Objective: To investigate the effects of thyroid stimulating hormone (TSH) and thyroid peroxidase antibody(TPOAb) on pregnancy outcomes of in vitro fertilization-embryo transfer (IVF-ET). Methods: The patients who underwent IVF-ET at the Reproductive Medicine Center of Hefei Maternal and Child Health Care Hospital from December 2019 to November 2023, and had normal free thyroxine and 0.3-<10 mIU/L TSH levels were selected as subjects. The patients were divided into three groups based on TSH levels: 0.3-<2.5 mIU/L, 2.5-4 mIU/L, and >4-<10 mIU/L, and the patients with normal free thyroxine and TSH levels were further divided into TPOAb-positive and TPOAb-negative groups. The biochemical pregnancy rate, clinical pregnancy rate and miscarriage rate were compared among patients with different TSH and TPOAb groups. Results: A total of 3 876 patients were recruited, including 830 patients with fresh embryo transfer cycles and 3 046 patients with frozen-thawed embryo transfer cycles. In the patients with fresh embryo transfer cycles, the biochemical pregnancy rate, clinical pregnancy rate and miscarriage rate were 59.16%, 52.77% and 19.41%, respectively. In the patients with frozen-thawed embryo transfer cycles, these rates were 55.52%, 46.98% and 20.27%, respectively. For both groups, there were no statistically significant differences in biochemical pregnancy rate, clinical pregnancy rate and miscarriage rate between TPOAb-positive and TPOAb-negative patients or among the patients with different TSH groups (all P>0.05). Additionally, a follow-up study of 150 patients who had successfully delivered after IVF-ET from 2020 to 2022 with TSH levels of >4-<10 mIU/L showed that no intellectual developmental issues or tendencies toward intellectual developmental disorders were found in their offsprings. Conclusion In the context of normal free thyroxine levels, this study did not find any impacts of mildly elevated TSH levels or isolated TPOAb positivity on the pregnancy outcomes of IVF-ET.

Eutrophils are the first innate immune cells to reach the site of inflammation. Neutrophils produce neutrophil extracellular traps (NETs) that can quickly capture and limit the spread of pathogens, facilitating the removal of pathogens and their debris. Neutrophils in the oral cavity are specifically transformed from circulating neutrophils in the blood, and the number of NETs released by oral neutrophils is much higher than that of circulating neutrophils, thus better maintaining the balance of the oral microenvironment. As a bimorphic fungus, only the mycelium phase of Candida albicans can induce NETs, which is related to the neutrophils' ability to sense the size of pathogenic microorganisms through neutrophil elastase. However, spherical Staphylococcus aureus are much smaller than Candida albicans, and they can still induce NETs. Porphyromonas gingivalis, as one of the microorganisms in the periodontitis complex, induces fewer NETs than Streptococcus oralis and Actinomycetes, which are two common oral microorganisms, and there may be a mechanism allowing them to escape neutrophilic immunity in the early stage of periodontitis. Although the two main pathways of NET production have been studied in detail, the mechanisms involved in the induction of NETs by different microorganisms, especially from oral neutrophils, are not well understood. This review describes the mechanism of the immune effects of pathogenic microorganisms on neutrophil NETs in the oral cavity, providing a reference for the search for therapeutic targets and the development of key drugs for treating oral infectious diseases.

The oral microbiota is associated with oral diseases and digestive systemic diseases. Nevertheless, the causal relationship between them has not been completely elucidated, and colonisation of the gut by oral bacteria is not clear due to the limitations of existing research models. The aim of this study was to develop a human oral microbiota-associated (HOMA) mouse model and to investigate the ecological invasion into the gut. By transplanting human saliva into germ-free (GF) mice, a HOMA mouse model was first constructed. 16S rRNA gene sequencing was used to reveal the biogeography of oral bacteria along the cephalocaudal axis of the digestive tract. In the HOMA mice, 84.78% of the detected genus-level taxa were specific to the donor. Principal component analysis (PCA) revealed that the donor oral microbiota clustered with those of the HOMA mice and were distinct from those of specific pathogen-free (SPF) mice. In HOMA mice, OTU counts decreased from the stomach and small intestine to the distal gut. The distal gut was dominated by Streptococcus, Veillonella, Haemophilus, Fusobacterium, Trichococcus and Actinomyces. HOMA mice and human microbiota-associated (HMA) mice along with the GF mice were then cohoused. Microbial communities of cohoused mice clustered together and were significantly separated from those of HOMA mice and HMA mice. The Source Tracker analysis and network analysis revealed more significant ecological invasion from oral bacteria in the small intestines, compared to the distal gut, of cohoused mice. In conclusion, a HOMA mouse model was successfully established. By overcoming the physical and microbial barrier, oral bacteria colonised the gut and profiled the gut microbiota, especially in the small intestine.
Animals ; Bacteria ; Gastrointestinal Microbiome ; Germ-Free Life ; Humans ; Mice ; Microbiota ; RNA, Ribosomal, 16S