BACKGROUND: Tissue engineering holds promise for vascular repair and regeneration by mimicking the extracellular matrix of blood vessels. However, achieving a functional and thick vascular wall with aligned fiber architecture by electrospinning remains a significant challenge. METHODS: A novel electrospinning setup was developed that utilizes an auxiliary electrode and a spring. The impact of process parameters on fiber size and morphology was investigated. The structure and functions of the scaffolds were evaluated through material characterization and assessments of cellular biocompatibility. RESULTS: The new setup enabled controlled deposition of fibers in different designed orientations. The fabricated small-diameter vascular scaffolds consisted of an inner layer of longitudinally oriented fibers and an outer layer of circumferentially oriented fibers (L + C vascular scaffold). Key parameters, including rotational speed, the utilization of the auxiliary electrode, and top-to-collector distance (TCD) significantly influenced fiber orientation. Additionally, voltage, TCD, feed rate, needle size, auxiliary electrode and collector-auxiliary electrode distance affected fiber diameter and distribution. Mechanical advantages and improved surface wettability of L + C vascular scaffold were confirmed through tensile testing and water contact angle. Cellular experiments indicated that L + C vascular scaffold facilitated cell adhesion and proliferation, with human umbilical vein endothelial cells and smooth muscle cells attaching and elongating along the fiber direction of the inner and outer layer, respectively. CONCLUSION This study demonstrated the feasibility of fabricating fiber-aligned, thick-walled vascular scaffolds using a modified electrospinning setup. The findings provided insights into how the auxiliary electrode, specific collector influenced fiber deposition, potentially advancing biomimetic vascular scaffold engineering.

BACKGROUND: Tissue engineering holds promise for vascular repair and regeneration by mimicking the extracellular matrix of blood vessels. However, achieving a functional and thick vascular wall with aligned fiber architecture by electrospinning remains a significant challenge. METHODS: A novel electrospinning setup was developed that utilizes an auxiliary electrode and a spring. The impact of process parameters on fiber size and morphology was investigated. The structure and functions of the scaffolds were evaluated through material characterization and assessments of cellular biocompatibility. RESULTS: The new setup enabled controlled deposition of fibers in different designed orientations. The fabricated small-diameter vascular scaffolds consisted of an inner layer of longitudinally oriented fibers and an outer layer of circumferentially oriented fibers (L + C vascular scaffold). Key parameters, including rotational speed, the utilization of the auxiliary electrode, and top-to-collector distance (TCD) significantly influenced fiber orientation. Additionally, voltage, TCD, feed rate, needle size, auxiliary electrode and collector-auxiliary electrode distance affected fiber diameter and distribution. Mechanical advantages and improved surface wettability of L + C vascular scaffold were confirmed through tensile testing and water contact angle. Cellular experiments indicated that L + C vascular scaffold facilitated cell adhesion and proliferation, with human umbilical vein endothelial cells and smooth muscle cells attaching and elongating along the fiber direction of the inner and outer layer, respectively. CONCLUSION This study demonstrated the feasibility of fabricating fiber-aligned, thick-walled vascular scaffolds using a modified electrospinning setup. The findings provided insights into how the auxiliary electrode, specific collector influenced fiber deposition, potentially advancing biomimetic vascular scaffold engineering.

BACKGROUND: Tissue engineering holds promise for vascular repair and regeneration by mimicking the extracellular matrix of blood vessels. However, achieving a functional and thick vascular wall with aligned fiber architecture by electrospinning remains a significant challenge. METHODS: A novel electrospinning setup was developed that utilizes an auxiliary electrode and a spring. The impact of process parameters on fiber size and morphology was investigated. The structure and functions of the scaffolds were evaluated through material characterization and assessments of cellular biocompatibility. RESULTS: The new setup enabled controlled deposition of fibers in different designed orientations. The fabricated small-diameter vascular scaffolds consisted of an inner layer of longitudinally oriented fibers and an outer layer of circumferentially oriented fibers (L + C vascular scaffold). Key parameters, including rotational speed, the utilization of the auxiliary electrode, and top-to-collector distance (TCD) significantly influenced fiber orientation. Additionally, voltage, TCD, feed rate, needle size, auxiliary electrode and collector-auxiliary electrode distance affected fiber diameter and distribution. Mechanical advantages and improved surface wettability of L + C vascular scaffold were confirmed through tensile testing and water contact angle. Cellular experiments indicated that L + C vascular scaffold facilitated cell adhesion and proliferation, with human umbilical vein endothelial cells and smooth muscle cells attaching and elongating along the fiber direction of the inner and outer layer, respectively. CONCLUSION This study demonstrated the feasibility of fabricating fiber-aligned, thick-walled vascular scaffolds using a modified electrospinning setup. The findings provided insights into how the auxiliary electrode, specific collector influenced fiber deposition, potentially advancing biomimetic vascular scaffold engineering.

BACKGROUND: Tissue engineering holds promise for vascular repair and regeneration by mimicking the extracellular matrix of blood vessels. However, achieving a functional and thick vascular wall with aligned fiber architecture by electrospinning remains a significant challenge. METHODS: A novel electrospinning setup was developed that utilizes an auxiliary electrode and a spring. The impact of process parameters on fiber size and morphology was investigated. The structure and functions of the scaffolds were evaluated through material characterization and assessments of cellular biocompatibility. RESULTS: The new setup enabled controlled deposition of fibers in different designed orientations. The fabricated small-diameter vascular scaffolds consisted of an inner layer of longitudinally oriented fibers and an outer layer of circumferentially oriented fibers (L + C vascular scaffold). Key parameters, including rotational speed, the utilization of the auxiliary electrode, and top-to-collector distance (TCD) significantly influenced fiber orientation. Additionally, voltage, TCD, feed rate, needle size, auxiliary electrode and collector-auxiliary electrode distance affected fiber diameter and distribution. Mechanical advantages and improved surface wettability of L + C vascular scaffold were confirmed through tensile testing and water contact angle. Cellular experiments indicated that L + C vascular scaffold facilitated cell adhesion and proliferation, with human umbilical vein endothelial cells and smooth muscle cells attaching and elongating along the fiber direction of the inner and outer layer, respectively. CONCLUSION This study demonstrated the feasibility of fabricating fiber-aligned, thick-walled vascular scaffolds using a modified electrospinning setup. The findings provided insights into how the auxiliary electrode, specific collector influenced fiber deposition, potentially advancing biomimetic vascular scaffold engineering.

BACKGROUND: Tissue engineering holds promise for vascular repair and regeneration by mimicking the extracellular matrix of blood vessels. However, achieving a functional and thick vascular wall with aligned fiber architecture by electrospinning remains a significant challenge. METHODS: A novel electrospinning setup was developed that utilizes an auxiliary electrode and a spring. The impact of process parameters on fiber size and morphology was investigated. The structure and functions of the scaffolds were evaluated through material characterization and assessments of cellular biocompatibility. RESULTS: The new setup enabled controlled deposition of fibers in different designed orientations. The fabricated small-diameter vascular scaffolds consisted of an inner layer of longitudinally oriented fibers and an outer layer of circumferentially oriented fibers (L + C vascular scaffold). Key parameters, including rotational speed, the utilization of the auxiliary electrode, and top-to-collector distance (TCD) significantly influenced fiber orientation. Additionally, voltage, TCD, feed rate, needle size, auxiliary electrode and collector-auxiliary electrode distance affected fiber diameter and distribution. Mechanical advantages and improved surface wettability of L + C vascular scaffold were confirmed through tensile testing and water contact angle. Cellular experiments indicated that L + C vascular scaffold facilitated cell adhesion and proliferation, with human umbilical vein endothelial cells and smooth muscle cells attaching and elongating along the fiber direction of the inner and outer layer, respectively. CONCLUSION This study demonstrated the feasibility of fabricating fiber-aligned, thick-walled vascular scaffolds using a modified electrospinning setup. The findings provided insights into how the auxiliary electrode, specific collector influenced fiber deposition, potentially advancing biomimetic vascular scaffold engineering.

Objective Based on quantile regression analysis, the influencing factors of relapse hospitalization expenses of adult leukemia patients were analyzed. Methods Analyze the composition and influencing factors of hospitalization expenses for leukemia recurrence patients in our hospital. Results From 2017 to 2022 , the per capita hospitalization cost for leukemia patients with recurrence showed an increasing trend year by year. The results of quantile regression model showed that age, payment method , length of stay, times of stay, operation and complications had an impact on the hospitalization expenses of patients at different quantiles, and the difference between different quantiles was statistically significant (P<0.05). Conclusions The quantile regression method can more clearly reflect the distribution of the variables of each factor , we can reduce the hospitalization expenses of patients by improving the coverage rate of medical insurance and controlling the length of stay.

BACKGROUND: Vascular intimal hyperplasia (IH) is one of the key challenges in the clinical application of smalldiameter vascular grafts. Current tissue engineering strategies focus on vascularization and antithrombotics, yet few approaches have been developed to treat IH. Here, we designed a tissue-engineered vascular scaffold with portulaca flavonoid (PTF) composition and biomimetic architecture.METHOD: By electrospinning, PTF is integrated with biodegradable poly(e-caprolactone) (PCL) into a bionic vascular scaffold. The structure and functions of the scaffolds were evaluated based on material characterization and cellular biocompatibility. Human vascular smooth muscle cells (HVSMCs) were cultured on scaffolds for up to 14 days. RESULTS: The incorporation of PTF and preparation parameters during fabrication influences the morphology of the scaffold, including fibre diameter, structure, and orientation. Compared to the PCL scaffold, the scaffolds integrated with bioactive PTF show better hydrophilicity and degradability. HVSMCs seeded on the scaffold alongside the fibres exhibit fusiform-like shapes, indicating that the scaffold can provide contact guidance for cell morphology alterations. This study demonstrates that the PCL/PTF (9.1%) scaffold inhibits the excessive proliferation of HVSMCs without causing cytotoxicity. CONCLUSION The study provides insights into the problem of restenosis caused by IH. This engineered vascular scaffold with complex function and preparation is expected to be applied as a substitute for small-diameter vascular grafts.

Objective To provide evidence for the long-term development of biobank in China,we retrieved literature on biobank for analyzing the development status and trend of Biobank in the world and China.Methods Using the topic of "Biobank" to search articles from 2008 to 2017 in the core collection of Web of ScienceTM,we conducted statistical analysis covering the annual published quantity,the corresponding national/regional distribution,h-index,and the authors of these articles.Results A total number of 2012 articles on Biobank published from 2008 to 2017 were retrieved from the core collection of Web of ScienceTM,in which the annual published quantity on Biobank in the world and China was basically similar,and was on the upward trend;among them,the top three countries/regions with the published quantity were United States,England and China;the top three countries/regions with the h-index were United States,England and the Netherlands,and China ranked fifth;the cooperation degree and co-authorship rate of the authors in China were higher than that in the world.Conclusions The annual growth trend of published quantity on Biobank in China is basically consistent with that in the world.Chinese Biobank plays an important role in the world,and the Chinese researchers on biobank attach more importance to cooperation.However,the scientific research achievements with significant academic influence need to be further improved.Therefore,in order to build a standardized and high-quality biobank,Chinese biobank still needs innovation and exploration continuously.

Objective: To investigate the effects of modified acidic fibroblast growth factor (MaFGF) mediated by nanoliposomes combined with ultrasound-targeted microbubble destruction (UTMD) on left ventricular systolic function in early diabetes mellitus(DM) rats. Methods: The nanoliposomes containing MaFGF(MaFGF-nlip) were prepared by reverse phase evaporation method. Among 60 male Sprague Dawley (SD) rats, 50 rats were randomly selected and were induced to be DM models by streptozotocin(STZ) through intraperitoneal injecting, the other 10 rats as control group. Then DM rats were randomly divided into 4 groups: DM model group, MaFGF solution group, MaFGF-nlip group and MaFGF-nlip+ UTMD group. After the successful induction of DM model, the intervention was performed twice a week.After 12 weeks of intervention, all rats underwent conventional echocardiography and velocity vector imaging (VVI). Left ventricular ejection fraction (LVEF) and left ventricular fraction shortening(LVFS) were measured by conventional echocardiography. The mean peak systolic radial velocity (Vs), radial strain (Sr) and radial strain rate (SRr) of six walls at the papillary muscle level were measured in left ventricular short-axis view by VVI. At last, myocardial tissue of all rats were stained with Sirius red to evaluate myocardial interstitial fibrosis. The level of myocardial apoptosis was evaluated by TUNEL staining, and the changes of myocardial ultrastructure were observed by transmission electron microscopy. Results: The prepared MaFGF-nlip were more rounded, evenly dispersed, and of good stability and high encapsulation efficiency. Twelve weeks later after intervention, LVEF, LVFS, Vs, Sr and SRr in the DM model group were significantly lower than those in the control group (all P<0.05). LVEF, LVFS, Vs, Sr and SRr in the MaFGF-nlip+ UTMD group were significantly higher than those of the DM model group and other intervention groups (all P<0.05). The results of Sirius red staining and Tunel staining showed that CVF and AI in the DM model group were significantly higher than those in the control group (all P<0.05). For MaFGF-nlip+ UTMD group, CVF and AI were significantly decreased compared with the DM model group and other intervention groups(all P<0.05). According to the results of transmission electron microscopy, compared with the DM model group, the improvement of myocardial ultrastructure was the most obvious in the MaFGF-nlip+ UTMD group. Conclusions MaFGF delivered by using nanoliposomes combined with UTMD can improve the left ventricular systolic function in diabetic rats by inhibiting the myocardium cardiac fibrosis and reducing the cardiomyocyte apoptosis.

Objective To provide evidence for the long-term development of biobank in China,we retrieved literature on biobank for analyzing the development status and trend of biobank in the world and China.Methods Using the topic of "Biobank" to search articles from 2008 to 2017 in the core collection of Web of ScienceTM,we conducted statistical analysis covering the annual published quantity,the corresponding national/regional distribution,h-index,and the authors of these articles.Results A total number of 2012 articles on biobank published from 2008 to 2017 were retrieved from the core collection of Web of ScienceTM,in which the annual published quantity on biobank in the world and China was basically similar,and was on the upward trend;among them,the top three countries/regions with the published quantity were United States,England and China;the top three countries/regions with the h-index were United States,England and the Netherlands,and China ranked fifth;the cooperation degree and co-authorship rate of the authors in China were higher than that in the world.Conclusions The annual growth trend of published quantity on biobank in China is basically consistent with that in the world.Chinese biobank plays an important role in the world,and the Chinese researchers on biobank attach more importance to cooperation.However,the scientific research achievements with significant academic influence need to be further improved.Therefore,in order to build a standardized and high-quality biobank,Chinese biobank still needs innovation and exploration continuously.