Oropharyngeal microbiome in children with adenotonsillar hypertrophy and after adenotonsillectomy.

BACKGROUND: The microbiome of tonsils and adenoid in adenotonsillar hypertrophy (ATH) has been profiled. Adenotonsillectomy (AT) is widely used for ATH in children. The variation of the oropharyngeal microecology in children with ATH or after AT have never been studied. OBJECTIVES: Here we aimed to evaluate the change in oropharyngeal microbiome in ATH Children after AT. MATERIALS AND METHODS: In this cross-sectional study, throat swabs for microbiome analysis were collected from ATH, AT and control groups. Using 16s rDNA sequencing, this study investigated the characteristics of oropharyngeal microbiome. RESULTS: The α-diversity showed a statistical difference in richness and the ß-diversity was significantly different among the three groups. The relative abundance of Haemophilus (member of Proteobacteria) increased but that of Actinomyces (member of Actinobacteriota) decreased in the ATH group compared to those in the AT and control groups, but their abundances showed no statistical difference between the AT and control groups. CONCLUSIONS: The oropharyngeal microbial diversity and composition are disrupted in children with ATH and can be restored after AT. This microbiome analysis provides a new understanding about the pathogenesis of ATH in children.SummaryIn this study, we aimed to evaluate the change in oropharyngeal microbiome in ATH Children after AT. The oropharyngeal microbial diversity and composition are disrupted in children with ATH and can be restored after AT.

LncRNA GMDS-AS1 inhibits lung adenocarcinoma development by regulating miR-96-5p/CYLD signaling.

According to the global cancer statistic, lung cancer is one of the most dangerous tumors, which poses a serious threat to human health. Exploration the mechanism of lung cancer and new targeted therapeutic measures is always the hot topic. Long noncoding RNA (lncRNA) is an important factor affecting the development of tumors. However, the research on the mechanism of lncRNA in the progress of lung cancer needs to be further expanded. In this study, we found that the expression of lncRNA GMDS-AS1 was significantly reduced in lung adenocarcinoma (LUAD) tissues and cells. Upregulated GMDS-AS1 can significantly inhibit the proliferation of LUAD cells and promote cell apoptosis in vitro and in vivo. The results indicate that GMDS-AS1 acts as a tumor suppressor gene to affect the development of LUAD. Further studies revealed that GMDS-AS1 is a target gene of miR-96-5p, and GMDS-AS1 regulates proliferation and apoptosis of LUAD cells in association with miR-96-5p. In addition, we also confirmed that CYLD lysine 63 deubiquitinase (CYLD) is also a target gene of miR-96-5p. Through various validations, we confirmed that GMDS-AS1 can act as a ceRNA to upregulate the expression of CYLD by sponging miR-96-5p. Moreover, the intervention of GMDS-AS1/miR-96-5p/CYLD network can regulate the proliferation and apoptosis of LUAD cells. In this study, we revealed that the GMDS-AS1/miR-96-5p/CYLD network based on ceRNA mechanism plays an important role in the development of LUAD and provides a new direction and theoretical basis for targeted therapy of LUAD.

18F-fluorodeoxyglucose positron emission tomography/computed tomography in the diagnosis of benign pulmonary lesions in sarcoidosis.

BACKGROUND: Many benign pulmonary lesions, especially sarcoidosis, are metabolically active and are indistinguishable from lung cancer using 18F-fluorodeoxyglucose positron emission tomography/computed tomography (18F-FDG PET/CT) imaging. This study sought to analyze the 18F-FDG PET/CT imaging features of benign pulmonary lesions and to improve the differential diagnosis of benign pulmonary lesions by 18F-FDG PET/CT imaging. METHODS: One hundred and thirteen patients with benign pulmonary lesions were studied retrospectively. Each patient underwent an 18F-FDG PET/CT scan. All cases were identified by pathology, diagnostic therapy or follow-up. The maximum standardized uptake value (SUVmax) was calculated for each pulmonary lesion. RESULTS: According to the final results, the benign pulmonary lesions were classified as inflammatory lesions (n=77) and granulomas (n=36) by histopathological diagnoses. The SUVmax of inflammatory lesions and granulomas were both high (4.55±2.77 and 6.81±3.96, respectively; P<0.05). When the benign pulmonary lesions were classified by clinical diagnoses, the SUVmax of sarcoidosis was significantly different from other diseases (15.12±5.67; P<0.01). CONCLUSIONS: Inflammatory lesions and granulomas show moderate or high FDG uptake on 18F-FDG PET/CT, but granulomas have higher values. 18F-FDG PET/CT appeared to have a higher SUVmax for the differential diagnosis of sarcoidosis and benign pulmonary lesions.

The pulmonary nodule "discovered" by pneumonia: a case report.

The number of patients diagnosed with pulmonary nodules increased as more patients with high risk of lung cancer choose low-dose computed tomography (CT) scans for the screening of cancer. Clinicians might get two questions from the patients: what is the definite diagnosis of the nodule? What should we do? We have already got many guidelines trying to solve these problems. There are also several prediction models for pulmonary nodules. However, guidelines are not suitable for all types of patients, and the reality of patients is more complicated. Here we reported a 58-year-old man with a lung nodule in the right upper lobe, which was occasionally found during a period of pneumonia. We suggested two periods of follow-up, and the patient was also admitted to a clinical trial about circulating tumor cells (CTCs). He finally accepted surgical excision with a pathologic diagnosis of adenocarcinoma. This case suggests that: we might suggest CT surveillance for patients with solid nodules about 8 mm maximum diameter; three-dimensional reconstruction of CT scans could provide more information about the details of nodules; CTCs counts of peripheral blood could be considered as a potential clue for malignancy.