In the past decades, significant progress has been achived in cartilage regeneration. The traditional techniques for constructing tissue engineering cartilage scaffold mainly include pore agent method (or template method), phase separation method, gas foaming method, freeze-drying method, electrospinning method, etc. Cartilage is heterogeneous, and it is difficult for traditional scaffolds to simulate the high anisotropy of cartilage. Therefore, functional regeneration of cartilage is challenging. With the progress of three-dimensional(3D) printing technology, it is possible to prepare functional bionic scaffolds with fine structure and gradient changes through co-deposition of biomaterials, cells and active biomolecules, so as to achieve functional cartilage regeneration. This article reviewed 3D printing technology of cartilage tissue engineering, and the application of 3D printing technology in cartilage regeneration at different anatomical positions (articular cartilage, auricle cartilage, nasal cartilage). In addition, the importance of preparing bionic constructs with regional structure gradient and regional composition gradient was discussed. 3D bioprinting technology, 4D printing techniques, smart biomaterials brought hope for the construction of bionic tissues and organs.

In the past decades, significant progress has been achived in cartilage regeneration. The traditional techniques for constructing tissue engineering cartilage scaffold mainly include pore agent method (or template method), phase separation method, gas foaming method, freeze-drying method, electrospinning method, etc. Cartilage is heterogeneous, and it is difficult for traditional scaffolds to simulate the high anisotropy of cartilage. Therefore, functional regeneration of cartilage is challenging. With the progress of three-dimensional(3D) printing technology, it is possible to prepare functional bionic scaffolds with fine structure and gradient changes through co-deposition of biomaterials, cells and active biomolecules, so as to achieve functional cartilage regeneration. This article reviewed 3D printing technology of cartilage tissue engineering, and the application of 3D printing technology in cartilage regeneration at different anatomical positions (articular cartilage, auricle cartilage, nasal cartilage). In addition, the importance of preparing bionic constructs with regional structure gradient and regional composition gradient was discussed. 3D bioprinting technology, 4D printing techniques, smart biomaterials brought hope for the construction of bionic tissues and organs.

Objective:To explore the relationship between the levels of serum complement C3 and C4 and the degree of renal pathological injury in patients with IgA nephropathy (IgAN).Methods:It was a retrospective study. The clinical and pathological data of patients with primary IgAN diagnosed by renal biopsy in the Department of Nephrology of the Second People's Hospital of Qujing City, Yunnan Province from December 1, 2019 to December 31, 2022 were collected. According to the IgAN Oxford classification criteria, the patients were divided into mild renal pathological injury group (mild group, <3 pathologic types) and severe renal pathological injury group (severe group, ≥3 pathological types). The levels of serum C3 and C4 and other clinical data were compared between the two groups. Spearman correlation method was used to analyze the correlation between serum C3, C4 levels and estimated glomerular filtration rate (eGFR) during renal biopsy.Multivariate logistic regression model was used to analyze the influencing factors of the pathological injury degree in IgAN patients and the forest map depicted the effect of risk factors.Results:A total of 164 IgAN patients were included in the study, including 77 males (47.0%), aged (35.5±12.9) years old. There were 60 patients in the mild group and 104 patients in the severe group. Compared with the mild group, the patients in the severe group were older, had higher levels of serum C4, serum uric acid, low density lipoprotein cholesterol and 24 h urinary protein, higher proportions of hypertension, glucocorticoids/immunosuppressant therapy, C3 deposition in renal tissues and microscopic hematuria, and had lower hemoglobin and serum C3 level (all P<0.05). The results of Spearman correlation analysis showed that the level of serum C3 was positively correlated with eGFR ( r=0.303, P<0.001), and the level of serum C4 was negatively correlated with eGFR ( r=-0.238, P=0.002). Multivariate logistic regression analysis results showed that serum C3 (every 0.01 g/L increase, OR=0.976, 95% CI 0.957-0.996, P=0.018), serum C4 (every 0.01 g/L increase, OR=1.091, 95% CI 1.020-1.166, P=0.011), hemoglobin ( OR=0.969, 95% CI 0.950-0.988, P=0.002), and serum uric acid ( OR=1.005, 95% CI 1.001-1.009, P=0.012) were independent related factors of renal pathological damage (severe injury /mild injury) in IgAN patients. Conclusions:Serum C3 and C4 are independent related factors of the severity of renal pathological injury in IgAN patients.

Objective:To explore the mechanism of Ma-Xing Shi-Gan decoction combined with Xiao-Chai-Hu decoction (hereinafter referred to as " Sanyang combined treatment" ) in alleviating colon injury in mice infected with influenza virus by transcriptome sequencing technique.Methods:The mouse model of colonic injury caused by influenza virus was induced by intranasal drip of influenza A virus H1N1 suspension. The mice were divided into Control group, Model group, and Sanyang combined treatment (SCT) group. Model group and SCT group were fed with PBS and Ma-Xing Shi-Gan decoction combined with Xiao-Chai-Hu decoction respectively. Seven days later, the colon tissues of each group were taken, the colon length and pathological damage were observed, and the transcriptome was sequenced to screen the significantly different genes between the SCT group and model group for Gene Ontology (GO), Kyoto Encyclopedia of Genes and Genomes (KEGG) and Gene Set Enrichment Analysis(GSEA).Results:After the therapy with SCT, the length of the colon of mice was significantly improved and the pathological injury of the colon was reduced. There are 92 differentially expressed genes between the SCT group and the model group. GO analysis indicated that the differential genes were enriched in biological processes such as regulation of cytokine and chemokine production, inflammatory response, defense response, immune response, regulation of NF-κB inducing kinase(NIK)/Nuclear factor-κB(NF-κB) signal and Mitogen-activated protein kinase(MAPK) cascade, as well as cell components related to intestinal barrier such as brush border membrane, brush border and microvilli. KEGG analysis indicated that the differential genes were enriched in Toll-like receptor signaling pathway, intestinal immune network for IgA production, complement and coagulation cascade, and Peroxisome proliferator-activated receptor(PPAR) signaling pathway. GSEA indicated that the intestinal immune network for IgA production, PPAR signaling pathway, propionic acid metabolism and butyrate metabolism were significantly up-regulated after the intervention with SCT, while apoptosis and MAPK signaling pathway were significantly down-regulated.Conclusions:Sanyang combined therapy can protect the intestinal tract of mice infected with influenza virus mainly through immunity, inflammation and metabolism pathways.

Objective:To investigate the effect of different negative pressure level on drain volume after augmentation mammoplasty through inframammary fold incision, and try to put forward the appropriate negative pressure level for the best prognosis of patients.Methods:This was a randomized controlled clinical study. Patients who underwent prosthetic augmentation mammoplasty through inframammary fold incision in the Medical Beauty Center of the First Affiliated Hospital of Zhengzhou University from January 2019 to August 2021 were selected as the study subjects. Patients were divided into 4 groups by random number table method and different levels of negative pressure drainage were applied: 600 ml adjustable negative pressure drain bottle was used uniformly after operation by -80--85 kPa group, -40--60 kPa group, and -15--30 kPa group. In 0--5.2 kPa group, 300 ml drain drum was applied after operation. The criteria for drain removal was that the drain volume within 24 hours was less than 10 ml and the drainage fluid was clear. Daily drain volume, duration of drain placement, total drain volume, acceptance of the drain device and postoperative complications were recorded in the four groups. The corresponding indexes of each group were statistically analyzed by SPSS 21.0. Measurement data were expressed as Mean±SD. One-way analysis of variance was used for comparison between groups, and LSD- t test was used for pair comparison between groups. P<0.05 was considered statistically significant. Results:A total of 80 patients were included, 20 in each group. Inter-group equilibrium analysis: there was no significant difference in age, body mass index, distance from midclavicular point to nipple, distance from inferior mammary fold to nipple, and breast tissue thickness among 4 groups ( P>0.05). Evaluation of curative effect between groups: on the first and second day after operation, there was no significant difference in drain volume between -80--85 kPa group and -40--60 kPa group ( P>0.05), but there was significant difference among other groups ( P<0.05). There was significant difference in drain volume on the third day after operation, total drain volume and duration of drain placement between the four groups ( P<0.05). The lower the negative pressure level was, the less drain volume on the third day after surgery and the less total drain volume, and the shorter duration of drain placement. The duration of drain placement of the four groups were (5.6±0.7) d (-80--85 kPa group), (4.8±0.5) d (-40--60 kPa group), (4.0±0.5) d (-15--30 kPa group), and (3.2±0.4) d (0--5.2 kPa group), respectively. Safety evaluation: the complication rate of -80--85 kPa group, -40--60 kPa group, -15--30 kPa group and 0--5.2 kPa group were 2.5% (1/40), 2.5% (1/40), 0(0/40) and 15.0% (6/40), respectively. The complication rate of 0--5.2 kPa group was the highest. Investigation on the acceptance of the drainage device (no impact/dissatisfaction): 75 patients expressed dissatisfaction, with a dissatisfaction rate of 93.75%(75/80). Conclusion:In augmentation mammoplasty through inferior fold incision low negative pressure provides less drain volume, shorter drain placement. Negative pressure between -15 to -30 kPa is optimal.

In the past decades, great progress has been made in cartilage regeneration. The traditional techniques for constructing tissue engineering cartilage scaffold mainly include pore agent method (or template method ) , phase separation method, gas foaming method, freeze-drying method , electrospinning method, etc. Cartilage is heterogeneous, and it is difficult for traditional scaffolds to simulate the high anisotropy of cartilage. Therefore, functional regeneration of cartilage is challenging. With the progress of three-dimensional (3D) printing technology, it is possible to prepare functional bionic scaffolds with fine structure and gradient changes through co deposition of biomaterials, cells and active biomolecules, so as to achieve functional cartilage regeneration. This article reviews 3D printing technology of cartilage tissue engineering, and the application of 3D printing technology in cartilage regeneration at different anatomical positions (articular cartilage, auricle cartilage, nasal cartilage) . In addition, the importance of preparing bionic constructs with regional structure gradient and regional composition gradient was discussed. 3D bioprinting technology, 4 D printing techniques, smart biomaterials brought hope for the construction of bionic tissues and organs.

Objective:To investigate the effect of different negative pressure level on drain volume after augmentation mammoplasty through inframammary fold incision, and try to put forward the appropriate negative pressure level for the best prognosis of patients.Methods:This was a randomized controlled clinical study. Patients who underwent prosthetic augmentation mammoplasty through inframammary fold incision in the Medical Beauty Center of the First Affiliated Hospital of Zhengzhou University from January 2019 to August 2021 were selected as the study subjects. Patients were divided into 4 groups by random number table method and different levels of negative pressure drainage were applied: 600 ml adjustable negative pressure drain bottle was used uniformly after operation by -80--85 kPa group, -40--60 kPa group, and -15--30 kPa group. In 0--5.2 kPa group, 300 ml drain drum was applied after operation. The criteria for drain removal was that the drain volume within 24 hours was less than 10 ml and the drainage fluid was clear. Daily drain volume, duration of drain placement, total drain volume, acceptance of the drain device and postoperative complications were recorded in the four groups. The corresponding indexes of each group were statistically analyzed by SPSS 21.0. Measurement data were expressed as Mean±SD. One-way analysis of variance was used for comparison between groups, and LSD- t test was used for pair comparison between groups. P<0.05 was considered statistically significant. Results:A total of 80 patients were included, 20 in each group. Inter-group equilibrium analysis: there was no significant difference in age, body mass index, distance from midclavicular point to nipple, distance from inferior mammary fold to nipple, and breast tissue thickness among 4 groups ( P>0.05). Evaluation of curative effect between groups: on the first and second day after operation, there was no significant difference in drain volume between -80--85 kPa group and -40--60 kPa group ( P>0.05), but there was significant difference among other groups ( P<0.05). There was significant difference in drain volume on the third day after operation, total drain volume and duration of drain placement between the four groups ( P<0.05). The lower the negative pressure level was, the less drain volume on the third day after surgery and the less total drain volume, and the shorter duration of drain placement. The duration of drain placement of the four groups were (5.6±0.7) d (-80--85 kPa group), (4.8±0.5) d (-40--60 kPa group), (4.0±0.5) d (-15--30 kPa group), and (3.2±0.4) d (0--5.2 kPa group), respectively. Safety evaluation: the complication rate of -80--85 kPa group, -40--60 kPa group, -15--30 kPa group and 0--5.2 kPa group were 2.5% (1/40), 2.5% (1/40), 0(0/40) and 15.0% (6/40), respectively. The complication rate of 0--5.2 kPa group was the highest. Investigation on the acceptance of the drainage device (no impact/dissatisfaction): 75 patients expressed dissatisfaction, with a dissatisfaction rate of 93.75%(75/80). Conclusion:In augmentation mammoplasty through inferior fold incision low negative pressure provides less drain volume, shorter drain placement. Negative pressure between -15 to -30 kPa is optimal.

In the past decades, great progress has been made in cartilage regeneration. The traditional techniques for constructing tissue engineering cartilage scaffold mainly include pore agent method (or template method ) , phase separation method, gas foaming method, freeze-drying method , electrospinning method, etc. Cartilage is heterogeneous, and it is difficult for traditional scaffolds to simulate the high anisotropy of cartilage. Therefore, functional regeneration of cartilage is challenging. With the progress of three-dimensional (3D) printing technology, it is possible to prepare functional bionic scaffolds with fine structure and gradient changes through co deposition of biomaterials, cells and active biomolecules, so as to achieve functional cartilage regeneration. This article reviews 3D printing technology of cartilage tissue engineering, and the application of 3D printing technology in cartilage regeneration at different anatomical positions (articular cartilage, auricle cartilage, nasal cartilage) . In addition, the importance of preparing bionic constructs with regional structure gradient and regional composition gradient was discussed. 3D bioprinting technology, 4 D printing techniques, smart biomaterials brought hope for the construction of bionic tissues and organs.

OBJECTIVES: To establish the imaging mass spectrometry for analysis of differentially expressed proteins distribution in the rat brains with diffuse axonal injury （DAI） based on matrix assisted laser desorption/ionization-time of flight imaging mass spectrometry （MALDI-TOF-IMS）. METHODS: MALDI-TOF-IMS scanning were conducted on the brains of DAI group and control group in the m/z range of 1 000 to 20 000 using AutoflexⅢ MALDI-TOF spectrometer. ClinProTool 2.2 software was used for statistical analysis on the data of two groups, and then the differentially expressed proteins were picked out to conduct imaging. The distribution of the proteins with different m/z in the rat brains was observed. RESULTS: Five proteins with different m/z, including 4 963, 5 634, 6 253, 6 714 and 7 532, differentially expressed in the rat brains with DAI. CONCLUSIONS MALDI-TOF-IMS can be used for studying the differentially expressed proteins in rat brains with DAI and the analysis method is established for exploring the distribution of differentially expressed proteins in the rat brains with DAI using imaging mass spectrometry.
Animals ; Brain/pathology* ; Diffuse Axonal Injury/pathology* ; Proteins/metabolism* ; Proteome/metabolism* ; Proteomics ; Rats ; Software ; Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization

Based on multi-layer dielectric model of spherical biological cell, a simulating method of frequency characteristics of inner and outer membranes is presented in this paper. Frequency-domain analysis showed that inner and outer membranes subjected to pulsed electric field exhibit band-pass and low-pass filter characteristics, respectively. A calculating method of the transmembrane potential of inner and outer membranes induced by time-varying electric field was introduced, and the window effect between electric field and transmembrane potential was also analyzed. When the duration is reduced from microsecond to sub-microsecond, and to nanosecond, the target induced was from the outer membrane to inner membrane gradually. At the same time, the field intensity should be increased to induce corresponding bioelectric effects. Window effect provides theoretical guidance to choosing reasonable parameters for application of pulsatile electric field in tumor treatment.
Cell Membrane ; physiology ; radiation effects ; Computer Simulation ; Electromagnetic Fields ; Humans ; Membrane Potentials ; physiology ; radiation effects ; Models, Biological