Influencing factors and solution strategies of chimeric antigen receptor T-cell therapy(CAR–T)cell immunotherapy

Chimeric antigen receptor T-cesll therapy(CAR–T)has achieved groundbreaking advancements in clinical application,ushering in a new era for innovative cancer treatment.However,the challenges associated with implementing this novel targeted cell therapy are increasingly significant.Particularly in the clinical management of solid tumors,obstacles such as the immunosuppressive effects of the tumor microenvironment,limited local tumor infiltration capability of CAR–T cells,heterogeneity of tumor targeting antigens,uncertainties surrounding CAR–T quality,control,and clinical adverse reactions have contributed to increased drug resistance and decreased compliance in tumor therapy.These factors have significantly impeded the widespread adoption and utilization of this therapeutic approach.In this paper,we comprehensively analyze recent preclinical and clinical reports on CAR–T therapy while summarizing crucial factors influencing its efficacy.Furthermore,we aim to identify existing solution strategies and explore their current research status.Through this review article,our objective is to broaden perspectives for further exploration into CAR–T therapy strategies and their clinical applications.

Single Radar Measurement Method for Antiaircraft Projectile Miss Distance

To measure miss distance for antiaircraft projectile,a radial velocity identification and positioning method with a single radar is proposed. By analyzing the spatial resolution of multi-frequency ranging radar,the discrimination and testing model of this radar for multi-targets（ projectile and target） is established to analyze the systematic error of antiaircraft miss distance. Then through the aerial target flight test and contrast test with optical test equipment,the validity of the measurement method is verified. This newmethod has the potential to be used in the measurement of antiaircraft projectile miss distance.

Apoptosis is an obstacle to the differentiation of adipose-derived stromal cells into astrocytes

Previous studies have demonstrated that nerve cells differentiated from adipose-derived stro-mal cells after chemical induction have reduced viability;however, the underlying mechanisms remained unclear. In this study, we induced the differentiation of adult adipose-derived stromal cells into astrocytes using chemical induction. 3-（4,5-Dimethylthiazol-2-yl）-2,5-diphenyltetra-zolium bromide assay and flow cytometry showed that, with increasing induction time, the apoptotic rate gradually increased, and the number of living cells gradually decreased. Im-munohistochemical staining demonstrated that the number of glial fibrillary acidic protein-, caspase-3- and caspase-9-positive cells gradually increased with increasing induction time. Transmission electron microscopy revealed typical signs of apoptosis after differentiation. Taken together, our results indicate that caspase-dependent apoptosis is an obstacle to the differentia-tion of adipose-derived stromal cells into astrocytes. Inhibiting apoptosis may be an important strategy for increasing the efifciency of induction.

Transcranial magnetic stimulation-induced finger force changes under various finger coordination patterns and target finger force phases

BACKGROUND： The detection of motor evoked potential is utilized to explore neuromuscular finger coordination. The influence of transcranial magnetic stimulation on finger force has been investigated mainly on a single finger, and only time-dependent increased target finger force has been detected in the finger force task. OBJECTIVE： To explore the neural mechanism of finger force coordination in the motor cortex by observing the influence of various finger coordination patterns and patterns of transcranial magnetic stimulation （TMS）-induced finger force changes. DESIGN, TIME AND SETTING： Neurophysiological and behavioral study was performed at the Biomedical Engineering Laboratory of Chongqing University from April to June 2008. PARTICIPANTS： A total of 10 healthy, university students, comprising 5 males and 5 females, aged 21-23 years, voluntarily participated in this study. All participants were right-handed, with normal or corrected vision. Individuals with upper limb complaints or other musculoskeletal disorders were excluded. METHODS： A target force-tracking task was conducted on the index finger, the index and middle fingers, and four fingers （index, middle, ring, and little）, respectively. Target force trace in a single trial consisted of a 6-second ramp phase, a 20-second constant phase, and a 6-second drop phase. During experimentation, an unpredictable single-pulse TMS （120% motor threshold） was applied to the primary motor cortex （M1） in each phase. MAIN OUTCOME MEASURES： Changes in peak force induced by TMS were obtained for each finger pattern during each force-tracking phase. Differences in force changes were tested between different finger pattems with regard to ramp, constant, and drop phases of target force. RESULTS： Under ramp, constant, and drop phases of target force, the increase in magnetic stimulation-induced finger forces changes positively correlated with the number of fingers involved in the force tracking task. The magnetic stimulation-induced force changes from the index finger were less than the combination of the index and middle fingers or all four fingers under the corresponding target force, and the force changes from the combination of the index and middle fingers were less than all four fingers, Le., index finger 〈 index and middle fingers 〈 four fingers. CONCLUSION： Different neuromuscular mechanisms could be involved in finger force production for different finger combination patterns. Results from the present study suggested that independent motor neurons regulated individual finger force production.

660 nm red light-enhanced bone marrow mesenchymal stem cell transplantation for hypoxic-ischemic brain damage treatment

Bone marrow mesenchymal stem cell transplantation is an effective treatment for neonatal hy- poxic-ischemic brain damage. However, the in vivo transplantation effects are poor and their survival, colonization and differentiation efficiencies are relatively low. Red or near-infrared light from 600-1,000 nm promotes cellular migration and prevents apoptosis. Thus, we hypothesized that the combination of red light with bone marrow mesenchymal stem cell transplantation would be effective for the treatment of hypoxic-ischemic brain damage. In this study, the migra- tion and colonization of cultured bone marrow mesenchymal stem cells on primary neurons after oxygen-glucose deprivation were detected using Transwell assay. The results showed that, after a 40-hour irradiation under red light-emitting diodes at 660 nm and 60 mW/cmz, an increasing number of green fluorescence-labeled bone marrow mesenchymal stem cells migrated towards hypoxic-ischemic damaged primary neurons. Meanwhile, neonatal rats with hypoxic-ischemic brain damage were given an intraperitoneal injection of 1 x 106 bone marrow mesenchymal stem cells, followed by irradiation under red light-emitting diodes at 660 nm and 60 mW/cm2 for 7 successive days. Shuttle box test results showed that, after phototherapy and bone marrow mesenchymal stem cell transplantation, the active avoidance response rate of hypoxic-ischemic brain damage rats was significantly increased, which was higher than that after bone marrow mesenchymal stem cell transplantation alone. Experimental findings indicate that 660 nm red light emitting diode irradiation promotes cells, thereby enhancing the contribution ic-ischemic brain damage. the migration of bone marrow mesenchymal stem of cell transplantation in the treatment of hypox-

Correlation between primary motor cortex neural activity and fingertip force following transcranial magnetic stimulation

A better understanding of the neural mechanisms of finger-force regulation can help to explain the relationship between the central nervous system and nerve-muscle force, as well as assist in motor functional rehabilitation and the development robot hand designs. In the present study, 11 healthy volunteers performed a different target force-tracking task, which involved the index finger alone, index and middle finger together, and the combination of four fingers （i.e., index, middle, ring, and little）. The target force trace corresponded to 3 levels of 20% maximal voluntary changes （MVC）, 30% MVC, and 40% MVC in 20 seconds. In the test, an unexpected single 120% motor threshold transcranial magnetic stimulation was applied to the primary motor cortex （M1） during force tracking. Results revealed that peak force changes increased with increasing background force and the number of involved task fingers. These results demonstrate that M1 neural activities correlate with finger-force production, and M1 plays a role in finger-force control. Moreover, different neuronal networks were required for different finger patterns; a complicated task required multi-finger combinations and a complicated neuronal network comprised a large number of neurons.

Parameters of Exterior Ballistic Feature Points Extraction in Radar Measurement Data by EMD

The problem of measuring exterior ballistic feature points is always difficult to solve and it is essentiale on exterior ballistic measurement.By analysis of radar reflection characteristics and non-stationary echo signals of exterior ballistic feature points,the echo data of exterior ballistic feature points is measured by using the continuous wave radar.The parameters of feature points are extracted by the empirical mode decomposition method(EMD)of Hilbert-Huang transform(HHT)spectrum analysis technique.The radar echo signal model and EMD extraction model are established to analyze the exterior ballistic mutation point detection and EMD extraction method of aliasing echo signal.Typical feature point parameters of exterior ballistic in rocket flight tests are carried out and the effectiveness of the method is verified.A new method of measuring the parameters of exterior ballistic feature point is therefore presented.

Renal Amyloidosis Secondary to ANCA-Associated Vasculitis:A Case Report

Renal amyloidosis secondary to anti-neutrophil cytoplasmic antibody(ANCA)-associated vasculitis is extremely rare.Here,we reported a 77-year-old woman with ANCA-associated vasculitis.Renal biopsy with Masson trichrome staining showed pauci-immune crescentic glomerulonephritis,and electron microscopy showed amyloid deposition in the mesangial area.Immunofluorescence revealed kappa light chain and lambda light chain negative.Bone marrow biopsy revealed no clonal plasma cell.Finally,she was diagnosed as ANCA-associated vasculitis with secondary renal amyloid A amyloidosis.

Mechanism of Inhibitory Effect of Essential Oil from Valerianae Jatamansi Rhizoma et Radix on Activation of Microglia

[Objectives]To investigate the inhibitory effect and possible mechanism of essential oil from Valerianae Jatamansi Rhizoma et Radix on microglia activation induced by lipopolysaccharide(LPS).[Methods]The LPS-induced microglia activation model was established and treated with different doses of essential oil from Valerianae Jatamansi Rhizoma et Radix.MTT assay was used to detect cell viability,ELISA to detect IL-6 secretion,RT-PCR to detect mRNA expression levels of IL-6,IL-1β,NF-κB,and IκBα,Western blotting to detect the protein expression of IL-6,IL-1β,NF-κB,IκBα,and their phosphorylated products.[Results]Compared with the normal control group,the model group showed increased IL-6 content(P<0.01),upregulated mRNA and protein levels of IL-6,IL-1β,and NF-κB(P<0.01),and elevated ratio of P-IκBα/IκBα(P<0.05).Compared with the model group,4 and 2μg/L essential oil from Valerianae Jatamansi Rhizoma et Radix reduced the content of IL-6(P<0.05),while 4,2,and 1μg/L essential oil from Valerianae Jatamansi Rhizoma et Radix down-regulated the mRNA and protein levels of IL-6,IL-1β,and NF-κB to varying degrees(P<0.05 or P<0.01),up-regulate the mRNA expression of IκBα(P<0.05 or P<0.01),and decreased the ratio of P-IκBα/IκBα(P<0.05 or P<0.01).[Conclusions]Essential oil from Valerianae Jatamansi Rhizoma et Radix can inhibit LPS-induced microglia activation,and its mechanism may be related to the inhibition of the NF-κB/IκBαsignaling pathway.

Antimicrobial Resistance Analysis and Whole-Genome Sequencing of Salmonella Isolates from Environmental Sewage — Guangzhou City, Guangdong Province, China, 2022–2023

What is already known about this topic?S.1,4,[5],12:i:-and S.Rissen are emerging serotypes of Salmonella that require close monitoring for antimicrobial resistance and containment of their spread.What is added by this report?The study aimed to identify antimicrobial resistance genes(ARGs)in S.1,4,[5],12:i:-and S.Rissen strains isolated from environmental sewage in Guangzhou City,Guangdong Province,China.A phylogenetic tree was constructed using single nucleotide polymorphism data to assess genetic relatedness among strains,offering insights for Salmonella infection outbreak investigations in the future.What are the implications for public health practice?It is crucial to implement strategies,such as integrating different networks,to control the spread of drugresistant Salmonella.Novel technologies must be utilized to disinfect sewage and eliminate ARGs.Ensuring food safety and proper sewage disinfection are essential to curb the dissemination of Salmonella.

Engineering the inter-island plasmonic coupling in homometallic Au-Au_(n)core-satellite structures

We show that through strong ligand mediated interfacial energy control between Au seeds and the deposited Au,the non-wetting growth of Au on Au seeds led to the formation homometallic core-satellite nanostructures.To modulate the intraparticle plasmonic coupling between the core and the satellites,the number and size of the Au satellites,and their inter-island distances were continuously tuned by varying the growth kinetics.As a result of the precise structural control,the plasmonic absorptions of the core-satellite nanostructures were tuned from visible to near-infrared(NIR)spectral range,and the extent of spectral modulation(500-1300 nm)is among the best of the literature methods.This synthetic advance enriches the toolbox for nanosynthesis and points to a new direction in the exploration of sophisticated functional designs.

SMILE矫正高度近视的临床疗效及角膜后表面高度改变

目的:观察小切口角膜基质透镜取出术(SMILE)矫正高度近视的安全性、有效性、可预测性、稳定性及角膜后表面高度的变化情况。方法:描述性纵向研究。对2016年中南大学湘雅医院眼科37例高度近视SMILE术后患者67眼(等效球镜度为-10.75^-6.25D)做回顾性分析,于术前、术后1d、1个月、3个月、6个月行裸眼视力(UCVA)、最佳矫正视力(BCVA)、屈光度、眼压、眼轴、角膜地形图等检查。采用广义估计方程对手术前后数据及影响因素进行分析。结果:高度近视患者SMILE术后6个月UCVA(LogMAR)为-0.1(-0.2,0),有效性指数0.83±0.20;BCVA(LogMAR)-0.2(-0.2,-0.2),安全性指数1.03±0.16。术后1、3、6个月近视度数逐渐增加,术后6个月屈光度为-0.25(-0.50,0)D,回退量为-0.25(-0.50,0)D。术后UCVA(LogMAR)与年龄呈正相关,术后屈光度、回退量均与年龄呈负相关。角膜后表面Diff值术前为(0.030±0.006)mm,术后6个月为(0.046±0.012)mm,较术后1个月降低,与术后3个月差异无统计学意义。术后6个月Diff值及ΔDiff值均与角膜组织改变百分比mPTA呈正相关。结论:SMILE矫正高度近视有较好的安全性、有效性、可预测性和稳定性,但在术后6个月内仍有轻度屈光度回退,尤其是年龄较大的患者。术后角膜后表面前移,术后3个月部分恢复,术中组织切削百分比较大者前移量较大。

热量限制对成年弱视小鼠初级视皮质突触可塑性的调控作用

目的:探讨热量限制(CR)对成年单眼形觉剥夺(MD)弱视小鼠视皮质突触可塑性的调控作用及可能的分子机制。方法:实验研究。将54只新生健康昆明小鼠按随机数字表法分为正常组、MD+自由进食(AL)组、MD+CR组,每组18只。小鼠21日龄时构建MD模型,35日龄时去除剥夺因素,63日龄时通过行为学检测视敏度及电生理检测视功能;免疫组织化学及WesternBlot法检测视皮质组织中可塑性相关蛋白突触后致密蛋白95(PSD95)、突触素(SYP)、生长相关蛋白43(GAP-43)等的表达;RT-PCR检测胰岛素样生长因子1(IGF-1)的表达。采用重复测量双因素方差分析比较各组数据差异。结果:最终正常组、MD+AL组、MD+CR组分别有14、18、18只小鼠完成研究。从第1周开始,MD+CR组小鼠体质量百分比的增加明显低于MD+AL组(P<0.05)。MD+AL组小鼠视敏度明显低于正常组和MD+CR组小鼠的视敏度(P<0.05)。MD+AL组小鼠PSD95、GAP-43、SYP的表达均明显低于正常组和MD+CR组小鼠(P<0.05)。MD+AL组小鼠视皮质中IGF-1mRNA水平较正常组和MD+CR组显著降低(P<0.05)。结论:CR能改善成年MD弱视小鼠视觉功能,增加视皮质中可塑性相关蛋白的表达,重新激活视皮质可塑性,其机制可能与其调节IGF-1的表达有关。

近视患者SMILE术后双眼视觉功能变化

目的:探讨飞秒激光小切口角膜基质透镜取出术(SMILE)后双眼视觉功能的变化及其临床意义。方法:前瞻性临床研究。选取2016年3月至2017年10月在中南大学湘雅医院眼科激光治疗中心接受SMILE的近视患者58例(116眼),术前矫正视力≥5.0。所有患者按术前等效球镜度(SE)分为低中度近视(≥-6.00D)组38例(76眼),高度近视(<-6.00D)组20例(40眼)。所有患者按优势眼分为主导眼组58例(58眼)和非主导眼组58例(58眼)。分别测量术前,术后1周、1个月、3个月的调节功能(包括调节幅度、正/负相对调节、双眼调节灵活度、调节反应)及聚散功能(隐斜、正/负融像范围、集合近点)变化。组间手术前后各时间点数据比较采用重复测量方差分析和两样本t检验。结果:①低中度近视组和高度近视组患者术后1周、1个月、3个月SE均较术前减小(P<0.05)。低中度近视组术后3个月主导眼调节幅度、正相对调节均较术前增大(P<0.05),术后1、3个月双眼调节灵活度较术前增大(P<0.05),高度近视组调节幅度、正/负相对调节、双眼调节灵活度手术前后各时间点比较差异均无统计学意义。低中度近视组与高度近视组主导眼与非主导眼调节幅度手术前后各时间点比较差异均无统计学意义。②低中度近视组与高度近视组术后远/近距隐斜、正/负融像范围、调节性集合/调节比值与术前相比差异均无统计学意义。低中度近视组与高度近视组术后集合近点均较术前增大(P<0.05)。结论:SMILE手术对低中度近视患者术后调节功能及聚散功能均具有积极的影响,但对于高度近视患者,术后双眼视觉功能变化不明显。

SMILE术后不同瞳孔直径下视觉质量的比较

目的:探讨近视患者飞秒激光小切口角膜基质透镜取出术(SMILE)后在4 mm和7 mm瞳孔直径下视觉质量变化及其影响因素。方法:前瞻性临床研究。选取2019年2-5月在中南大学湘雅医院行SMILE的近视和近视散光患者46例,年龄18~36岁,均选择右眼数据用于统计。采用欧卡斯视觉质量分析系统测量术眼在4 mm和7 mm瞳孔直径下术前及术后1周、1个月、3个月的调制传递函数(MTF)、调制传递函数截止频率(MTF cutoff)和斯特列尔比(SR)变化。采用主观质量问卷评估患者主观视觉质量。手术前后视力、屈光度、MTF及SR值等比较采用重复测量方差分析。多元线性回归分析SMILE术后3个月视觉质量变化的影响因素。结果:SMILE术后裸眼视力及等效球镜度(SE)较术前明显改善(F=210.976,P<0.001;F=144.129,P<0.001)。SMILE术后3个月,有效性及安全性指数分别为0.97±0.11、1.00±0.06,SE在±0.5 D内的患者占100%。SMILE手术前后不同时间点4 mm及7 mm瞳孔直径下SR、MTF、MTF cutoff值的总体比较,差异均有统计学意义(均P<0.05)。4 mm瞳孔直径(明视环境)下各空间频率下MTF、MTF cutoff、SR先降后升,术后1个月恢复至术前水平。7 mm瞳孔直径(暗视环境)下,MTF cutoff术后1个月恢复至术前水平,MTF、SR在术后3个月恢复至术前水平。暗视环境下,年龄、术前暗瞳大小为SR及空间频率20、25、30 c/d MTF的影响因素(B_(年龄)=-0.440、-0.409、-0.404、-0.389,均P<0.05;B_(暗瞳)=-0.404、-0.333、-0.371、-0.368,均P<0.05),年龄为MTF cutoff及空间频率5、10、15 c/d MTF的影响因素(B=-0.522,P=0.003;B=-0.403,P=0.008;B=-0.409,P=0.008;B=-0.416,P=0.004)。术前暗瞳大小为夜视力、眩光光晕得分的影响因素(B=-0.370,P=0.020;B=-0.417,P=0.013)。结论:SMILE术后早期明、暗环境下视觉质量较术前有所降低,暗环境下视觉质量与术前暗瞳大小及年龄呈负相关。

高度近视SMILE和FS-LASIK术后早期局部调节和中枢视感知觉功能变化

目的:探讨高度近视患者行飞秒激光小切口角膜基质透镜取出术(SMILE)和飞秒激光制瓣准分子激光原位角膜磨镶术(FS-LASIK)术后早期双眼调节功能和视感知觉功能的变化及差异。方法:前瞻性临床研究。选取2019年11月至2020年7月在中南大学湘雅医院眼科中心行SMILE和FS-LASIK手术的患者60例(120眼),其中SMILE组35例(70眼),FS-LASIK组25例(50眼)。测量术前术后1周、1个月、3个月的调节功能(正/负相对调节、调节幅度、调节反应、调节灵活度)和视感知觉功能(知觉眼位、注视稳定性、精细立体视)。用t检验、Wilcoxon检验或λ2检验进行组间数据比较,用重复测量方差分析、LSD-t检验、Kruskal-WallisH或λ2检验进行组内不同时间点间比较。结果:SMILE组正相对调节术后1、3个月较术前提高(P<0.05),单、双眼调节幅度和调节灵活度术后1、3个月均较术后1周提高(P<0.05),术后3个月单眼调节幅度高于术前(P=0.028)。垂直眼位、5 m精细立体视术后1、3个月较术前提高(P<0.05)。FS-LASIK组正相对调节术后1个月较术后1周提高(P=0.02),术后3个月较术前、术后1周提高(P<0.05),单、双眼调节幅度术后3个月较术前,术后1周、1个月提高(P<0.05),单、双眼调节灵活度术后1周低于术前(P<0.05),术后1、3个月较术后1周提高(P<0.05),且在术后3个月恢复到术前水平。5 m精细立体视术后3个月较术后1周提高(P<0.05)。组间比较:FS-LASIK组术前双眼调节幅度(t=-2.067,P=0.043),术后1个月负相对调节(t=-3.181,P=0.03)及术后3个月单眼调节幅度(t=-2.126,P=0.036)高于SMILE组,而术后1周正相对调节(t=-2.249,P=0.028)、单眼调节灵活度(t=3.013,P=0.003),术后1个月双眼调节幅度差值(t=3.031,P=0.004)小于SMILE组。FS-LASIK组术后1周、1个月2.5 m精细立体视和5 m精细立体视,术后3个月5 m精细立体视等级总体低于SMILE组(P<0.05)。结论:SMILE与FS-LASIK不仅能改善高度近视双眼局部调节功能,还能改善大脑知觉层面的高级视功能。且SMILE术后早期视感知觉功能恢复快于FS-LASIK。

Fiber-shaped organic electrochemical transistors for biochemical detections with high sensitivity and stability

Precise and continuous monitoring of biochemicals by biosensors assists to understand physiological functions for various diagnostics and therapeutic applications.For implanted biosensors,small size and flexibility are essential for minimizing tissue damage and achieving accurate detection.However,the active surface area of sensor decreases as the sensor becomes smaller,which will increase the impedance and decrease the signal to noise ratio,resulting in a poor detection limit.Taking advantages of local amplification effect,organic electrochemical transistors(OECTs)constitute promising candidates for high-sensitive monitoring.However,their detections in deep tissues are rarely reported.Herein,we report a family of implantable,fiber-shaped all-in-one OECTs based on carbon nanotube fibers for versatile biochemical detection including H2O2,glucose,dopamine and glutamate.These fiber-shaped OECTs demonstrated high sensitivity,dynamical stability in physiological environment and antiinterference capability.After implantation in mouse brain,7-day dopamine monitoring in vivo was realized for the first time.These fiber-shaped OECTs could be great additions to the"life science"tool box and represent promising avenue for biomedical monitoring.

Polymer-based ?exible bioelectronics

Due to the mechanical mismatch between conventional rigid electronic devices and soft tissues at nature,a lot of interests have been attracted to develop flexible bioelectronics that work well both in vitro and in vivo. To this end, polymers that can be used for both key components and substrates are indispensable to achieve high performances such as high sensitivity and long-term stability for sensing applications.Here we will summarize the recent advances on the synthesis of a variety of polymers, the design of typical architectures and the integration of different functions for the flexible bioelectronic devices. The remaining challenges and promising directions are highlighted to provide inspirations for the future study on the emerging flexible bioelectronics at end.

Ufl1 deficiency causes kidney atrophy associated with disruption of endoplasmic reticulum homeostasis

The UFMylation modification is a novel ubiquitin-like conjugation system,consisting of UBA5(E1),UFC1(E2),UFL1(E3),and the conjugating molecule UFM1.Deficiency in this modification leads to embryonic lethality in mice and diseases in humans.However,the function of UFL1 is poorly characterized.Studies on Ufl1 conditional knockout mice have demonstrated that the deletion of Ufl1 in cardiomyocytes and in intestinal epithelial cells causes heart failure and increases susceptibility to experimentally induced colitis,respectively,suggesting an essential role of UFL1 in the maintenance of the homeostasis in these organs.Yet,its physiological function in other tissues and organs remains completely unknown.In this study,we generate the nephron tubules specific Ufl1 knockout mice and find that the absence of Ufl1 in renal tubular results in kidney atrophy and interstitial fibrosis.In addition,Ufl1 deficiency causes the activation of unfolded protein response and cell apoptosis,which may be responsible for the kidney atrophy and interstitial fibrosis.Collectively,our results have demonstrated the crucial role of UFL1 in regulating kidney function and maintenance of endoplasmic reticulum homeostasis,providing another layer of understanding kidney atrophy.

Design of a virtual reality rehabilitation system for upper limbs that inhibits compensatory movement

Stroke is currently the main cause of death and disability among the elderly in our country.According to medical research,a considerable number of patients with physical disabilities can be recovered through rehabilitation training.However,traditional motor rehabilitation is a continuous,repeated and slow process,and patients tend to feel bored and lose motivation for training.In this paper,we developed a virtual reality rehabilitation system based on Kinect,which is a vision capture sensor,for patients with movement disorders who are at or above Brunnstrom Stage III and have certain motor ability.Through the management platform of the system,physician can obtain the patient's personal information,formulate and adjust the training plan.Patients can control the role in the virtual scene through Kinect sensor,and complete the training action according to the guidance.The system collects the user's motion data in real time and detect the compensation.The system will adaptively evolve to guide the patient to self-correct the compensatory patterns.After the training,the system will evaluate the patients based on the their training performance.Two experiments are also carried out to verify the accuracy of the range of motion and the effectiveness of virtual guidance.It is proved that the virtual reality upper limb rehabilitation training system studied in this paper is reliable,stable,and can guide users to complete the training action and improve the rehabilitation effect.