ABSTRACT
Objective:To study the effect of Gegen Qinliantang (GQT) on the structure of intestinal flora in dysbacterial diarrhea rats by 16S rRNA sequencing. Method:Sixty healthy SD rats were randomly and equally divided into a control group, a model group, high-, medium-, and low-dose GQT groups, and a Bifidobiogen group. The rat model was induced in the five groups except the control group by administration of mixed antibiotics (178.6 mg·kg<sup>-1</sup> cefradine and 31.25 mg·kg<sup>-1 </sup>gentamicin sulfate) according to the dose. Drug intervention was carried out in each group (7.02, 3.51, and 1.755 g·kg<sup>-1</sup> GQT for the high-, medium-, and low-dose GQT groups, 0.125 g·kg<sup>-1</sup> bifidobacterium capsules for the Bifidobiogen group, and sterile distilled water for the control and model groups) with a volume of 10 mL·kg<sup>-1</sup> for seven days. Colon contents of rats were obtained under anesthesia. The extracted fecal DNA underwent 16S rRNA high-throughput sequencing and the results were analyzed. Result:GQT was proved capable of adjusting the species number and Alpha and Beta diversity, improving the biological richness and diversity of the flora, and positively regulating three differential phyla (Firmicutes, Proteobacteria, and Bacteroidetes) and 14 differential genera (<italic>Bacteroides</italic>,<italic> Parabacteroides</italic>,<italic> Blautia</italic>, etc.) in rat model of dysbacterial diarrhea. Conclusion:The present study confirmed the regulatory effect of GQT on intestinal flora of dysbacterial diarrhea rats, and revealed the physiological and pathological mechanism between intestinal flora and dysbacterial diarrhea.
ABSTRACT
Objective To evaluate the application of “OmniView”, a new three-dimensional ultrasound technology, in displaying the fetal palate. Methods The three-dimensional volume data was acquired from 100 normal fetuses, analysed by OmniView technology with the facial midsagittal plane as the starting plane. The imaging of fetal palate was obtained in axial plane (through maxilla, oral cleft), coronal plane, oblique coronal plane (through piriform aperture, oral cleft, submental triangle), and the palate′s curved plane tiled imaging by drawing the anatomical lines on referenced sagittal plane (facial midsagittal plane). The volumes of ifve fetuses with cleft lip and palate were obtained and analysed by the same technology. Results The volume dataset of 91 (91.0%, 91/100) normal fetuses were acquired successfully, and analyzed by OmniView technology, the results of 91 normal fetal palate in different plane were: (1) In axial plane through maxilla, the visualization of alveolar process bow was 91 (100%, 91/91). It was shown as“C”shaped arcuate structure, the anechoic structure of alveolar socket could be seen on the bow, and the ifrst 6 alveolar sockets were displayed clearly. The visualization number of hard palate was 91 (100%, 91/91), it was shown as hyperechoic lfake between two sides of alveolar bones. In axial plane through oral cleft, the visualization number of soft palate was 81 (89.0%, 81/91), it was shown as a strip of soft tissue echo band. (2) In coronal plane, the visualization number of hard palate was 91 (100%, 91/91), it was shown as a strip of hyperechoic band and separated the oral and nasal cavity. (3) In oblique coronal plane through piriform aperture, the visualization number of hard palate was 91 (100%, 91/91), it was shown as a short strip of hyperechoic band. In oblique coronal plane through oral cleft, the visualization number of hard palate was 91 (100%, 91/91). In oblique coronal plane through submental triangle, the visualization number of hard palate was 91 (100%, 91/91). In the above two planes, the hard palate was shown as a strip of hyperechoic band, due to acoustic shadow behind the hard palate, the nasal cavity and nasal septum above the hard palate couldn’t be displayed. (4) In oblique coronal plane through piriform aperture, the visualization number of soft palate was 81 (89.0%, 81/91). The visualization number of uvula was 25 (27.5%, 25/91). The soft palate was shown as a lfake of soft tissue echo behind the hard palate, and the uvula was shown as papillary protrusions on the edge of the soft palate in the midline. In oblique coronal plane through oral cleft, the visualization number of soft palate was 81 (89.0%, 81/91). In oblique coronal plane through submental triangle, the visualization number of soft palate was 81 (89.0%, 81/91). In the above two planes, the soft palate was shown as a strip of soft tissue echo band, the soft tissue echo of fetal tongue was in the lower front of soft palate, and the anechoic region of nasopharynx was superior behind the soft palate. (5) In the curved plane tiled imaging of palate, the visualization number of alveolar process bow (primary palate) was 91 (100%, 91/91). The visualization number of hard palate was 91 (100%, 91/91). The visualization number of soft palate was 81 (89.0%, 81/91). the visualization number of uvula was 25 (27.5%, 25/91), the planar panorama of alveolar process bow, hard palate and soft palate could be visualized intuitively, the alveolar arch and hard palate were shown as bone-like hyperecho, and the soft palate was shown as soft tissue hypoecho. In iffteen cases′volume involved cleft lip and palate, all five cases of malformations were detected through three-dimensional data analysis, the position and range of the cleft palate could also be conifrm. Abnormal fetuses were all veriifed after induction of labor. Conclusions By three-dimensional ultrasound technology-“OmniView”, the axial and coronal plane of fetal palate could be obtained easily which was dififcult by two-dimensional ultrasound, and the special oblique coronal plane of secondary palate could be displayed easily. The panorama of the palate could be visualized intuitively though curved plane tiled imaging by drawing a line tracking the structure of the palate. This technology could simplify the ultrasound examination procedure of the fetal palate, reduce the operators′skill-dependence, and quickly evaluated the integrity of the fetal primary palate and secondary palate. For the cleft lip fetus, this technology can determine whether the cleft palate exist or not, together with their position and range.