Objective To explore the value of echocardiography in evaluation of pulmonary venous in total anomalous pulmonary venous connection (TAPVC).Methods Fifty-five children with TAPVC were enrolled in the study.The data of echocardiography and CT angiography were retrospectively analyzed and compared with intraoperative findings.Results Totally 55 patients with TAPVC were classified into supra-cardiac type (n=24),cardiac type (n=20),infra-cardiac type (n=7) and mixed type (n=4) according to the sites of drainage of pulmonary venous in echocardiography.In 15 patients with obstruction of pulmonary vertical vein,the sites of obstruction in the supra-cardiac type mostly presented between vertical vein and superior vena cava or innominate vein,and the sites of obstruction in the infra-cardiac presented all between vertical vein and hepatic or portal vein.In 4 patients with pulmonary vein stenosis,3 cases with local pulmonary vein stenosis were all cardiac type,which presented between individual pulmonary vein and common confluence or right atrium;1 patient with diffuse pulmonary vein stenosis was infra-cardiac type.In 9 patients of abnormal individual pulmonary vein,8 cases were not detected by echocardiography,but all were detected by CT angiography.Conclusion Echocardiography is able to make more comprehensive evaluation for the pulmonary venous drainage,obstruction,and proximal stenosis of individual pulmonary vein in TAPVC.CT angiography is superior in evaluation of abnormalities of connection and amount of individual pulmonary vein,and imaging of distal pulmonary vein.

Bacterial outer membrane vesicles (OMVs) are diminutive vesicles naturally released by Gram-negative bacteria. These vesicles possess distinctive characteristics that attract attention for their potential use in drug administration and immunotherapy in cancer treatment. Therapeutic medicines may be delivered via OMVs directly to the tumor sites, thereby minimizing exposure to healthy cells and lowering the risk of systemic toxicity. Furthermore, the activation of the immune system by OMVs has been demonstrated to facilitate the recognition and elimination of cancer cells, which makes them a desirable tool for immunotherapy. They can also be genetically modified to carry specific antigens, immunomodulatory compounds, and small interfering RNAs, enhancing the immune response to cancerous cells and silencing genes associated with disease progression. Combining OMVs with other cancer treatments like chemotherapy and radiation has shown promising synergistic effects. This review highlights the crucial role of bacterial OMVs in cancer, emphasizing their potential as vectors for novel cancer targeted therapies. As researchers delve deeper into the complexities of these vesicles and their interactions with tumors, there is a growing sense of optimism that this avenue of study will bring positive outcomes and renewed hope to cancer patients in the foreseeable future.

Objective To explore the effect and mechanism of microRNA (miR)-17-5p on the invasion and metastasis of hepatocellular carcinoma (HCC) cells. Methods Expression of miR-17-5p in the normal human L-02 hepatocyte and QGY-7703 HCC cells was detected by RT-PCR. QGY-7703 HCC cells were transfected by miR-17-5p mimic and mimic control respectively. Influence of miR-17-5p on the invasion and metastasis ability of HCC cells was detected using Transwell assay and scratch test. Target gene of miR-17-5p was confirmed by bioinformatic analysis, and its expression in HCC cells was detected by Western blot. After siRNA silenced by target gene, the invasion and metastasis ability of HCC cells were observed. Comparison of microRNA in the two kinds of cells was conducted by t test. Results Expression level of miR-17-5p in HCC cells was 0.16±0.04, significantly lower than 1.01±0.19 in normal L-02 hepatocytes (t=-9.67, P<0.05). Number of trans-membrane cells and metastasis rate of HCC cells transfected by miR-17-5p mimic were respectively 36±4 and (5.37±0.15) mm/d, significantly lower than 62±7 and (7.50±0.01) mm/d of control group (t=-15.40, -32.00; P<0.05). Bioinformatic analysis showed that AKT3 was the key target gene of miR-17-5p, and the expression of AKT3 in HCC cells was obviously higher than that of normal hepatocyte. Number of trans-membrane cells and metastasis rate of HCC cells transfected by siRNA-AKT3 were respectively 13±3 and (4.13±0.15) mm/d, significantly lower than 58±3 and (7.23±0.25) mm/d of control group (t=-17.88, -53.69; P<0.05). Conclusion miR-17-5p inhibits the invasion and metastasis ability of HCC cells through targeting effect on AKT3.

Objective:To investigate the effects of microwave radiation on associative learning and memory function and hippocampal structure of mice.Methods:C57BL/6N mice were ramdomly divided into sham-radiated group ( n=27) and radiation group ( n=2). The radiation group was exposed to microwave at 2.856 GHz, 8 mW/cm 2 for 15 min, then their spatial and associative learning and memory function were examined with the morris water maze and shuttle box behavior experiment. The pathological changes of hippocampal tissue were observed by HE staining and light microscope, the ultrastructural changes of hippocampal tissue were observed by transmission electron microscope. Results:After microwave radiation, the times of mice crossing the platform for the reverse space exploration decreased from(3.60±0.79) times to (2.55±0.47) times( t=2.21, P=0.046), the average active escape rate decreased significantly ( t = 2.70, P<0.05), and the average active latency and the total shock time was significantly prolonged ( t = -3.09, -3.02, P < 0.05). At 8 d after microwave radiation, the nuclei of some neurons in the CA3 and DG regions of the hippocampus were pyknosis. The neurons were apoptotic, the synaptic spaces blurred, the glial cells swollen, and the perivascular spaces widened in the CA3 region of the hippocampus. Conclusions:Microwave radiation can decline the spatial reference memory ability and associative learning and memory ability of mice. The morphological and pathological changes of hippocampus are the structural basis of this dysfunction.