Search Results (1,619)

With the continuous advancement in reproductive biology, oocyte vitrification has become a critical technology for preserving female germplasm and protecting it from environmental disruptions. This technique also eliminates temporal and spatial constraints in animal embryo engineering research. However, during the vitrification of animal oocytes, exposure to low temperatures and high concentrations of cryoprotectants can cause various forms of damage, including cytoskeletal disruption, spindle abnormalities, mitochondrial dysfunction, apoptosis, oxidative stress and epigenetic modifications. These issues are now understood to severely restrict the subsequent developmental competence of oocytes, resulting in lower cleavage and blastocyst formation rates than those of fresh oocytes. Currently, the mechanisms of cryodamage in vitrified oocytes remain poorly understood, and standardized strategies to enhance vitrification efficiency have yet to be firmly established. This review provides a formal overview of the physiological factors underlying oocyte sensitivity to vitrification, alongside the mechanisms of cryodamage and the variables influencing post-thaw survival and reproductive success. It evaluates strategies for mitigating vitrification-induced stress, compares interspecies differences, and addresses current research limitations. By identifying future directions, this review offers new insights for optimizing mammalian oocyte cryopreservation techniques. Full article

Background/Objectives: Artificial intelligence (AI) models are increasingly applied across the assisted reproductive technology (ART) workflow, including male-factor assessment, ovarian stimulation, endometrial receptivity evaluation, embryo selection and prediction of pregnancy outcomes. However, many systems remain difficult to interpret, raising concerns regarding transparency, clinical integration and patient communication. Explainable artificial intelligence (XAI) aims to address these limitations by making model behavior more accessible to clinicians and embryologists. This review aimed to provide a narrative, concept-driven synthesis of how XAI has been implemented in ART, to critically examine methodological quality and clinical relevance and to outline priorities for responsible translation into practice. Methods: A structured narrative review was conducted using PubMed/MEDLINE as the primary database, supplemented by targeted reference-list screening of key primary studies and recent cross-disciplinary reviews relevant to AI in ART. Studies were curated and classified according to stage of the ART workflow, data modality, model family, explanation technique and validation strategy. Methodological features, performance reporting and implementation considerations were qualitatively appraised. Results: Most XAI applications in ART fall into two dominant categories: (i) feature-attribution methods such as SHAP and LIME applied to tabular clinical and laboratory data and (ii) saliency-based approaches, including Grad-CAM and related techniques, applied to embryo and ultrasound imaging. These methods can improve transparency and support counselling by clarifying which variables or image regions influence predictions. However, the majority of studies are retrospective and single centre, with limited external validation and heterogeneous outcome definitions, often prioritising clinical pregnancy over live birth. Calibration, decision-analytic evaluation and prospective assessment remain uncommon. XAI outputs are frequently interpreted as biologically causal despite being derived from observational data, highlighting the need for cautious clinical framing. Conclusions: XAI in ART has progressed from proof-of-concept demonstrations to early clinically oriented tools, but robust validation, standardised reporting and thoughtful workflow integration are still needed. Explanations can enhance auditability and communication, yet they do not compensate for methodological weakness. Future progress will depend on higher-quality multi-centre data, evaluation beyond discrimination metrics and governance frameworks that ensure transparency, fairness and sustained performance in real-world practice. Full article

Wireless sensor networks (WSNs) have increasing demand on lightweight, efficient, and secure encryption techniques for devices with limited resources, since traditional algorithms require high computation which make them impractical. This preliminary study presents an encryption algorithm based on chaos designed for transmitting short data, using the Lorenz system and Euler’s method for computation. It is combined with a synchronization model based on data array. It inserts iteration parameters within the ciphertext to ensure consistent key reproduction while decrypting. Within the broader context of e-health data streams, encryption efficiency is critical: continuous ECG signals generate large volumes of data that challenge real-time secure transmission, whereas individual blood pressure readings are far smaller and lightweight. While this work delimits its scope to short, low-power transmissions, simulations and hardware implementation on an nRF chip using the Enhanced ShockBurst (ESB) protocol demonstrated efficiency, with the lowest encryption speed of 0.154 ms for a 1-byte payload. Security analysis using the NIST Statistical Test Suite confirmed high statistical randomness of the generated keystream, and theoretical key-space analysis supports robustness. By focusing on short-stream encryption in preliminary form, the scheme contributes toward inclusive secure communication technologies for resource-constrained IoT healthcare systems and diverse user populations. Full article

Embryos being treated using assisted reproductive technology (ART) are unavoidably exposed to physical stressors, thus producing reactive oxygen species (ROS) which trigger mitophagy to support embryonic development. However, the mechanisms underlying the regulation of mitophagy in early embryonic development remain largely unexplored. Here, we found that Mucin 1 (MUC1) exhibited a uniform distribution in both mouse and human oocytes, and its expression peaked at the blastocyst stage. Further analysis revealed that Muc1 knockout impairs blastocyst formation in vitro. Correspondingly, Muc1 knockout led to the accumulation of mitochondrial reactive oxygen species (mtROS) and a reduction in phosphatase and tensin homolog (PTEN)-induced putative kinase 1 (PINK1)/Parkinson protein 2 (PARK2/Parkin)-dependent mitophagy. Stimulation of mitophagy via low-dose carbonyl cyanide 3-chlorophenylhydrazone (CCCP) treatment rescued the blastocyst formation defect in Muc1-null embryos. Vitamin C supplementation effectively scavenged mtROS and restored developmental competence. Together, our findings establish that MUC1 safeguards early embryonic development by promoting mitophagy to decrease mtROS levels in vitro. Moreover, vitamin C could compensate for Muc1 deficiency by eliminating mtROS. This study not only identified a new function of MUC1 in protecting early embryonic development in vitro, but also revealed a novel mechanism of mitophagy regulation in early embryos, which has potential applications for ART. Full article

Age-related decline in oocyte quality is closely associated with mitochondrial dysfunction and oxidative imbalance, which disrupt redox-sensitive meiotic signaling and compromise embryo developmental competence. Rescue in vitro maturation (r-IVM) enables the utilization of immature oocytes retrieved during conventional in vitro fertilization (IVF) cycles. However, the developmental potential of r-IVM oocytes remains limited, particularly in women of advanced maternal age. This study evaluated whether transient caffeine supplementation during r-IVM improves the developmental competence of immature human oocytes in clinical assisted reproduction technology cycles. Immature oocytes obtained during conventional IVF were cultured with or without short-term caffeine exposure during r-IVM prior to standard culture conditions. After maturation, metaphase II oocytes underwent intracytoplasmic sperm injection, and embryonic development was assessed by fertilization rate, day 3 good-quality embryo formation, and blastocyst development. Although caffeine supplementation did not significantly affect nuclear maturation rates, it significantly increased fertilization efficiency and the proportion of good-quality embryos compared with controls. These effects were most pronounced in women aged ≥ 37 years. Time-lapse morphokinetic analysis further revealed more synchronized developmental kinetics in embryos derived from caffeine-treated oocytes, resembling those derived from in vivo-matured oocytes. Collectively, these findings suggest that transient caffeine exposure during r-IVM enhances post-fertilization developmental competence. The underlying mechanisms remain to be elucidated, and future studies are required to determine whether redox-sensitive meiotic pathways and mitochondrial function are involved. Full article

Background/Objectives: Infertility affects about 17.5% of people globally, with higher rates in women. Despite advances in assisted reproductive technologies, success remains limited. Endometrial scratching (ES) is proposed to enhance implantation by altering cytokines and gene expression, but evidence is conflicting. Methods: A systematic search of the PubMed, Cochrane Library, and Scopus databases was conducted according to the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines. Eight randomized controlled trials (RCTs) involving women undergoing in vitro fertilization (IVF) or intracytoplasmic sperm injection (ICSI), with ES performed in the luteal phase of the cycle preceding IVF or ICSI, were included. Results: The meta-analysis included 3210 patients and 1445 clinical pregnancies (754 in the ES group and 691 in the control group). In the ES group, a significantly higher clinical pregnancy rate (CPR) (RR 1.09, 95% CI 1.01–1.18, p = 0.02) was revealed. Pooled data from six studies reporting live birth rates (1268 births) showed a significant increase in the LBR after ES (RR 1.12, 95% CI 1.03–1.22, p = 0.01). The ongoing pregnancy rate (OPR) was also statistically significant in the ES group (RR 1.13, 95% CI 1.01–1.26, p = 0.03). Conclusions: This meta-analysis shows a small but statistically significant and consistent positive effect of ES on the LBR, CPR, and OPR in women undergoing IVF or ICSI, with a modest but measurable absolute benefit of approximately 4–5 additional events per 100 individuals. This procedure may particularly benefit patients with impaired endometrial receptivity, potentially enhancing reproductive outcomes while reducing the time and cost required to achieve a successful pregnancy. Further research is warranted to optimize its use and identify patients most likely to benefit. Full article

Per- and polyfluoroalkyl substances (PFAS) are a class of synthetic chemicals notable for their high persistence and extensive applications. With the advancement of detection technologies in recent years, PFAS have been frequently identified in environmental media and human biological samples, raising significant global concerns about their potential health risks. PFAS exhibit distinctive toxicokinetic behaviors, including efficient absorption, strong protein binding, limited metabolism, and slow excretion, which lead to prolonged biological half-lives and considerable bioaccumulation in humans. These properties contribute to a range of adverse health outcomes, such as endocrine disruption, immune suppression, liver damage, reproductive toxicity, carcinogenic potential, and cardiovascular disease. This review synthesizes evidence on PFAS-associated health risks from a multisystem, multitarget perspective, elucidating the key molecular pathways involved, thereby providing a scientific basis for understanding their complex toxicological effects and for developing targeted prevention and control strategies. Future research should prioritize characterizing the toxicological profiles of individual PFAS compounds, evaluating the health impacts of combined (mixture) exposures, and assessing risks associated with chronic, low-dose exposure to support the development of public health strategies and regulatory decisions. Full article

Proteostasis, defined as the coordinated regulation of protein synthesis, folding, trafficking, and degradation, is essential for maintaining cellular integrity and supporting normal development. During reproduction and early life stages, efficient proteostasis is crucial for gamete quality, successful fertilization, embryonic development, and neurodevelopmental outcomes. Increasing evidence suggests that impaired proteostasis contributes to infertility and may be intertwined with biological vulnerabilities associated with assisted reproductive technologies [ARTs]. This review provides an integrative perspective on the role of disrupted proteostasis in infertility, ART procedures, and neurodevelopmental differences [NDD]. We review epidemiological and molecular findings indicating proteostasis failure in both male and female infertility, with particular emphasis on molecular chaperones. Among these, heat shock protein 60 [Hsp60] is discussed as a central mediator linking mitochondrial function, protein quality control, and reproductive competence. We further highlight that ART procedures coincide with sensitive periods of epigenetic reprogramming and proteostasis regulation during early embryogenesis, indicating that disturbances in proteostasis may affect epigenetic stability and subsequent neurodevelopmental outcomes. In addition, this review emphasizes the importance of proteoforms and proteome complexity as critical determinants of reproductive success and neurodevelopmental robustness in the context of ART. Finally, we discuss the potential of proteomic and chaperone-based biomarkers as emerging tools to optimize ART strategies, improve gamete and embryo selection, and enhance risk assessment and clinical outcomes. The current review underscores proteostasis as a fundamental yet underrecognized mechanism linking reproductive biology, ART outcomes, and long-term neurodevelopment while highlighting future directions for translational investigations. Full article

Ovarian function relies on a network of well-coordinated molecular mechanisms that regulate follicular development, oocyte maturation, ovulation, and corpus luteum function. When these processes are disrupted, infertility can result. Extracellular matrix (ECM) remodeling represents a central regulatory component in these processes and is essential for follicle rupture and oocyte release. This mechanism involves metalloproteinases (MMPs), mainly MMP-2 and MMP-9, which degrade the ECM and allow the necessary structural changes. Other ECM-modulating proteases, such as ADAM and ADAMTS families, also contribute to this process. Their activity is tightly regulated by tissue inhibitors of metalloproteinases (TIMPs), ensuring that tissue remodeling occurs in a controlled manner. Disruption of the balance between MMPs and TIMPs increases the risk of infertility-related conditions such as polycystic ovary syndrome (PCOS), endometriosis, luteinizing hormone (LH) deficiency syndrome, and ovarian aging. In addition to the ECM, other factors, including intracellular signaling pathways, oxidative stress (OS), and mitochondrial function, contribute to ovarian physiology and directly affect oocyte quality and viability. This narrative review focuses on the molecular mechanisms governing ovarian function, with particular emphasis on the remodeling of the ECM by MMPs during ovulation, and examines how their disorders contribute to infertility. A deeper understanding of these mechanisms may lead to the identification of new therapeutic targets and the improvement of assisted reproduction outcomes. Full article

Sociotechnical imaginaries are collectively held and institutionally stabilised visions of desirable futures that link scientific and technological development with social and political order. Developed within Science and Technology Studies, the concept highlights the co-production of knowledge, technology, and governance, showing how ideas of progress are embedded in cultural values, moral assumptions, and political priorities. These imaginaries function as normative horizons that orient innovation, legitimise policy, shape regulation, and guide clinical practice. In health and biomedicine, sociotechnical imaginaries are particularly salient, as medical innovations directly affect life, death, and embodiment. Within medical sociology, the concept has been used to analyse how technologies such as assisted reproductive technologies (ARTs), genomics, regenerative medicine, and digital health are framed through narratives of hope, responsibility, risk, and transformation. These imaginaries shape what counts as legitimate knowledge, who accesses treatment, and how ethical debates are structured, from autonomy in ARTs to individualised care in precision medicine. Imaginaries are also shaped by national and institutional contexts. Comparative research shows that the United States, Europe, and East Asia produce distinct biomedical futures, reflecting different political traditions and governance models. As an analytical lens, sociotechnical imaginaries reveal health and biomedicine as domains where futures are imagined, contested, and enacted. Full article

Given livestock’s crucial role in global food security and economic stability, the alarming threat of climate change calls for the implementation of effective mitigation strategies for climate-resilient livestock production. Management and nutritional strategies offer temporary relief, whereas genetic approaches represent a permanent solution. The role of genetic tools in enabling the development of climate-resilient livestock breeds is widely recognized. Genetic tools like microarrays, RNA-seq, omics, and GWAS can improve the understanding of livestock’s climate adaptability at a molecular level. These tools facilitate the identification of biomarkers for thermo-tolerance, bordering on climate-resilient livestock breeding. Among them, studies employing genome-wide association studies (GWAS) have increased in recent years. GWAS have the potential to improve the genetic basis of thermo-tolerance in heat-stressed livestock populations. GWAS have been used to identify candidate genes for complex and economically important traits in livestock. These include growth, reproduction, disease resistance, milk, meat, and wool production traits under heat stress conditions. This makes GWAS a useful tool for identifying biomarkers that can be incorporated in breeding programs through marker-assisted selection (MAS). The integration of these potential biomarkers into selection and breeding programs would allow GWAS to substantially refine breeding strategies, thereby advancing the climate-resilient potential and sustainability of the livestock sector. Furthermore, GWAS, when utilized along with emerging technologies like Artificial Intelligence (AI), machine learning (ML), and deep learning (DL) for genomic prediction, can predict genetic aspects of livestock adaptation more efficiently and precisely. Thus, future studies should focus on integrated modeling approaches for improving the climate resilience of livestock without jeopardizing their production potential. Such an effort will contribute to sustainable livestock production as well as ensure food security for the growing human population amid changing climate conditions. Full article

Objective: This study aimed to identify distinct dyadic coping profiles among infertile couples undergoing assisted reproductive technologies (ARTs) and to examine the associations between these coping profiles, depressive symptoms, and fertility quality of life (FertiQOL). Methods: A total of 271 infertile couples undergoing ARTs were recruited from a reproductive medicine center in Zhengzhou, China, and completed standardized self-report measures. Latent profile analysis was conducted to identify distinct dyadic coping profiles at the couple level. Multinomial logistic regression was used to examine sociodemographic and infertility-related predictors of profile membership. Differences in depressive symptoms and FertiQoL across profiles were analyzed using the Bolck–Croon–Hagenaars method. Results: Four dyadic coping profiles were identified: high-coping wife and low-coping husband (15.4%), low dyadic coping (20.1%), medium dyadic coping (31.5%), and high dyadic coping (33.0%). Couples in the high dyadic coping profile reported the lowest levels of depression and the highest level of FertiQoL. Women in the low dyadic coping profile reported the highest depressive symptoms, while men in the high-coping wife and low-coping husband profile demonstrated the highest depression among male partners. Sociodemographic factors (household registration, family income) and infertility characteristics (type of infertility, infertility duration) were significant predictors of profile membership. Conclusions: Dyadic coping among infertile couples undergoing ARTs is heterogeneous and differentially associated with depression and FertiQoL. Low and asymmetric dyadic coping represent high-risk profiles linked to poorer outcomes in both partners. These findings suggest that dyadic coping may serve as a protective resource for infertile couples to improve their psychological well-being and quality of life, highlighting the importance of incorporating dyadic coping assessment into routine care and providing couple-centered psychosocial interventions in fertility care practice. Full article

Microplastic (MP) contamination has become a global environmental and public health concern due to the extensive use of plastics and ineffective waste management. These microscopic particles are now detected in air, water, soil, and food products, raising serious concerns about their persistence, bioaccumulation, and potential risks. Microplastics (MPs) have been shown to disrupt marine biodiversity, affect plant metabolism, and enter food webs, leading to accumulation in human tissues. Chronic exposure is increasingly linked to reproductive toxicity, carcinogenesis, neurotoxicity, and metabolic disorders. This review provides a comprehensive overview of the sources, pathways, and environmental fate of microplastics, with an emphasis on their ecotoxicological effects and human health implications. It also summarises key analytical methods for detecting microplastics in environmental and food matrices, including spectroscopy, microscopy, and emerging sensor-based technologies. Finally, the review highlights the need for improved waste management, stronger policy interventions, and enhanced public awareness to mitigate microplastic pollution and protect ecosystem and human health. Full article

Non-invasive assessment of oocyte quality remains a challenge in assisted reproductive technology (ART). Through their bidirectional communication with the gamete, cumulus cells (CCs) act as a functional mirror of oocyte competence; however, the specific angiogenic signature within this microenvironment is still poorly understood. In the present study, we performed RNA-seq on CCs from healthy oocyte donors and infertile patients, utilizing a multi-pipeline bioinformatic approach (STAR-Cufflinks, TopHat-HTSeq, and HISAT2-StringTie) to establish a high-confidence, exploratory transcriptomic profile. A set of 234 differentially expressed genes (DEGs) consistently identified across pipelines was obtained, with functional enrichment highlighting blood vessel morphogenesis and angiogenesis as primary drivers of transcriptomic divergence between groups. RT-qPCR validation in individual samples confirmed statistically significant differences for ANKRD22 (upregulated) and E2F7 (downregulated) in infertile patients, while other angiogenesis-related genes, including ANGPT1, ANGPT2 and THBS1, showed consistent but non-significant expression trends, suggesting alterations in angiogenesis-related processes within the follicular microenvironment. These findings support the presence of coordinated angiogenesis-related alterations in cumulus cells and provide a basis for future studies exploring their potential relevance in oocyte competence and ART outcomes. Full article

Pluripotent stem cells (PSCs) have proven outstanding potential to revolutionize biomedical research. Specifically, their capacity to form 3D multicellular systems that recapitulate organ development and biology, known as organoids, has transformed basic and translational research. The groundbreaking technology is also being applied to the intricate hypothalamus–pituitary (HP) axes, including the target organs (such as gonads, thyroid and adrenal glands). These HP axes govern critical physiological processes, including reproduction, metabolism and stress. Here, we provide an overview of PSC-derived organoid models that are part of the HP axes, both as individual and multi-organ systems, and evaluate their culturing conditions, phenotypic characteristics, advantages, drawbacks and challenges, as well as their potential for disease modeling and therapeutic discovery. By offering this wide perspective, our review will also serve as a key resource for researchers navigating the evolving landscape of PSC-derived organoid technologies in endocrinology. Full article