collected on birth certificates so that these vital statistics may, in the future, provide the basis for useful retrospective cohort studies. At present, recommendations for data collection at birth in the United States are made nationally but states implement their own systems. Therefore, there is a clear need for national standards. A working group of experts should be convened to generate computerized pre-, peri-, and postnatal forms for clinicians to use. Although there are drawbacks to computer dependence including limited computer access in some settings, an enormous volume of data management, and the complexity of quality assurance and control, the benefits of standardized data collection outweigh the limitations. Recognize the importance of standardized laboratory methods and sample archiving. Scientists need to be able to compare data obtained through laboratory testing. However, many of the laboratory methods for assessing male reproductive health are not standardized, which means not only that different laboratories will generate different results using the same sample but also that the results of the same sample within one laboratory may be different when analyzed at different times. Centralization of laboratories is not necessary but standardization of methodologies is necessary. Quality control initiatives involving research and clinical laboratories are necessary to ensure reliability of data. It is critical that the international research community develop standards by which laboratory testing can become more accurate and more precise. This need for standardization applies to exposure as well as outcomes assessment. This will allow for a better characterization of international comparisons or trends in male reproductive health. These programs would encompass tissue archives, including pathologic specimens from tumors, blood banks, and semen banks. Research should be developed that will incorporate the use of archived tissue to provide as broad a picture of male reproductive health as possible. It is important to continue to archive tissue and develop strategies to maximize multiuse research in the future. Summary From changes observed in wildlife, to increasing rates of testicular cancer, to the debate regarding trends in sperm counts, there has been increasing concern that hazardous substances in the environment adversely affect male reproductive health. Our ability to fully address the impact of hazardous substances has been hampered by limitations on sources of relevant data and appropriate research methodologies. The recommendations summarized in this paper should serve as a framework for future studies to improve our knowledge in this area. By better defining the problems, learning about the mechanisms responsible for adverse effects, and developing panels of relevant biomarkers, we will make progress toward preventing future adverse effects on male reproductive health. REFERENCES AND NOTES (1.) Tas S, Lauwerys R, Lison D. Occupational hazards for the male reproductive system. Crit Rev Toxicol 26(3):261-307 (1996). (2.) NIOSH. The National Occupational Research Agenda. NIOSH 96-115. Cincinnati, OH:National Institute for Occupational Safety and Health, 1996. (3.) Ekbom A, Akre O. Increasing incidence of testicular cancer--birth cohort effects. APMIS APMIS Acta Pathologica, Microbiologica et Immunologica Scandinavica APMIS Automated Project Management Information System APMIS Automated Project Management System 106:225-231 (1998). (4.) Cryptorchidism: an apparent substantial increase since 1960. John Radcliffe Hospital The John Radcliffe Hospital is a large tertiary teaching hospital in Oxford, UK. It is the main teaching hospital for Oxford University and Oxford Brookes University. As such, it is a well developed centre of medical research. Cryptorchidism Study Group. Br Med J (Clin Res Ed) 29:1401-1404 (1986). (5.) Guillette LJ Jr, Brock JW, Rooney AA, Woodward AR. Serum concentrations of various environmental contaminants and their relationship to sex steroid concentrations and phallus phallus /phal·lus/ (fal´us) pl. phal´li 1. penis. 2. a representation of the penis. 3. the primordium of the penis or clitoris that develops from the genital tubercle. size in juvenile American alligators. Arch Environ Contam Toxicol 36(4):447-455 (1999). (6.) National Research Council. Biologic Markers in Reproductive Toxicology. Washington, DC:National Academy Press, 1989. (7.) Harrison PT, Holmes P, Humfrey CD. Reproductive health in humans and wildlife: are adverse trends associated with environmental chemical exposure? Sci Total Environ 205:97-106 (1997). (8.) Fox GA. Practical causal inference for ecoepidemiologists. J Toxicol Environ Health 33:359-373 (1991). (9.) Guillette LJ Jr, Gross TS, Masson GR, Matter JM, Percival HF, Woodward AR. Developmental abnormalities of the gonad gonad /go·nad/ (go´nad) a gamete-producing gland; an ovary or testis.gonad´algonad´ial indifferent gonad the sexually undifferentiated gonad of the early embryo. and abnormal sex hormone concentrations in juvenile alligators from contaminated and control lakes in Florida. Environ Health Perspect 102:680-688 (1994). (10.) Kelce WR, Stone CR, Laws SC, Gray LE, Kemppainen JA, Wilson EM. Persistent DDT metabolite p,p'-DDE is a potent androgen receptor antagonist. Nature 375:581-585 (1995). (11.) Facemire CF, Gross TS, Guillette LJ Jr. Reproductive impairment in the Florida panther: nature or nurture? Environ Health Perspect 103(suppl 4):79-86 (1995). (12.) Ankley G, Mihaich E, Stahl R, Tillitt D, Colborn T, McMaster S, Miller R, Bantle J, Campbell P, Denslow N, et al. Overview of a workshop on screening methods for detecting potential (anti-) estrogenic/androgenic chemicals in wildlife. Environ Toxicol Chem 17:68-87 (1998). (13.) Campbell PM, Hutchinson TH. Wildlife and endocrine disruptors: requirements for hazard identification. Environ Toxicol Chem 17:127-135 (1998). (14.) Carlsen E, Giwercman A, Keiding N, Skakkebaek NE. Evidence for decreasing quality of semen during past 50 years. Br Med J 305:609-613 (1992). (15.) Colborn T, Dumanoski D, Myers JP. Our Stolen Future. New York New York, state, United States New York, Middle Atlantic state of the United States. It is bordered by Vermont, Massachusetts, Connecticut, and the Atlantic Ocean (E), New Jersey and Pennsylvania (S), Lakes Erie and Ontario and the Canadian province of :Dutton Press, 1996. (16.) Irvine DS. Falling sperm quality [Letter]. Br Med J 309:476 (1994). (17.) James WH. Secular trend secular trend The relatively consistent movement of a variable over a long period. A stock in a secular uptrend is an indicator that the security has experienced an extended period of rising prices. in reported sperm count. Andrologia 12:381-388 (1980). (18.) Swan SH, Elkin EP, Fenster L. Have sperm densities declined? A reanalysis of global trend data. Environ Health Perspect 105:1228-1232 (1997). (19.) Toppari J, Larsen JC, Christiansen P, Giwercman A, Grandjean P, Guilette LJ Jr, Jegou B, Jensen TK, Jouennet P, Keiding N, et al. Male reproductive health and environmental xenoestrogens. Environ Health Perspect 104(suppl 4):741-803 (1996). (20.) Henderson BE, Benton B, Cosgrove M, Baptista J, Aldrich J, Townsend D, Hart W, Mack TM. Urogenital tract abnormalities in sons of women treated with diethylstilbestrol. Pediatrics 58:505-507 (1976). (21.) Gill WB, Schumacher GFB GFB Georgia Farm Bureau GFB Government-Furnished Baseline GFB Gasping for Breath GFB Geschäftsfallbearbeitung (German) GFB Gleaners Community Food Bank GFB Generalized Forward-Backward Method , Bibbo M. Pathological semen and anatomical abnormalities of the genital tract genital tract n. The genital passages of the urogenital system. Genital tract The organs involved in reproduction. in human male subjects exposed to diethylstilbestrol in utero. J Urol 117:477-480 (1977). (22.) Arai Y, Mori T, Suzuki Y, Bern HA. Long-term effects of perinatal exposure to sex steroids and diethylstilbestrol on the reproductive system of male mammals. Int Rev Cytol 84:235-268 (1983). (23.) Brown-Grant K, Fink G, Greig F, Murray MAF MAF macrophage activating factor. . Altered sexual development in male rats after oestrogen oes·tro·gen n. Variant of estrogen. oestrogen see estrogen. administration during the neonatal period. J Reprod Fertil 44:25-42 (1975). (24.) Newbold RR, Bullock BC, McLachlan JA. Adenocarcinoma adenocarcinoma: see neoplasm. of the rete testis. Diethylstilbestrol-induced lesions of the mouse rete testis. Am J Pathol 125:625-628 (1986). (25.) McLachlan JA. Rodent models for perinatal exposure to diethylstilbestrol and their relation to human disease in the male. In: Developmental Effects of Diethylstilbestrol (DES) in Pregnancy (Herbst AL, Bern HA, eds). New York:Thieme-Stratton, 1981;148-157. (26.) Newbold RR, McLachlan JA. Diethylstilbestrol associated defects in murine murine /mu·rine/ (mur´en) pertaining to, derived from, or characteristic of mice or rats. mu·rine adj. genital tract development. In: Estrogens in the Environment. II: Influences on Development (McLachlan JA, ed). New York:Elsevier, 1985;288-318. (27.) Wingo PA, Tong T, Bolden S. Cancer statistics, 1995. CA Cancer J Clin 45:8-30 (1995). (28.) Bosl GJ, Motzer RJ. Testicular germ-cell cancer. N Engl J Med 337:242-253 (1997). (29.) Skakkehaek NE, Rajpert-De Meyts E, Jorgensen N, Cerlsen E, Petersen PM, Giwercman A, Andersen A-G A-G Air-to-Ground , Jensen TK, Andersson A-M A-M Alternating Maximization (algorithm) , Muller J. Germ cell cancer and disorders of spermatogenesis: an environmental connection? APMIS 106:3-12 (1998). (30.) Adami H-O, Bergstrom R, Mohner M, Zatonski W, Storm H, Ekbom A, Tretli S, Teppo L, Ziegler H, Rahu M, et al. Testicular cancer in nine northern European countries. Int J Cancer 59:33-38 (1994). (31.) Bergstrom R, Adami H-O, Mohner M, Zatonski W, Storm H, Ekbom A, Tretli S, Teppo L, Akre O, Hakulinen T. Increase in testicular cancer incidence in six European countries: a birth cohort phenomenon. J Natl Cancer Inst 88:727-733 (1996). (32.) Levi F, Te V-C, La Vecchia C. Testicular cancer trends in the Canton of Vaud, Switzerland, 1974-1987. Br J Cancer 62:871-873 (1990). (33.) Pearce N, Sheppard RA, Howard K, Fraser J, Lilley BM. Time trends and occupational differences in cancer of the testis in New Zealand. Cancer 59:1677-1682 (1987). (34.) Thompson IM, Optenberg S, Byers R, Dove M. Increased incidence of testicular cancer in active duty members of the Department of Defense. Urology 53:806-807 (1999). (35.) Magoha GA. Testicular cancer in Nigerians. East Afr Meal J 72:554-556 (1995). (36.) Stat bite: U.S. incidence of testicular cancer [News]. J Natl Cancer lost 91(21):1803 (1999). (37.) Davies JM. Testicular cancer in England and Wales England and Wales are both constituent countries of the United Kingdom, that together share a single legal system: English law. Legislatively, England and Wales are treated as a single unit (see State (law)) for the conflict of laws. ; some epidemiological aspects. Lancet 1(8226):928-932 (1981). (38.) Westergaard T, Andersen PK, Pederson JB, Frisch M, Olsen JH, Melbye M. Testicular cancer risk and maternal parity: a population-based cohort study. Br J Cancer 77:1180-1185 (1998). (39.) Moller H, Skakkebaek NE. Testicular cancer and cryptorchidism in relation to prenatal factors: case-control studies in Denmark. Cancer Causes Control 8:904-912 (1997). (40.) Akre O, Ekbom A, Hsieh CC, Trichopoulos D, Adami HO. Testicular nonseminoma and seminoma seminoma /sem·i·no·ma/ (-no´mah) a radiosensitive, malignant neoplasm of the testis, thought to be derived from primordial germ cells of the sexually undifferentiated embryonic gonad. Cf. germinoma. in relation to prenatal characteristics. J Natl Cancer Inst 88:883-889 (1996). (41.) Moller H, Skakkebaek NE. Risks of testicular cancer and cryptorchidism in relation to socio-economic status end related factors: case-control studies in Denmark. Int J Cancer 66:287-293 (1996). (42.) Mills PK. Correlation analysis of pesticide use data and cancer incidence rates in California counties. Arch Environ Health 53:410-413 (1998). (43.) Hardell L, Nasman A, Ohlson CG, Fredrikson M. Case-control study on risk factors for testicular cancer. Int J Oncol 13:1299-1303 (1998). (44.) Foley S, Middleton S, Stitson D, Mahoney M. The incidence of testicular cancer in Royal Air Force personnel. Br J Urol 76:495-496 (1995). (45.) Hardell L, Ohlson CG, Fredrikson M. Occupational exposure to polyvinyl chloride as a risk factor for testicular cancer evaluated in a case-control study. Int J Cancer 73:828-830 (1997). (46.) Ramani P, Yeung C, Habeebu S. Testicular intratubular germ cell neoplasia neoplasia /neo·pla·sia/ (-pla´zhah) the formation of a neoplasm. cervical intraepithelial neoplasia in children and adolescents with intersex intersex /in·ter·sex/ (in´ter-seks) 1. hermaphrodite. 2. pseudohermaphrodite. 3. intersexuality. female intersex a female pseudohermaphrodite. . Am J Surg Pathol 17:1124-1132 (1993). (47.) Rajpert-De Meyts E, Jorgensen N, Brondum-Nielsen K, Muller J, Skakkebaek NE. Developmental arrest of germ cells in the pathogenesis of germ cell neoplasia. APMIS 106:196-206 (1998). (48.) Moller H, Skakkebaek NE. Risk of testicular cancer in subfertile men: case-control study. Br Med J 318:559-562 (1999). (49.) Moller H. Trends in sex-ratio, testicular cancer and male reproductive hazards: are they connected? APMIS 106:232-239 (1998). (50.) Sharpe RM, Skakkebaek NE. Are oestrogens involved in falling sperm counts and disorders of the male reproductive tract? Lancet 29:1392-1395 (1993). (51.) Congenital malformations worldwide: a report from the International Clearinghouse for Birth Defects Monitoring Systems. Oxford:Elsevier, 1991. (52.) Paulozzi LJ. International trends in rates of hypospadias and cryptorchidism. Environ Health Perspect 107:297-302 (1999). (53.) Auger J, Kunstmann JM, Czyglik F, Jouannet P. Decline in sperm quality among fertile men in Paris during the past 20 years. N Engl J Med 332:281-285 (1995). (54.) Bostofte E, Serup J, Rebbe reb·be n. A Jewish spiritual leader or rabbi, especially of a Hasidic sect. [Yiddish, from Hebrew rabbî, rabbi; see rabbi.] H. Has the fertility of Danish men declined through the years in terms of semen quality? A comparison of semen qualities between 1952 and 1972. Int J Fertil 28:91-95 (1983). (55.) Bendvold E. Semen quality in Norwegian men over a 20-year period. Int J Fertil 34:401-404 (1989). (56.) Carlsen E, Giwercman A, Keiding N, Skakkebaek NE Declining semen quality and increasing incidence of testicular cancer: is there a common cause? Environ Health Perspect 103(suppl 7):137-139 (1995). (57.) Fisch H, Ikeguchi EF, Goluboff ET. Worldwide variations in sperm counts. Urology 48:909-911 (1996). (58.) Fisch H, Goluboff ET, Olson JH, Feldshuh J, Broder SJ, Barad DH. Semen analyses in 1,283 men from the United States over a 25-year period: no decline in quality. Fertil Steril 65:1009-1014 (1996). (59.) Rasmussen PE, Erb K, Westergaard LG, Laursen SB. No evidence for decreasing semen quality in four birth cohorts of 1,055 Danish men born between 1950 and 1970. Fertil Steril 68:1059-1064 (1997). (60.) Fisch H, Andrews H, Hendricks J, Goluboff ET, Olson JH, Olsson CA. The relationship of sperm counts to birth rates: a population based study. Urology 157:840-844 (1997). (61.) Claudio L, Bearer CF, Wallinga D. Assessment of the U.S. Environmental Protection Agency methods for identification of hazards to developing organisms. Part I: the reproduction and fertility testing guidelines. Am J Ind Med 35(6):543-553 (1999). (62.) Chapin RE, Sloane RA, Haseman JK. The relationships among reproductive endpoints in Swiss mice, using the reproductive assessment by continuous breeding database. Fundam Appl Toxicol 38:129-142 (1997). (63.) Wyrobeck AJ, Schrader SM, Perreault SD, Fenster L, Huszar G, Katz DF, Osorio AM, Sublet sub·let tr.v. sub·let, sub·let·ting, sub·lets 1. To rent (property one holds by lease) to another. 2. To subcontract (work). n. V, Evenson D. Assessment of reproductive disorders and birth defects in communities near hazardous chemical sites. III: Guidelines for field studies of male reproductive disorders. Reprod Toxicol 11:243-259 (1997). (64.) Golden AL, Moline JM, Bar-Chama N. Male reproduction and environmental and occupational exposures: a review of epidemiological methods. Salud Publica de Mexico 41(suppl 2):S93-S105 (1999). (65.) Whorton D, Krauss RM, Marshall S, Milby TH. Infertility in male pesticide workers. Lancet 2:1259-1261 (1977). (66.) Whorton D, Foliart D. DBCP DBCP Dibromochloropropane DBCP Database Connection Pooling DBCP Data Buoy Cooperation Panel (IOC, WMO) DBCP Digital Broadcast Content Provision (FCC) DBCP Data Base Connection Pools : eleven years later. Reprod Toxicol 2:155-161 (1988). (67.) Schrader SM. Male reproductive toxicity. In: Handbook of Human Toxicology (Massaro EJ, ed). Boca Raton, FL:CRC (Cyclical Redundancy Checking) An error checking technique used to ensure the accuracy of transmitting digital data. The transmitted messages are divided into predetermined lengths which, used as dividends, are divided by a fixed divisor. Press, 1997:962-980. (68.) Schrader SM, Turner TW, Ratcliffe JM. The effects of ethylene dibromide on semen quality: a comparison of short-term and chronic exposure. Reprod Toxicol 2:191-198 (1988). (69.) Bonde JP, Hjollund H, Kolstad H, Abell A, Larsen B. Environmental semen studies: is infertility increased by a decline in sperm count? [Abstract]. Presented at the International Symposium on Environment, Lifestyle and Fertility, 7-10 December 1997, Aarhus, Denmark. (70.) Hatch M, Marcus M. Occupational exposures and reproduction. In: Reproductive and Perinatal Epidemiology (Kiely M, ed). Boca Raton, FL:CRC Press, 1993;131-142. (71.) Selevan SG. Epidemiology. In: Occupational and Environmental Reproductive Hazards: A Guide for Clinicians (Paul M, ed). Baltimore, MD:Williams & Wilkins, 1993;100-110. (72.) Schrader SM, Turner TW, Breitenstein MJ, Simon SD. Longitudinal study of semen quality of unexposed workers. I: Study overview. Reprod Toxicol 2:183-190 (1998). (73.) Schenker MB, Samuels SJ, Perkins C, Lewis EL, Katz DF, Overstreet JW. Prospective surveillance of semen quality in the workplace. J Occup Meal 30:336-344 (1988). (74.) Larsen SB, Abell A, Bonde JP. Selection bias in occupational sperm studies. Am J Epidemiol 147:681-685 (1998). (75.) Bar-Chama N, Lamb DJ. Evaluation of sperm function. What is available in the modern andrology laboratory? Urol Clin North Am 21:433-446 (1994). (76.) Schrader SM, Turner TW, Simon SD. Longitudinal study of semen quality of unexposed workers. Sperm motility characteristics. J Androl 12:126-131 (1991). (77.) Royster MO, Lobdell DT, Mendola P, Perreault SD, Selevan SA, Rothmann SA, Robbins WA. Evaluation of a container for collection and shipment of semen with potential uses in populations-based, clinical and occupational settings. J Androl 21:478-484 (2000). (78.) Bigelow PL, Jarrell J, Young MR, Keefe TJ, Love EJ. Association of semen quality and occupational factors: comparison of case-control analysis and analysis of continuous variables. Fertil Steril 69:11-18 (1998). (79.) Levine R. Methods for detecting occupational causes of male infertility. Scand J Work Environ Health 9:371-376 (1983). (80.) World Health Organization. WHO laboratory manual for the examination of human sperm and semen-cervical mucus interaction, 4th ed. Cambridge, NY:Cambridge University Press Cambridge University Press (known colloquially as CUP) is a publisher given a Royal Charter by Henry VIII in 1534, and one of the two privileged presses (the other being Oxford University Press). , 1999. (81.) Kruger TF, Menkveld R, Stander FS, Lombard CJ, Van der Merwe JP, van Zyl JA, Smith K. Sperm morphologic features as a prognostic factor in in vitro fertilization. Fertil Steril 46:1118-1130 (1986). (82.) Lipschultz LI. The debate continues--the continuing debate over the possible decline in semen quality. Fertil Steril 65:909-911 (1996). (83.) Martin RH, Ernst S, Rademaker A, Barclay L, Ko E, Summers N. Chromosomal abnormalities in sperm from testicular cancer patients before and after chemotherapy. Hum Genet genet: see civet. 99:214-218 (1997). (84.) Bonde JP, Giwercman A, Ernst E. Identifying environmental risk to male reproductive function by occupational sperm studies: logistics and design options. Occup Environ Med 53:511-519 (1996). (85.) Bonde JP, Joffe M, Danscher G, Apostoli P, Bisanti L, Giwercman A, Kolstad H, Thonneau P, Roeleveld N, Vanhoorne M. Objectives, designs and populations of the European Asclepios study on occupational hazards to male reproductive capability. Scand J Work Environ Health 25(suppl 1):49-61 (1999). (86.) Schrader SM, Platek SM, Zaneveld IJD IJD International Journal of Dermatology IJD Indian Journal of Dermatology , Perez-Palaez M, Jeyendra RS. Sperm viability: a comparison of analytical methods. Andrologia 18:530-538 (1986). (87.) Schrader SM, Kesner JS. Male reproductive toxicology. In: Occupational and Environmental Reproductive Hazards. A Guide for Clinicians (Paul M, ed). Baltimore:Williams & Wilkins, 1993;3-17. (88.) Santen RJ, Bardin CW. Episodic luteinizing hormone secretion in man: pulse analysis, clinical interpretation, physiologic mechanisms. J Clin Invest 52:2616-2628 (1973). (89.) Sokol RZ. Endocrine evaluations in the assessment of male reproductive hazards. Reprod Toxicol 2:217-222 (1988). (90.) Schrader SM, Turner TW, Breitenstein MJ, Simon SD. Measuring male reproductive hormones for occupational field studies. J Occup Med 35:574-576 (1993). (91.) Apostoli P, Romeo L, Peroni E, Ferioli A, Ferrari S, Pasini F, Aprili F. Steroid hormone sulphation in lead workers. Br J Ind Med 46:204-208 (1996). (92.) Halvorson LM, DeCherney AH. Inhibin, activin, and follistatin in reproductive medicine. Fertil Steril 65:459-469 (1996). (93.) Jensen TK, Andersson AM, Hjollund NH, Scheike T, Kolstad H, Giwercman A, Henriksen TB, Ernst E, Bonde JP, Olsen J, et al. Inhibin B as a serum marker of spermatogenesis: correlation to differences in sperm concentration and follicle-stimulating hormone levels. A study of 349 Danish men. J Clin Endocrinol Metab 82:4059-4063 (1997). (94.) Moosani N, Pattinson HA, Carter MD, Cox DM, Rademaker AW, Martin RH. Chromosomal analysis of sperm from men with idiopathic infertility using sperm karyotyping and fluorescence in situ hybridization. Fertil Steril 64:811-817 (1995). (95.) Jacobs PA. The chromosome complement of human gametes. In: Oxford Review of Reproductive Biology (Milligan SR, ed). New York:Oxford University Press, 1992;47-72. (96.) Martin R, Redemaker A. The effect of age on the frequency of sperm chromosomal abnormalities in normal men. Am J Hum Genet 41:484-492 (1987). (97.) Martin RH, Spriggs E, Rademaker AW. Multicolor fluorescence in situ hybridization analysis of aneuploidy and diploidy dip·loi·dy n. The state or condition of being diploid. diploidy the state of being diploid. diploidy A DNA complement double the haploid number, n–ie, 2n. See Haploid. Cf Aneuploidy. frequencies in 225,846 sperm from 10 normal men. Biol Reprod 54:394-398 (1998). (98.) Spriggs EL, Rademaker AW, Martin RH. Aneuploidy in human sperm: the use of multicolor FISH to test various theories of nondisjunction. Am J Hum Genet 58:356-362 (1996). (99.) Kinakin B, Rademaker A, Martin R. Paternal age effect The paternal age effect describes the influence that a father's age has on the chances of conferring a genetic defect to his offspring. Generally, older men have a greater probability of fathering children with a genetic defect than younger men do. of YY aneuploidy in human sperm, as assessed by fluorescence in situ hybridization. Cytogenet Cell Genet 78:116-119 (1997). (100.) Robbins WA, Vine MF, Truany KY, Everson RB. Use of fluorescence in situ hybridization (FISH) to assess effects of smoking, caffeine, and alcohol and aneuploidy load in sperm of healthy men. Environ Mol Mutagen mutagen: see mutation. mutagen Any agent capable of altering a cell's genetic makeup by changing the structure of the hereditary material, DNA. Many forms of electromagnetic radiation (e.g. 30:175-183 (1997). (101.) Rubes Rubes is a syndicated newspaper single panel cartoon created by Leigh Rubin in 1984. Leigh Rubin began making and distributing his own greeting cards in 1979 through his company Rubes. J, Lowe X, Moore D II, Perreault S, Slott V, Evenson D, Selevan SG, Wyrobek AJ. Smoking cigarettes is associated with increased sperm disomy in teenage men. Fertil Steril 70:715-723 (1998). (102.) Petrini J, Alter C, Andrews H, Damus K. Men have babies too: paternal factors and pregnancy outcomes [Abstract]. Presented at the International Conference on Hazardous Substances and Male Reproductive Health, 14-15 May 1998, New York, New York. (103.) Robbins WA, Rubes J, Selevan SG, Perreault SD. Air pollution and sperm aneuploidy in healthy young men. Environ Epidemiol Toxicol 1:125-131 (1999). (104.) U.S. Environmental Protection Agency. Health Effect Test Guidelines. Reproduction and Fertility Effects. OPPTS OPPTS Office of Prevention, Pesticides & Toxic Substances (US Environmental Protection Agency) 870.3800. Washington, DC:U.S. Government Printing Office, 1998. (105.) Organisation for Economic Co-operation and Development The Organisation for Economic Co-operation and Development (OECD), (in French: Organisation de coopération et de développement économiques; OCDE) is an international organisation of thirty countries that accept the principles of representative democracy and a free market . OECD's Guidelines for the Testing of Chemicals, Section 4--Health Effects. TG Nos. 414, 415, 416. Available: http://www.oecd.org/ehs/test/health.htm [cited 14 June 2000]. (106.) U.S. Environmental Protection Agency Office of Pollution Prevention and Toxics. Chemical Hazard Data Availability Study. Available: http://www.epa.gov/ opptintr/chemtest.htm [cited 14 June 2000]. (107.) Pope AM, Rall DP, eds. Environmental Medicine: Integrating a Missing Element into Medical Education. Washington, DC:National Academy Press, 1995. (108.) American Academy of Pediatrics The American Academy of Pediatrics ("AAP") is an organization of pediatricians, physicians trained to deal with the medical care of infants, children, and adolescents. Its motto is: "Dedicated to the Health of All Children. . Handbook of Pediatric pediatric /pe·di·at·ric/ (pe?de-at´rik) pertaining to the health of children. pe·di·at·ric adj. Of or relating to pediatrics. Environmental Health (Etzel RA, Balk balk the action of a horse when it refuses to obey a command to which it usually responds. See also jibbing. SJ, eds). Elk Grove Village Elk Grove Village, village (1990 pop. 33,429), Cook and Du Page counties, NE Ill., a suburb of Chicago; inc. 1956. With a population of c.100 at the time of its establishment on open farmland, the village has grown dramatically and steadily, largely because of its , IL:American Academy of Pediatrics, 1999. (109.) van der Schalie WH, Gardner HS Jr, Bantle JA, De Rosa CT, Finch RA, Reif JS, Reuter RH, Backer LC, Burger J, Folmar LC, et al. Animals as sentinels of human health hazards of environmental chemicals. Environ Health Perspect 107:309-315 (1999). (110.) Lunde AS, Lundeborg S, Lettenstrom GS, Thygesen L, Huebner J. The person-number systems of Sweden, Norway, Denmark, and Israel. Vital Health Stat 2:1-59 (1980). Jacqueline M. Moline,(1) Anne L. Golden,(1) Natan Bar-Chama,(2) Ernest Smith,(3) Molly E. Rauch,(1) Robert E. Chapin,(4) Sally D. Perreault,(5) Steven M. Schrader,(6) William A. Suk SUK Sveriges Unga Katoliker (Swedens Young Catholics) ,(4) and Philip J. Landrigan(1) (1) Department of Community and Preventive Medicine, Mount Sinai Medical Center, New York, New York, USA; (2) Department of Urology, Mount Sinai School of Medicine, New York, New York, USA; (3) Institute of Environmental and Human Health, Texas Technical University/TTU Health Science Center, Lubbock, Texas, USA; (4) National Institute of Environmental Health Sciences The National Institute of Environmental Health Sciences (NIEHS) is one of 27 Institutes and Centers of the National Institutes of Health (NIH),which is a component of the Department of Health and Human Services (DHHS). The Director of the NIEHS is Dr. David A. Schwartz. , Research Triangle Park Research Triangle Park, research, business, medical, and educational complex situated in central North Carolina. It has an area of 6,900 acres (2,795 hectares) and is 8 × 2 mi (13 × 3 km) in size. Named for the triangle formed by Duke Univ. , North Carolina, USA; (5) U.S. Environmental Protection Agency, Research Triangle Park, North Carolina, USA; (6) National Institute for Occupational Safety and Health, Cincinnati, Ohio, USA Address correspondence to J. Moline, Mount Sinai School of Medicine, Box 1057, 1 Gustave Levy Place, New York, NY 10029 USA. Telephone: (212) 241-4792. Fax: (212) 996-0407. E-mail: jacqueline.moline@mssm.edu This work was supported by NIH grant ES07198 (Superfund) from the NIEHS. Further support for the Hazardous Substances and Male Reproductive Health conference was provided by the U.S. Environmental Protection Agency, the National Institute for Occupational Safety and Health, the Agency for Toxic Substances and Disease Registry, and the New York Academy of Medicine. The contents of this work are solely the responsibility of the authors and do not necessarily represent the official views of the NIEHS, NIH. This document has been reviewed in accordance with the U.S. Environmental Protection Agency policy and approved for publication. Mention of trade names or commercial products does not constitute endorsement or recommendation for use. Received 24 January 2000; accepted 20 March 2000. |
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