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Papers
61,005 resultsShowing papers similar to Microplastics in ovarian function and ozone-based mitigation strategies: Emerging evidence and translational implications
ClearExposição De Microplásticos E Nanoplásticos Ao Tecido Ovariano: Uma Revisão Integrativa
This integrative review examines the impact of micro- and nanoplastics on female ovarian tissue, synthesizing animal model studies showing damage to follicular structures, increased oxidative stress, and disrupted reproductive hormone signaling.
A review of the impact of micro‐ and nanoplastics on female reproduction: What we know and gaps in knowledge
This review examines what is known about how micro- and nanoplastics affect female reproductive health. Animal studies show these particles accumulate in ovarian tissue, disrupt hormones, and cause oxidative stress, leading to hormonal imbalances and ovarian damage, though research in humans is still limited.
Exposição De Microplásticos E Nanoplásticos Ao Tecido Ovariano: Uma Revisão Integrativa
This integrative review (in Portuguese) examines published evidence on the effects of micro- and nanoplastic exposure on female ovarian tissue morphology, finding disrupted folliculogenesis, oxidative stress, and hormonal interference reported across animal model studies.
Implication of nano and microplastics in reproduction: understanding oocyte vulnerability
This review examined how nano- and microplastics (NMPs) compromise oocyte quality and female reproductive function, finding that NMPs trigger oxidative stress, disrupt meiotic spindle assembly, impair mitochondrial function, and cause DNA damage in eggs. The findings identified the oocyte as particularly vulnerable to NMP exposure, with implications for fertility and reproductive health.
Concerning influences of micro/nano plastics on female reproductive health: focusing on cellular and molecular pathways from animal models to human studies
This review summarizes research showing that micro- and nanoplastics can harm the female reproductive system in multiple ways, from reducing ovarian reserves and disrupting hormone balance to accumulating in the placenta and breast milk. Animal studies show these particles trigger oxidative stress and inflammation in reproductive tissues, and human studies have confirmed their presence in placental tissue and infant feces, raising concerns about effects on fertility and fetal development.
Reproductive toxicity and related mechanisms of micro(nano)plastics in terrestrial mammals: Review of current evidence.
This review of terrestrial mammal studies found that micro- and nanoplastics induce reproductive toxicity through oxidative stress, inflammation, endocrine disruption, and DNA damage, affecting both male and female fertility. In males, effects include blood-testis barrier disruption and impaired spermatogenesis, while females show compromised oocyte maturation, ovarian fibrosis, and diminished ovarian reserve, with particles also capable of crossing the maternal-fetal interface.
Plastic Particles and Female Fertility: Pathways, Toxicity, and Analytical Challenges
This review examines the pathways, toxicity mechanisms, and analytical challenges associated with microplastic and nanoplastic impacts on female fertility. Evidence from animal studies indicates that these particles can accumulate in ovaries and placental tissue, inducing oxidative stress, inflammation, and granulosa cell death that diminishes ovarian reserve. The study notes that microplastics have been confirmed in human placentas and umbilical cord blood, and may disrupt the hormonal axis governing reproduction.
Impact of microplastics on female reproductive health: insights from animal and human experimental studies: a systematic review
This systematic review of 15 experimental studies found that microplastic exposure significantly impairs ovarian function, decreases fertility rates, and disrupts hormone levels in female subjects. Several studies also reported negative effects on embryo development and offspring health, though study quality varied and more rigorous research is needed to confirm mechanisms.
Size- and hydrophobicity-dependent accumulation of microplastics in follicular fluid is linked to impaired ovarian reserve in women undergoing medically assisted reproduction
Researchers measured microplastic concentrations in follicular fluid and blood from women undergoing fertility treatment and found that nearly all samples contained microplastics. Higher microplastic concentrations in follicular fluid were significantly associated with reduced oocyte yield and lower odds of pregnancy, with evidence suggesting that certain hydrophobic polymers selectively accumulate in the ovary.
Reproductive toxicity of microplastics role of oxidative stress in cellular and molecular damage
This review synthesizes in vitro, in vivo, and epidemiological evidence on how microplastics cause reproductive toxicity, focusing on oxidative stress as the central mechanism. MPs infiltrate reproductive tissues, generate reactive oxygen species, and disrupt gametogenesis, hormone regulation, and embryonic development across multiple species.
"Unseen Dangers: The Effects of Micro- and Nanoplastics on Human Reproductive Health - A Narrative Review"
This review examines the effects of micro- and nanoplastics on human reproductive health, covering evidence from in vitro, animal, and epidemiological studies showing that plastic particles can disrupt hormone signaling, sperm function, ovarian development, and placental integrity.
Reproductive and developmental implications of micro- and nanoplastic internalization: Recent advances and perspectives
This systematic review documented the detection of micro- and nanoplastics in human semen, placenta, and ovarian follicular fluid, and found evidence linking exposure to impaired sperm quality, disrupted ovarian function, and adverse pregnancy outcomes. In animal models, MNPs caused developmental toxicity and transgenerational effects, with oxidative stress, inflammation, and epigenetic modification identified as key mechanisms.
Mechanistic insights into microplastic-induced reproductive toxicity in aquatic organisms: A comprehensive review
This review summarizes how microplastics cause reproductive harm in aquatic organisms by disrupting hormones, triggering oxidative stress, and interfering with cell death pathways. These effects lead to reduced fertility, abnormal egg and sperm development, and changes that can pass to future generations. Since microplastics accumulate through the food chain, these reproductive effects in aquatic life could have broader implications for ecosystem health and the seafood that humans consume.
Toxicological effects of micro/nano-plastics on human reproductive health: A review
This review summarizes research on how micro- and nanoplastics affect human reproductive health in both men and women. Evidence from animal and lab studies shows that these particles can accumulate in reproductive organs, disrupt hormones, damage eggs and sperm, and cause inflammation and oxidative stress. While human studies are still limited, the growing body of evidence suggests that microplastic exposure is a potential threat to fertility that warrants further investigation.
Microplastics: unraveling the signaling pathways involved in reproductive health
This review examines the effects of microplastics on male and female reproductive health, focusing on the metabolic pathways involved in compromised gamete quality, toxicity, apoptosis, and DNA damage. Evidence indicates that microplastics can increase oxidative stress leading to developmental abnormalities, epigenetic changes, and reduced gamete quality, though research on mammalian and human reproductive effects remains limited compared to studies in aquatic organisms.
Microplastics are present in women’s and cows’ follicular fluid and polystyrene microplastics compromise bovine oocyte function in vitro
Researchers detected microplastics in follicular fluid from both women and cows and showed that polystyrene microplastics disrupt oocyte development, providing the first evidence that microplastics can penetrate reproductive barriers and potentially contribute to the global decline in fertility.
The effects of exposure to microplastics on female reproductive health and pregnancy outcomes: A systematic review and meta-analysis
This meta-analysis pools data from multiple studies to assess how microplastic exposure affects female reproductive health and pregnancy outcomes. The findings suggest that microplastic accumulation may be linked to adverse effects on fertility and pregnancy, highlighting an important and underexplored area of concern for women's health.
Microplastics and nanoplastics in follicular fluid are associated with diminished ovarian reserve: clinical and molecular insights
Researchers found that microplastics and nanoplastics present in follicular fluid are associated with diminished ovarian reserve in women. The study provides evidence suggesting that exposure to these particles may harm female ovarian function. The findings point to the environment-gut-ovarian axis as a potential pathway through which micro- and nanoplastic exposure could contribute to reproductive health concerns.
The emerging risk of microplastics and nanoplastics on the microstructure and function of reproductive organs in mammals: A systematic review of preclinical evidence
Preclinical evidence from 12 studies shows micro- and nanoplastics accumulate in mammalian gonads, causing dose-dependent damage including seminiferous degeneration, sperm malformation, reduced follicular growth, and impaired hormone levels through pro-oxidant and pro-inflammatory mechanisms.
Microplastics are present in women’s and cows’ follicular fluid and polystyrene microplastics compromise bovine oocyte function in vitro
Researchers detected microplastics in both women's and cows' follicular fluid for the first time, and showed that polystyrene microplastics impair bovine oocyte function in vitro, raising concern that environmental microplastic exposure may be contributing to declining reproductive health.
Microplastics and human fertility: A comprehensive review of their presence in human samples and reproductive implication
This review examines the growing evidence linking microplastic and nanoplastic exposure to potential effects on human fertility. Researchers noted that these tiny plastic particles have been detected in blood, placenta, and seminal fluid, suggesting continuous systemic exposure and the ability to cross key biological barriers. Animal studies indicate that microplastics may affect reproductive health through oxidative stress, hormonal disruption, and tissue damage, though more standardized human research is needed.
Characterization of microplastics in human follicular fluid and assessment of their potential impact on mouse oocyte maturation in vitro
Scientists found microplastics in human follicular fluid, the liquid surrounding eggs in the ovaries, after analyzing samples from 19 women. When they tested how these particles affect egg development in mice, they found that certain types of microplastics reduced the ability of eggs to mature properly, raising concerns about potential effects on fertility.
Adverse health effects and mechanisms of microplastics on female reproductive system: a descriptive review
This review describes how microplastics, particularly polystyrene, can reach and accumulate in the female reproductive system through ingestion, inhalation, and skin contact. Animal studies suggest these particles may disrupt ovarian function, hormone balance, and fertility through oxidative stress and inflammation. While human evidence is still emerging, the research raises important questions about microplastic exposure and women's reproductive health.
Plastic pollution in human reproduction: should we worry?
Researchers reviewed evidence that micro- and nanoplastics can cross the placenta, enter amniotic fluid, and accumulate in reproductive tissues in both men and women. Animal and cell studies suggest these particles may reduce egg and sperm quality and harm fetal development, though most experiments use higher doses than people realistically encounter.