"Flipped Classroom" is a new kind of "student-centered" teaching model, which can give full play to the advantages of both sides of teaching and learning. According to this teaching model, we redesigned the teaching process, in which the students studied by themselves and built their own knowledge system. Moreover, each of them took part in three stages of experimental design including digital signal collection, analysis and processing in groups. Results have shown that this model can fully stimulate students' learning interest, not only helps students to deepen understanding of digital signal processing theory knowledge, but also strengthen the ability of autonomous learning and team collaboration. The teaching model maybe have certain reference function in comprehensive experiment teaching of Digital Signal Processing course for biomedical engineering specialty.

Based on the summary and reflection of the existing course construction content, this paper redesigns the course teaching to Brain Functional Imaging and forms a new curriculum construction scheme, including improving the professional teachers' ability of the teaching team by means of "internal training" + "external introduction", building an online and offline integrated teaching mode by combining online teaching resources such as course website with offline teaching (such as literature guidance, classroom discussion, comprehensive experimental design, etc.), and designing comprehensive experiments related to Electroencephalography (EEG) and functional near-infrared spectroscopy (fNIRS), which is driven by scientific research projects, based on the scientific research experimental platform of the teaching and research department. This construction scheme is of great significance for improving the teaching quality of the course, stimulating the learning interest of graduate students, and cultivating the comprehensive application and practical innovation ability of graduate students' brain imaging technology. And it also provides the reference for the further construction of the course and teaching reform in the future.

OBJECTIVE：To provide reference for the quality control of the leaves of Toricellia angulata . METHODS ：HPLC method was adopted. The determination was performed on Agela Promosil C 18 column with 0.2％ phosphoric acid solution-acetonitrile（gradient elution ）as mobile phase at the flow rate of 1.0 mL/min. The detection wavelength was set at 210 nm，and column temperature was 35 ℃. The sample size was 10 μL. HPLC fingerprint of 10 batches of the leaves of T. angulata was established and similarity evaluation was conducted by using Similarity Evaluation System of TCM Chromatographic Fingerprint（2004 edition）. The chromatographic peak was identified by comparing with the chromatogram of reference substance. Cluster analysis ，PCA and PLS-DA were used to identify chemical patterns ，and the quality differential markers were screened. The contents of hyperoside and isoquercitrin were determined by the same HPLC. RESULTS ：The similarities of HPLC fingerprint of 10 batches of the leaves of T. angulata with control fingerprint were 0.923-0.983. A total of 11 common peaks were identified ，and the peaks 4 and 5 were hyperoside and isoquercitrin ，respectively. Results of cluster analysis ，PCA and PLS-DA showed that 10 batches of leaves of T. angulata could be divided into two categories ，Y10 was clustered into one category ，and others were clustered into one category. PLS-DA analysis showed that 6 common peaks （peaks 4，3，10，2，6 and 11） with variable importance projection （VIP）greater than 1 were selected. Average contents of hyperoside and isoquercitrin in 10 batches of the leaves of T. angulata were 0.47-6.97，0.21-1.87 mg/g，respectively. CONCLUSIONS ：Established HPLC fingerprint and the method for content determination are stable and reliable ，and can be used for the quality control of the leaves of T. angulata from different areas. Six quality differential markers including hyperoside in the leaves of T. angulata from different areas are qnyz202034） preliminarily screened.

Objective:To observe the changes of the structure and visual function of the retina in patients with or without the ectopic inner foveal layers (EIFL) and to explore the factors influencing the recovery of visual function in patients with idiopathic epimacular membrane (IMEM).Methods:A retrospective clinical study. From March 2015 to June 2019, 90 patients with MEM who were diagnosed by Ophthalmic Center of the Second Hospital of Hebei Medical University were enrolled in the study. All patients were examined by best corrected visual acuity (BCVA) and frequency domain optical coherence scan. BCVA was recorded by Snellen vision table, and it was converted into the minimum resolution angle logarithm (logMAR) vision. Among 90 eyes, IMEM grade 2-4 was 68 (75.6%, 68/90), 18 (20.0%, 18/90), 4 (4.4%, 4/90), respectively. According to this, the grade 2 was set as group A, and the grade 3 and grade 4 were combined to group B. There was no significant difference in age ( t=0.015), sex composition ratio of patients between two groups ( χ2=0.060) and the average of central macular thickness (CMT) ( F=2.277) ( P=0.904, 0.809, 0.141). The difference of average logMAR and BCVA was statistically significant ( F=35.913, P=0.000). All patients underwent 25G pars plana three channel vitrectomy with simultaneous removal of epiretinal membrane and internal limiting membrane. BCVA, CMT and improvement of IMEM grading were observed at 1, 3, 6 and 12 months after operation. BCVA, EIFL thickness and CMT were compared before and after operation by single factor repeated variance analysis; Fisher exact probability method was used to compare the changes of the anatomical structure of the eyes in the two groups at 12 months after operation. Results:1, 3, 6, 12 months after operation, the average eyes of logMAR BCVA in group A were 0.50±0.13, 0.38±0.12, 0.27±0.12, 0.19±0.10. The patients in group B were 0.66±0.14, 0.60±0.13, 0.54±0.14, 0.52±0.14. CMT in group A were 364.82±81.29, 281.65±72.45, 228.55±55.34, 182.84±56.13 μm. The patients in group B were 455.88±69.60, 440.18±68.65, 383.76±65.38, 371.39±66.60 μm. The difference was statistically significant in the two groups (BCVA: F=37.913, 11.479, 24.250, 39.013; P=0.000, 0.002, 0.000, 0.000. CMT: F=10.987, 39.610, 55.789, 79.987; P=0.002, 0.000, 0.000, 0.000). In group A, IMEM was improved to 57 eyes of grade 1 on 12 months after operation. Among the 18 eyes in group B, IMEM was improved to 1 and 3 eyes in level 1 and level 2, respectively, and no improvement was found in 4 eyes in grade 4. The difference was statistically significant ( P=0.000) in the improvement of the number of eyes in the two groups. Conclusions:The patients with IMEM without EIFL have better visual prognosis and reversible anatomical changes. EIFL is an important factor affecting the visual function and anatomical structure recovery after operation.

Exosomes are small vesicles with a bilayer membrane structure secreted by a variety of cells. They are widely distributed in a variety of body fluids and contain proteins, nucleic acids and other components. They can mediate information transmission between cells and participate in a variety of physiological and pathological activities of cells. Hepatocytes, hepatic sinus endothelial cells and other cells were able to communicate with hepatic stellate cells via exosomes, and regulate the activation, migration, apoptosis and other biological activities of hepatic stellate cells. In this review, the recent advances in the regulation of exosomes on the biological activity of hepatic stellate cells were reviewed.