key: cord-0975985-5arkhr9r authors: Tirpák, Filip; Greifová, Hana; Lukáč, Norbert; Stawarz, Robert; Massányi, Peter title: Exogenous Factors Affecting the Functional Integrity of Male Reproduction date: 2021-03-09 journal: Life (Basel) DOI: 10.3390/life11030213 sha: 0e964158671df96dd7c551f56e5012ad4a8badd3 doc_id: 975985 cord_uid: 5arkhr9r Natural processes along with increased industrial production and the irresponsible behavior of mankind have resulted in environmental pollution. Environmental pollutants can be categorized based on their characteristics and appearance into the following groups: physical, biological, and chemical. Every single one of them represents a serious threat to the male reproductive tract despite the different modes of action. Male gonads and gametes are especially vulnerable to the effect of exogenous factors; therefore, they are considered a reliable indicator of environmental pollution. The impact of xenobiotics or radiation leads to an irreversible impairment of fertility displayed by histological changes, modulated androgen production, or compromised spermatozoa (or germ cells) quality. The present article reviews the exogenous threats, male reproductive system, the mode of action, and overall impact on the reproductive health of humans and animals. The present society is largely focused on the creation and optimization of technological methods. This effort for financial or personalistic gain, or the process simplification of production brings along high, although on first sight, imperceptible sacrifice. The development and spread of diseases of affluence reflect the negative impact of various byproducts of industrial production or other anthropogenic activities. Accordingly, the most advanced industrial areas are usually also known for the enormous environmental pollution. The accumulation and consecutive synergism of toxicants in the living environment leads to impairment of individual physiological processes or even death [1] . Contaminants, commonly known also as risk factors, may have different characteristics depending on their origin. Physical contamination is caused by ubiquitous ionizing and nonionizing radiation. Micro-organisms and their metabolites or pollens can be considered as risk factors of biological origin. Chemical contaminants include endocrine disruptors or toxic metals [2] . Pollutants tend to accumulate in different organs and harm their functions. Poisoning or contaminant-derived diseases can be acute (episodic) or can develop over time (chronic intoxication). They are often accompanied by skin problems, breathing complications, convulsions, digestive disorders, or serious failures of the central nervous system and endocrine activity. The most terrifying effects, affecting even the progeny, are mutagenicity and carcinogenicity [3] [4] [5] [6] [7] [8] . A good example of the consequence of high environmental pollution is the year to year decrease in the infertility of wild animals, domestic animals, or even humans. A negative effect of toxicants (decrease in concentration, motility, or longevity of spermatozoa) is often monitored on the individual or the group of individuals, however, the mechanism of action of toxicants on the cellular level is not studied enough. If so, most of the time only one compound is studied at a time and studies do not take into consideration the possible effect of synergism or antagonism of xenobiotics [9] [10] [11] [12] . Previous studies imply that the exogenic effect of toxicants is strongly related to the enhanced production of reactive oxygen species (ROS) and reactive nitrogen species (RNS), resulting in the degradation of biomolecules or even apoptosis [13] . On the other hand, it is important to mention that ROS are necessary for the physiological processes of spermatozoa such as capacitation or acrosome reaction. Therefore, spermatozoa may be affected by several exogenic and endogenic factors where the determining variables are the imbalance between antioxidants and free radicals and appropriate proportion between individual components of seminal plasma [14] . The present article describes exogenous agents in general and summarizes the current knowledge about their effects on male reproductive system and their modes of action. The pollution of the environment has a serious consequence in the endangerment of human and animal health. It is caused primarily by growing industrial production, transportation, chemical substances used in agriculture [15, 16] , and pharmaceutical remedies [17] . Soil contamination and thus the pollution of foods of plant origin is one of the most pressing issues in discussion about food safety on the European [18] or even global [19] level. Gonads and gametes serve as a very sensible and reliable barometer of the incidence of risk elements in the environment. They are affected via the degeneration of seminiferous epithelium, abortion of connection with the basal membrane, defects in spermatozoa development, and generation of ROS thereby reducing male fertility [20] [21] [22] [23] . Donkin and Barres [24] report that environmental factors along with diet and lifestyle are reflected in spermatozoa epigenetics. More important, these genetic changes may be passed on to the next generations via epigenetic inheritance. We recognize three types of contaminants that can eventually cause environmental pollution and we divide them based on their character and appearance on physical biological and chemical contaminants [2] . The Glossary of Environment Statistics issued by the United Nations Department for Economic and Social Information and Policy Analysis defines physical pollution as pollution caused by color, suspended solids, foaming, thermal conditions, or radioactivity [25] . This definition was adopted by the Organization for Economic Cooperation and Development (OECD) and is still used today [26] . Color pollution is the result of color contamination by an inappropriate arrangement of colors that induces a disorder in the perception of the visual field within the natural or urban environment [27] . Suspended solids are contaminants of the water environment in the form of microplastics. Microplastics are serious polluting agents themselves, moreover, they may have a role as pathogen carriers. Their presence in a marine environment is a threat not only to aquatic flora and fauna but also to human food safety in the form of seafood and salt [28, 29] . Temperature changes in the aquatic system may also cause thermal pollution which is reflected in degraded water quality. The source of thermal pollution is frequently found in the activity of power plants. The negative effect is then shown on soil erosion or on fish that exhibit thermal shock, metabolism alterations, and reproductive dysfunction [30, 31] . Another water-related contaminant causing physical pollution is foaming. Due to the appearance of the foam on the surface of the freshwater, contamination can be easily visually recognizable. Foam pollution may find a cause in the natural processes of aquaculture or anthropogenic activity. Man-made pollution is often caused unintentionally by of oil, detergent, or lignosulfonate leaks. Foam lines are formed from the surfactants which reduce the tension of the water surface and enable the foam bubbles occurrence [32] . Radiation is an extensively occurring contaminant of the environment. Radiation can be divided based on the amount of emitted energy into ionizing and non-ionizing, which determinates the power and further features of the radiation. Non-ionizing radiation causes electron excitation which can induce heat generation. Ionizing radiation possesses enough energy to induce the emission of electrons from atoms and electrons being a threat to all living organisms [33, 34] . Radioactive compounds are usually the waste of nuclear power generation, production of nuclear fuels, weapons development, biomedical interests, and industrial activities. However, radioactive contaminants can also originate in nature [35] . Radiation is the only exogenous agent of the group of physical contaminants that have a direct effect on male reproduction. As the ubiquitous aspect of the modern age, radiation may be considered a serious threat based on its emitted energy, frequency, and dose of exposure (Table 1 ). Table 1 . The effect of non-ionizing and ionizing radiation on the most targeted sites in male reproduction. The Site of the Effect Non-ionizing The term biological contaminant covers all cases of contaminations induced by the biological activity of organisms in the environment. This includes all invasive plant and animal species, pollen, but concerning reproduction, the most frequent biological pollutants are microorganisms. Either microbes themselves or their metabolites cause air, water, soil, or food pollution [54] [55] [56] [57] . The food chain contains numerous entries for contamination. The contamination of groceries is often associated with improper storage conditions while fresh products are considered safe and healthy. This bias is frequently promoted along with a healthy lifestyle. However, microbiological threats are present in every step of the farmto-fork chain, including the soil, water sources, cultivation, harvesting, and processing [58] . In respect to one of the highest sources of contamination, water, the US Environmental Protection Agency identifies over 500 waterborne pathogens, including viruses, fungi, bacteria, protozoa [59] . Epidemiologists also warn against the HVAC (heating, ventilation, and air conditioning) technology and hand dryers in public restrooms when they are not regularly maintained, inspected for microbial pollution, and disinfected [60] . Male reproductive organs are prone to microbial infection and subsequential inflammations. The male urogenital tract is occupied by numerous bacteria including Escherichia coli, Proteus spp., Enterococcus spp., and other Gram-positive and Gram-negative bacteria. The presence of bacteria in the semen is called bacteriospermia and does not inevitably mean the pathological sign. On the contrary, the presence of Mycoplasma spp., Chlamydia spp. or other pathogenic bacteria are not appreciated. Sequela such as orchitis, epididymitis may be caused by Brucella spp., Mycobacterium leproe, Mycobacterium leproe, or uropathogenic Escherichia coli. In addition to epididymis and testis, Chlamydia trachomotis targets and causes inflammation of the urethra, prostate, and seminal vesicles. In certain cases, when the concentration of pathogenic bacteria is too excessive, the body responds with leukocytospermia-abnormally high concentration of white blood cells in ejaculate. The physiological regulation of this phenomenon is not sufficiently explained yet [60] [61] [62] [63] . Some authors even did not find any or just weak associations between bacteriospermia and leukocytospermia [64, 65] . Semen may be considered the vector of viral infection; however, the male reproductive system may also suffer from viral contamination. It has been documented that semen may be a host to approximately 27 viruses. This includes Adenoviruses, Ebola virus, Hepatitis virus (HPV) B and C, Zika virus, Epstein Barr virus, Human immunodeficiency virus (HIV), Mumps virus, several herpes viruses, Human T-cell lymphoma virus, SARS-CoV-2 virus, etc. [61, 66, 67] . Evidence on the direct effect of viruses on fertility has been reported by several studies. Some viruses affect only the spermatozoa by alteration of their motility and viability (Hepatitis B and C, SARS-CoV-2, HPV) [67] [68] [69] . On the other hand, the CoxsacKie virus, Mumps virus, HIV, Zika virus, HPV, Influenza virus target male reproductive organs-testis and epididymis [68] [69] [70] [71] [72] . In some cases of HPV infection, the targeted site might be just Sertoli cells. This phenomenon is called the "Sertoli cell-only" syndrome [71] . Chemical contaminants turn into pollutants when accumulations are sufficient to undesirably affect the natural environment or to present a risk to living organisms. There are thousands of industrial chemicals identified as a hazard to humans, animals, and the environment. Therefore, governmental agencies regulate their production, storage, transportation, and disposal. Sources of chemical contamination contain agricultural activities, industrial and manufacturing activities, municipal waste, service-related activities, and resource extraction [73] . The term "heavy metals" defines a wide group of contaminating elements that are distinctive of their miscellaneous features, associated effects, and origin. Heavy metals of-ten appear as positively charged molecules that bind to negatively charged molecules of other elements to become a part of a compound. Ecotoxicological studies include the group of heavy metal elements like Cu, Zn, Cd, Hg, Pb, Cr, Ni, Mn, Fe, and semimetals As and Se. These metals are sometimes incorrectly indexed as toxic metals which is inaccurate since many metals are essential nutrients and at certain levels are not toxic at all [74, 75] . Heavy metals fall into a group of trace elements. Their impact on the body may be diverse-metabolic, carcinogenic, or even mutagenic. The mode of action depends on several factors: the features of the element, a form of contact with the organism, the dose of the element, exposure time, type of absorption of the element, or bioaccumulation. The current research is aimed mainly at heavy metals present in industrial or former mining areas [76] . According to Arvay et al. [77] , toxicity varies in dependence on mobility, solubility, pH, etc. Numerous studies proved that heavy metals accumulate in adipose tissues and consequently disrupt the functioning of internal organs and impair the nervous or endocrine system [78] [79] [80] . In general, compounds containing heavy metals are toxic, mutagenic, teratogenic, and carcinogenic for animals [81] . There are several ways of the entrance to the animal organism (e.g., consumption, inhalation, through the skin) that can cause severe intoxications [82] . Therefore, thorough, and periodic monitoring of health conditions is required in polluted areas [9, 16, 83] . The detrimental effects of heavy metals have been reported by numerous studies. Table 2 displays the most serious heavy metals-induced deteriorations reported in association with the male reproductive system. Endocrine disruptors represent a large group of environmental xenobiotic com-pounds that can interfere with the biosynthesis, secretion, action, or metabolism of endogenous hormones, which ultimately leads to changes in the efficacy of these hormones [120, 121] . EDs can be of natural origin (phytoestrogens, hormones, etc.) or are the result of anthropogenic activities (pharmaceuticals, dioxins, pesticides, etc.) [35] . Because most of them can interact with cell surfaces or nuclear receptors, they can cause alterations in cellular homeostasis even at extremely low concentrations, which places them in a special category of toxic substances in terms of health risks [122] . These substances are characterized by persistence and bioaccumulation properties, which are associated with the inhibition and disruption of physiological processes at the level of cells and molecular signaling pathways. The results are irreversible changes in the endocrine, cardiovascular, nervous, reproductive, and immune systems [123] . Due to their ability to interfere with estrogen, progesterone, and androgen receptors, endocrine disruptors pose extremely serious health risks in association with impairment of male reproductive functions [124] ; at the forefront of discussions is infertility due to reduced sperm count, reduced sperm quality, and inhibition of steroidogenesis [7, 125, 126] . Many xenobiotics have endocrine disrupting properties, including industrial chemicals, solvents, polycyclic aromatic hydrocarbons, plasticizers, and compounds found in detergents, cosmetics, agricultural chemicals, and pesticides, as well as natural and synthetic hormones and drugs. These chemicals are widely distributed in the environment, especially through the trophic chain and wastewater [127, 128] . At present, the attention of science in the field of EDs is focused mainly on synthetic industrial chemicals because of the absence of evolutionary adaptation to these xenobiotics [129] . These are plasticizers and other chemicals present in plastic as well as paper food packaging, which expose the human population to endocrine disruptors through food practically continuously [130] . This phenomenon has been confirmed by numerous studies, the results of which indicate increased concentrations of bisphenols, alkylphenols, phthalates, and perfluoroalkyl compounds in the saliva, urine, and milk of exposed individuals, but also in the food of daily consumption [131] . EDs also include many agrochemicals and pesticides, which have been shown endocrine disruptive activities in the living organism [132] . In particular, first-generation pesticides are a dangerous heritage for today's population because they persist in soils, aquatic sediments, bioaccumulate in invertebrate and vertebrate tissues, and move up in trophic chains [133, 134] . Numerous studies confirm that the increasing number of compounds released uncontrollably into the environment every year, which we classify as endocrine disruptors, harm animal and human health, and it is necessary to monitor their effects and consequences in organisms [7, [135] [136] [137] . As listed earlier, there are three types of contaminants (physical, biological, and chemical) based on their characteristics, origin, and MoA. This implies their various effects on the functionality of organs and gametes. The biological system has its own mechanisms to prevent the toxicity of the reproductive system. The hematotesticular barrier (HTB) regulates the migration of some toxicants from blood to the testis, mature sperm chromatin is inactive and firmly coiled, defective spermatocytes are degraded and replaced. The imperfection of the HTB consists in the influx of lipophilic compounds allowing the exposure of vulnerable spermatogonia to toxicants and compromises male fertility [74] . HTB is one of the tightest barriers between blood and tissue, dividing seminiferous epithelium into the basal and apical parts. Also known as the blood-testis barrier, HTB differs from other tissue barriers by its structure, composed of tight junctions, ectoplasmic specializations, desmosomes, and gap junctions. This highly specific and unique structure provides a favorable microenvironment for meiosis and following the development of spermatids into spermatozoa [138] . Spermatogonia are localized in the basal compartment while primary and secondary spermatocytes along with round and elongating and already elongated spermatids are situated in the apical compartment [139] . The MoA of radiation on male reproductive physiology is not clearly stated across the scientific literature. While ionizing radiation is considered dangerous due to the ability of electron liberation, non-ionizing radiation is supposedly safe as it lacks photon energy. However, non-ionizing radiation excites electrons which generates heat. It is assumed that heat generation stimulates OS production [33, 44, 140] . The spermatozoa of radiated individuals may contain microtubules with the modified arrangement, furthermore, disrupted mitochondria with up-regulated ROS generation may appear in radiation-exposed spermatozoa [141] . Excessive OS initiates adverse actions towards testicular tissue, mainly Sertoli cells, Leydig cells, and germ cells. The modulated integrity of testis indicates impaired spermatogenesis, apoptosis, and production of spermatozoa with functional and morphological damage. Moreover, male gametes may possess defected DNA [36, 37, 48, 52] . A decreased number of viable Leydig cells causes alteration of testosterone production. This variation in androgen production impairs the whole hypothalamic-pituitary-adrenal axis [142] . The significant limitation of the topic of radiation and male reproduction arises in the scientific community. Biologists evaluate the risk of radiation based solely on the biological data (mainly OS production) while physicists look at the same problematics on the level of electrons with no biological relevance. Biological pollutants affect reproduction primarily from the microbial perspective. Bacterial contamination of the urogenital tract is associated with an enhanced level of leukocytes in the semen. Leukocytes generate ROS in their combat with an infection which may cause deleterious changes of spermatozoa and the integrity of their DNA [64] . The effect of mycotoxins on male reproduction needs to be remembered as well. As shown by Zheng et al. [143] , zearalenone impairs reproductive functions. The results of in vitro administration of zearalenone were demonstrated on the Sertoli cells. Irreversible damage was detected damage to the cytoskeletal structure, namely the absence of both mitochondria and Golgi apparatus, and relocalization of vacuoles into the cytoplasm. Moreover, mycotoxins can interfere with the secretory functions of Sertoli cells. Most viruses affect only spermatozoa if at all. However, few other types target testicular and epididymal tis-sue and induce severe inflammation [68, 69] . This process includes HTB, which forms an interface between the immune system and germ cells. Strong inflammation in combination with responding cytokines modulates the functionality of HTB. Comprised barrier enables the entrance of inflammation and may result in the formation of granulomas as a response to chronic inflammation. Moreover, inflammation induces excessive ROS pro-duction causing even superior damage to the testis, germ cells, and developing spermatozoa [144] . Chemical pollutants are probably the most recognized of all pollutants. Toxic heavy metals, due to their capability to accumulate in tissues, represent a threat as chronic toxicants. The toxic mechanisms of heavy metals are defined as ion imitation, interruption of cell signaling pathways, oxidative stress, altered gene expression, apoptosis, disruption of the testis-blood barrier, and inflammation. It has been previously revealed that toxic heavy metals alter Leydig cell development and induce Leydig cell tumors. Even low doses of these toxic agents alter the walls of seminiferous tubules, thinness the germinal epithelium, thus impairing the process of spermatogenesis. Heavy metal exposure also results in the altered weight of testes, cellular degeneration, interfered androgen hormones pro-duction, dilatated and congested blood vessels, and necrosis [9, 89, 101, 145] . Elevated environmental concentrations of heavy metals are markedly displayed in the enhanced level of OS in seminal plasma [146] . Endocrine disruptors are associated mainly with imperceptible regulation of endocrine systems. The chemical structure of these pollutants mimics the natural hormones or interfere with the synthesis and secretion of the natural hormones. These agents are responsible not only for the improper development of sexual organs of the affected individual, but their effect may be also displayed on the health and sexual status of its progeny [7, 137, 147] . In addition to chemicals as polychlorinated bisphenols, organochlorine pesticides, and plasticizers and nonylphenols, it has been proposed, that heavy metals mercury, cadmium, and arsenic may also possess endocrine system modulating functions [148, 149] . Several studies report the direct disrupting effect of EDs on the germ cells and Leydig cells via excessive generation of OS [150] . Oxygen is a biogenic element for all aerobic cells. It is necessary for the maintenance of normal cell functions, however, reactive oxygen species (ROS) which are formed as a by-product of the natural metabolism of oxygen may be harmful to the cell. The deciding factor is whether there is a balance between ROS generation and antioxidants which can scavenge free radicals [151] . Free radicals may be defined as an independently existing atom or molecule with an unpaired electron. By accepting or donating the electron molecule becomes a free radical. Reactive oxygen species and reactive nitrogen species (RNS) belong among the best known and most frequent free radicals [152] . ROS represent a wide category of molecules including radicals and non-radicals. Oxygen-derived radicals comprise hydroxyl ion ( • OH), superoxide (O 2 •− ), peroxyl (LOO • ), hypochlorous acid (HOCl), etc. Non-radicals include ozone (O 3 ), singlet oxygen ( 1 O 2 ), peroxide substances (H 2 O 2 ), and others [152, 153] . Nitrogen-derived radicals are nitric oxide ( • NO), nitrous oxide (N 2 O), peroxynitrite (ONOO -), nitroxyl anion (NO − ), and peroxynitrous acid (ONOOH). Metabolism and the utilization of oxygen is an essential requirement of male gametes. Free radicals play an important role in several physiological processes of the reproductive tract [154] . Spermatozoa themselves generate ROS which is necessary for capacitation, hyperactivation, acrosome reaction, and sperm-oocyte fusion [14] . Each ejaculate contains potential sources of ROS. Often, these sources are leukocytes and neutrophils, which apply their cytotoxic mechanism against cells and pathogens and produce high levels of ROS [155] . The endogenous production of O 2 •− is caused by cell respiration. This radical is by itself relatively non-reactive, but the presence of H + leads to the formation of H 2 O 2 , which is largely involved in the lipid peroxidation of the plasma membrane [156, 157] abundant in PUFA [158, 159] . Gosalvez et al. [14] report that by the action of enzymatic antioxidants H 2 O 2 is catalyzed to water and oxygen. The external sources of ROS are associated with an individual's diet and the environment in which the individual lives. Indirect and direct effects on male infertility are induced by industrial intermediate products and wastes [160] , smoking and alcohol consumption [161] [162] [163] , obesity [164] , diabetes [165] , physical exercise [166] , psychological stress [167] , aging [168] , or the presence of increased levels of toxic heavy metals in the environment [169, 170] . NO, the major RNS, is formed of L-arginine by redox-reaction via nitric oxide synthase (NOS). This reaction necessitates oxygen and several cofactors. RNS are invaluable for numerous physiological processes in male reproduction, demonstrating their importance in intracellular signaling pathways [142] . Moreover, NO regulates the timing of the opening and closing of tight junctions of HTB thus prevents xenobiotics from entering the seminiferous tubules. Further, RNS are similarly as ROS involved in capacitation, acrosome reaction, hyperactivation, and oocyte-spermatozoa fusion. An excessive amount of RNS results in stimulation of apoptosis, inhibition of Leydig cell steroidogenesis. Clinically, RNS is often associated with leukocytospermia, varicocele, and erectile dysfunction [171] . The exposure to oxidative stress may result in adaptation (increased activity of defense mechanisms), damage to macromolecules (DNA fragmentation, protein modifications, lipid peroxidation) [172, 173] , or cell death (apoptosis, or even necrosis with a wider impact on surrounding cells and tissue) [174] . The effect of OS may be also mitigated by antioxidants by oral administration [175] [176] [177] [178] or direct supplementation of reproduction-associated cells [179] [180] [181] [182] [183] . Environmental pollutants have been determined as a risk factor to the overall health status of both humans and animals. The synergism of several contaminants and their bioaccumulation may lead to the induction of oxidative stress, resulting in cellular disruption, histological damage, endocrine disruption, and possible transgenerational effects. It is necessary to also consider antagonistic effects. The reproductive system, due to its high sensitivity, is considered the plausible marker of environmental quality that is applicable for humans as well as for various domestic and wild animals. Plenty of xenobiotics target the testis and impair their function. The male reproductive system possesses molecular repairing mechanisms that enable the limited but continuous production of viable gametes. Nevertheless, it is important to monitor and protect the environment by all means in order to maintain the fertility of humans and animals. Funding: This publication was supported by the Operational program Integrated Infrastructure within the project: Creation of nuclear herds of dairy cattle with a requirement for high health status through the use of genomic selection, innovative biotechnological methods, and optimal management of breeding, NUKLEUS 313011V387, co-financed by the European Regional Development Fund. This work was supported also by projects of the Scientific Grant Agency of the Ministry of Education, Science, Research and Sport of the Slovak Republic (projects VEGA 1/0539/18 and VEGA 1/0038/19); The Slovak Research and Development Agency (projects APVV-16-0289) and Cultural and Educational Agency of the Ministry of Education, Science, Research and Sport of the Slovak Republic (projects KEGA 010/SPU-4/2018 and KEGA 034SPU-4/2019). Data Availability Statement: Not applicable. The authors declare no conflict of interest. Urbanization, Economic Growth and Environmental Pollution: Evidence from China Copper-Induced Changes in Reproductive Functions: In Vivo and In Vitro Effects Reproductive Toxicology of Nickel-Review Assessment of the Effective Impact of Bisphenols on Mitochondrial Activity and Steroidogenesis in a Dose-Dependency in Mice TM3 Leydig Cells The Evaluation of Evidence Bisphenol A Exposure and Human Reproductive Health: A Review Identification of in Vitro Effect of 4-Octylphenol on the Basal and Human Chorionic Gonadotropin (HCG) Stimulated Secretion of Androgens and Superoxide Radicals in Mouse Leydig Cells Microplastics in the Marine Environment: Current Trends in Environmental Pollution and Mechanisms of Toxicological Profile Effects of Cadmium, Lead, and Mercury on the Structure and Function of Reproductive Organs Trace Elements Content in Semen and Their Interactions with Sperm Quality and RedOx Status in Freshwater Fish Cyprinus Carpio: A Correlation Study Acute Toxicity and Antioxidant Responses in the Water Flea Daphnia Magna to Xenobiotics (Cadmium, Lead, Mercury, Bisphenol A, and 4-Nonylphenol) Developmental Exposure of Zebrafish (Danio Rerio) to Bisphenol-S Impairs Subsequent Reproduction Potential and Hormonal Balance in Adults Free Radical and Superoxide Reactivity Detection in Semen Quality Assessment: Past, Present, and Future Concentration of Elastic System Fibers in the Corpus Cavernosum, Corpus Spongiosum, and Tunica Albuginea in the Rabbit Penis Seasonal Variations in the Blood Concentration of Selected Heavy Metals in Sheep and Their Effects on the Biochemical and Hematological Parameters Threat and Sustainable Technological Solution for Antineoplastic Drugs Pollution: Review on a Persisting Global Issue China Must Protect High-Quality Arable Land Fluid Viscoelasticity Promotes Collective Swimming of Sperm Altered Antioxidant Status and Increased Lipid Per-Oxidation in Seminal Plasma of Tunisian Infertile Men Seminal Plasma: An Essential Attribute to Spermatozoa Microelements and macroelements in seminal plasma affect oxidative balance of stallion semen Sperm Epigenetics and Influence of Environmental Factors United Nations Statistics Division-Glossary of Environment Statistics OECD-Glossary of Statistical Terms Color Pollution Microplastic Pollution in Commercial Salt for Human Consumption: A Review The Plastic in Microplastics: A Review Thermal Pollution Caused by Hydropower Plants BT-Energy Systems and Management Characterization Factors for Thermal Pollution in Freshwater Aquatic Environments Foam in the Aquatic Environment Exposure to Non-Ionizing Electromagnetic Radiation of Public Risk Prevention Instruments Threatens the Quality of Spermatozoids When Theory and Observation Collide: Can Non-Ionizing Radiation Cause Cancer? What Is an Endocrine Disruptor? The Thermal Effect of 2.45 GHz Microwave Radiation on Rat Testes Melatonin Attenuates Radiofrequency Radiation (900 MHz)-Induced Oxidative Stress, DNA Damage and Cell Cycle Arrest in Germ Cells of Male Swiss Albino Mice Cytokines Produced by Microwave-radiated Sertoli Cells Interfere with Spermatogenesis in Rat Testis Effect of Long-Term Exposure of 2.4 GHz Radiofrequency Radiation Emitted from Wi-Fi Equipment on Testes Functions The Effect of Whole Body Exposure of 50 GHz Microwave Radiation on Sperm Counts in Rats Long-Term Effects of 900 MHz Radiofrequency Radiation Emitted from Mobile Phone on Testicular Tissue and Epididymal Semen Quality Radio Frequency Electromagnetic Radiation (RF-EMR) from GSM (0.9/1.8 GHz) Mobile Phones Induces Oxidative Stress and Reduces Sperm Motility in Rats Microwave Radiation (2.45 GHz)-Induced Oxidative Stress: Whole-Body Exposure Effect on Histopathology of Wistar Rats In Vitro Effects of Radiofrequency Electromagnetic Waves on Bovine Spermatozoa Motility Influence of a 50 Hz Extra Low Frequency Electromagnetic Field on Spermatozoa Motility and Fertilization Rates in Rabbits Effects of 50 Hz Extremely Low Frequency Magnetic Field on the Morphology and Function of Boar Spermatozoa Capacitated In Vitro Comparative Proteomics Reveals the Underlying Toxicological Mechanism of Low Sperm Motility Induced by Iron Ion Radiation in Mice Protective Role of Hesperidin against γ-Radiation-Induced Oxidative Stress and Apoptosis in Rat Testis Atorvastatin Mitigates Testicular Injuries Induced by Ionizing Radiation in Mice Protection of Murine Spermatogenesis Against Ionizing Radiation-Induced Testicular Injury by a Green Tea Polyphenol Proteome Analysis for Profiling Infertility Markers in Male Mouse Sperm after Carbon Ion Radiation Wuzi Yanzong Pill, a Chinese Polyherbal Formula, Alleviates Testicular Damage in Mice Induced by Ionizing Radiation Site-Specific Changes in Zinc Levels in the Epididymis of Rats Exposed to Ionizing Radiation Effects of Bacterial Pollution Caused by a Strong Typhoon Event and the Restoration of a Recreational Beach: Transitions of Fecal Bacterial Counts and Bacterial Flora in Beach Sand Respiratory Syncytial Virus Bronchiolitis, Weather Conditions and Air Pollution in an Italian Urban Area: An Observational Study Biological Pollutants and Biological Pollution-An Increasing Cause for Concern The Protective Effect of Stilbenes Resveratrol and Pterostilbene Individually and Combined with Mycotoxin Citrinin in Human Adenocarcinoma HT-29 Cell Line In Vitro Microbial Contamination of Fresh Produce: What, Where, and How? Microbial Contamination of Drinking Water and Human Health from Community Water Systems Distribution Characteristics, Growth, Reproduction and Transmission Modes and Control Strategies for Microbial Contamination in HVAC Systems: A Literature Review Screening for Sexually Transmitted Infection Pathogens in Semen Samples Influence of Urogenital Infections and Inflammation on Semen Quality and Male Fertility Male Urogenital Infections: Impact of Infection and Inflammation on Ejaculate Parameters Oxidative Stress, Spermatozoa and Leukocytic Infiltration: Relationships Forged by the Opposing Forces of Microbial Invasion and the Search for Perfection The Incidence and Effect of Bacteriospermia and Elevated Seminal Leukocytes on Semen Parameters The Breadth of Viruses in Human Semen Semen Impairment and Occurrence of SARS-CoV-2 Virus in Semen after Recovery from COVID-19 Viral Threat to Male Fertility Viruses in the Mammalian Male Genital Tract and Their Effects on the Reproductive System. Microbiol Sperm Viral Infection and Male Infertility: Focus on HBV Presence of Human Papillomavirus DNA in Testicular Biopsies from Nonobstructive Azoospermic Men Viral Pathogenesis of SARS-CoV-2 Infection and Male Reproductive Health Chemical Contaminants Human Spermatozoa: Maturation, Capacitation and Abnormalities; Human Reproductive System-Anatomy, Roles, and Disorders Series Zinc Affects Rabbit Spermatozoa in Vitro: Effects on Motility and Viability Assessment of Environmental and Health Risks in Former Polymetallic Ore Mining and Smelting Area, Slovakia: Spatial Distribution and Accumulation of Mercury in Four Different Ecosystems Human Exposure to Heavy Metals and Possible Public Health Risks via Consumption of Wild Edible Mushrooms from Slovak Paradise National Park Molecular and Cellular Mechanisms of Cadmium Carcinogenesis Quantification of Trace Elements by Sector Field Inductively Coupled Plasma Mass Spectrometry in Urine, Serum, Blood and Cerebrospinal Fluid of Patients with Parkinson's Disease Dietary Toxicity of Metals in Aquatic Animals: Recent Studies and Perspectives Advances in Metal-Induced Oxidative Stress and Human Disease Heavy Metal Poisoning and Cardiovascular Disease Blood Concentration of Copper, Cadmium, Zinc and Lead in Horses and Its Relation to Hematological and Biochemical Parameters Changes in the Testis and Epididymis of Rabbits after an Intraperitoneal and Peroral Administration of Cadmium Protective Effect of Polygonatum Sibiricum against Cadmium-Induced Testicular Injury in Mice through Inhibiting Oxidative Stress and Mitochondria-Mediated Apoptosis Mechanism of Cadmium Poisoning on Testicular Injury in Mice Oral Administration of Cadmium Depletes Intratesticular and Epididymal Iron Levels and Inhibits Lipid Peroxidation in the Testis and Epididymis of Adult Rats Cadmium Induced Inflammation and Apoptosis of Porcine Epididymis via Activating RAF1/MEK/ERK and NF-KB Pathways Effects of Subchronic Exposure to Cadmium and Diazinon on Testis and Epididymis in Rats Cadmium Chloride-Induced Testicular Toxicity in Male Wistar Rats; Prophylactic Effect of Quercetin, and Assessment of Testicular Recovery Following Cadmium Chloride Withdrawal The Impact of Lead and Cadmium on Selected Motility, Prooxidant and Antioxidant Parameters of Bovine Seminal Plasma and Spermatozoa Protective Role of Glutamine against Cadmium-Induced Testicular Dysfunction in Wistar Rats: Involvement of G6PD Activity Determination of Cadmium Induced Acute and Chronic Reproductive Toxicity with Raman Spectroscopy Cadmium Toxicity at Low Concentration on Rabbit Spermatozoa Motility, Morphology and Membrane Integrity In Vitro Chronic Exposure to Cadmium Induces Differential Methylation in Mice Spermatozoa Impact of Silymarin on Cadmium-induced Apoptosis in Human Spermatozoa The Effect of Ferulic Acid against Lead-Induced Oxidative Stress and DNA Damage in Kidney and Testes of Rats Protective Effect of Betaine against Lead-induced Testicular Toxicity in Male Mice The Protective Effect of Costus Afer Ker Gawl Aqueous Leaf Extract on Lead-Induced Reproductive Changes in Male Albino Wistar Rats Thymoquinone Attenuates Testicular and Spermotoxicity Following Subchronic Lead Exposure in Male Rats: Possible Mechanisms Are Involved Protective Effect of Abutilon Indicum against Lead-Induced Reproductive Toxicity in Male Wistar Rats Silver, Tin, Mercury, Indium and Bismuth on Human Sperm Creatine Kinase Activity: A Presumable Mechanism for Men Infertility Detection of Lead-Induced Oxidative Stress in the Rat Epididymis by Chemiluminescence Impaired Hypothalamic-Pituitary-Testicular Axis Activity, Spermatogenesis, and Sperm Function Promote Infertility in Males with Lead Poisoning Vitamin E Modifies the Ultrastructure of Testis and Epididymis in Mice Exposed to Lead Intoxication Lead Exposure Reduces Sperm Quality and DNA Integrity in Mice Solanum Betaceum Extract as a Protective on Spermatozoa Morphology of Mice Exposed to Lead Acetate Protective Effect of Rutin on Mercuric Chloride-induced Reproductive Damage in Male Rats Ziziphus Spina-Christi Leaf Extract Attenuates Mercury Chloride-Induced Testicular Dysfunction in Rats Interventions of Aqueous Extract of Solanum Melongena Fruits (Garden Eggs) on Mercury Chloride Induced Testicular Toxicity in Adult Male Wistar Rats Role of A-tocopherol and Lactobacillus Plantarum in the Alleviation of Mercuric Chloride-induced Testicular Atrophy in Rat's Model: Implication of Molecular Mechanisms Mercury-Induced Alterations in Rat Kidneys and Testes In Vivo Down-Regulation of CatSper 1 and CatSper 2 Genes by Lead and Mercury Disruption of Estrogen Receptor Signaling and Similar Pathways in the Efferent Ductules and Initial Segment of the Epididymis Egg White-Derived Peptides Prevent Male Reproductive Dysfunction Induced by Mercury in Rats Effects of in Vitro Exposure of Mercury on Sperm Quality and Fertility of Tropical Fish Cyprinus carpio L Urine Mercury Levels Correlate with DNA Methylation of Imprinting Gene H19 in the Sperm of Reproductive-Aged Men Mechanism of Action of Mercury on Sperm Morphology, Adenosine Triphosphate Content, and Motility in Perca fluviatilis (Percidae; Teleostei) Mercury at Environmental Relevant Levels Affects Spermatozoa Function and Fertility Capacity in Bovine Sperm A Path Forward in the Debate over Health Impacts of Endocrine Disrupting Chemicals How Many Chemicals Are in Use Today? Endocrine-Disrupting Chemicals: An Endocrine Society Scientific Statement Endocrine Disruptors in Bottled Mineral Water: Total Estrogenic Burden and Migration from Plastic Bottles Molecular Mechanism(s) of Endocrine-Disrupting Chemicals and Their Potent Oestrogenicity in Diverse Cells and Tissues That Express Oestrogen Receptors Endocrine Disrupters-Potential Modulators of the Immune System and Allergic Response. Allergy Eur Endocrine-Disrupting Chemicals Rapidly Affect Intercellular Signaling in Leydig Cells Male Reproduction: One of the Primary Targets of Bisphenol The Effects of Endocrine Disrupting Chemicals on Biomarkers of Inflammation Produced by Lipopolysaccharide Stimulated RAW264.7 Macrophages Endocrine Modulators in the Food Chain and Environment Endocrine Disruptors in Food: Impact on Gut Microbiota and Metabolic Diseases Endocrine Disruptor Compounds (EDCs) and Agriculture: The Case of Pesticides Estrogenicity of Pyrethroid Insecticide Metabolites Finding Minimal Herbicide Concentrations in Ground Water? Try Looking for Their Degradates The Benefits of Pesticides to Mankind and the Environment The PERICLES Research Program: An Integrated Approach to Characterize the Combined Effects of Mixtures of Pesticide Residues to Which the French Population Is Exposed The Use and Acceptance of Other Scientifically Relevant Information (OSRI) in the U.S. Environmental Protection Agency (EPA) Endocrine Disruptor Screening Program Parallel Effect of 4-Octylphenol and Cyclic Adenosine Monophosphate (CAMP) Alters Steroidogenesis, Cell Viability and ROS Production in Mice Leydig Cells The Blood-Testis Barrier and Its Implications for Male Contraception The Mammalian Blood-Testis Barrier: Its Biology and Regulation Effects of Radiofrequency Electromagnetic Waves (RF-EMW) from Cellular Phones on Human Ejaculated Semen: An in Vitro Pilot Study Evidence for Mobile Phone Radiation Exposure Effects on Reproductive Pattern of Male Rats: Role of ROS Henkel, R. Radiations and Male Fertility Zearalenone Impairs the Male Reproductive System Functions via Inducing Structural and Functional Alterations of Sertoli Cells The Blood-Epididymis Barrier and Inflammation. Spermatogenesis 2014, 4, e979619 Lead Accumulation, Oxidative Damage and Histopathological Alteration in Testes and Accessory Glands of Freshwater Crab, Sinopotamon Henanense, Induced by Acute Lead Exposure Relationship between trace element concentrations and spermatozoa quality in rabbit semen Resveratrol Attenuates Hydrogen Peroxide-Induced Oxidative Stress in TM3 Leydig Cells in Vitro Endocrine Disrupting Chemicals: Exposure, Effects on Human Health, Mechanism of Action, Models for Testing and Strategies for Prevention The Effects of Metals as Endocrine Disruptors The Effect of Environmental Contaminants on Testicular Function Nitric Oxide and Oxygen Radicals: A Question of Balance Inorganic Arsenic Compounds Cause Oxidative Damage to DNA and Protein by Inducing ROS and RNS Generation in Human Keratinocytes Measurement, and Prevention of Oxidative Stress in Male Reproductive Physiology The Role of Free Radicals and Antioxidants in Reproduction Relationship to Sperm Deoxyribonucleic Acid Integrity in Patients Evaluated for Male Factor Infertility Etiologies of Sperm Oxidative Stress Reactive Oxygen Species and Human Spermatozoa: Physiology and Pathology Polyunsaturated Fatty Acids in Male Ruminant Reproduction-A Review Reactive Oxygen Species and Sperm Cells The Effect of Nonylphenol on the Motility and Viability of Bovine Spermatozoa in Vitro Decline of Semen Quality and Increase of Leukocytes with Cigarette Smoking in Infertile Men Effects of Ethanol Consumption on Chromatin Condensation and DNA Integrity of Epididymal Spermatozoa in Rat Leukocytes and Oxidative Stress: Dilemma for Sperm Function and Male Fertility Epigenetic Effects of Male Obesity on Sperm and Offspring Protective Effect of Berberine on Reproductive Function and Spermatogenesis in Diabetic Rats via Inhibition of ROS/JAK2/NFκB Pathway Effect of Different Intensities of Swimming Exercise on Testicular Oxidative Stress and Reproductive Dysfunction in Mature Male Albino Wistar Rats Effect of Psychological Stress on the L-Arginine-Nitric Oxide Pathway and Semen Quality. Braz Free Radical Theory of Aging: Implications in Male Infertility The Role of Physiologically Occurring Elements in Semen and Effect of Heavy Metals on Semen Concentration of Copper, Iron, Zinc, Cadmium, Lead, and Nickel in Boar Semen and Relation to the Spermatozoa Quality Role of Reactive Nitrogen Species in Male Infertility Reactive Oxygen Species and Protein Modifications in Spermatozoa Causes and Consequences of Oxidative Stress in Alzheimer's Disease. Free Radic Antioxidants, and Impact of the Oxidative Status in Male Reproduction Effects of Dietary Plant Polyphenols and Seaweed Extract Mixture on Male-Rabbit Semen: Quality Traits and Antioxidant Markers Chemical Analysis of Lepidium meyenii (Maca) and Its Effects on Redox Status and on Lepidium meyenii (Maca) in Male Reproduction Dietary Supplementation with Natural Extracts Mixture: Effects on Reproductive Performances, Blood Biochemical and Antioxidant Parameters in Rabbit Does High Taurine Concentrations Negatively Effect Stallion Spermatozoa Parameters in Vitro. Acta Fytotech Lippia citriodora (Verbascoside) Extract Supplementation: Effect on Rabbit Semen Quality In Vivo and In Vitro Effect of Taurine on Turkey (Meleagris gallopavo) Spermatozoa Viability and Motility Low Taurine Concentrations Possitively Affect Rabbit Spermatozoa Properties in Later Time Intervals Curcumin Has Protective and Antioxidant Properties on Bull Spermatozoa Subjected to Induced Oxidative Stress