Ischemic stroke,a neurological impairment caused by cerebral vascular occlusion,accounts for 87%of the cases of stroke.Recent studies have shown that changes in the abundance of metabolites can directly reveal the cel...Ischemic stroke,a neurological impairment caused by cerebral vascular occlusion,accounts for 87%of the cases of stroke.Recent studies have shown that changes in the abundance of metabolites can directly reveal the cellular phenotypes and identify the clinical implications of stroke diagnosis and therapy.However,systematic research to clarify the relationship between biomarkers and the mechanisms of ischemic stroke remains limited.In this study,we reviewed articles on ischemic stroke metabolites from 2005 to 2024,identified metabolites showing significant changes,and constructed a metabolite database based on the findings from 128 studies.The database included 125 differential metabolites detected in a middle cerebral artery occlusion mouse model,246 detected in an middle cerebral artery occlusion rat model,and 764 identified in ischemic stroke patient samples.Differential metabolites from various samples were then screened and classified into positive and negative categories based on their correlation with stroke prognoses.Based on this analysis,three positive metabolites and two negative metabolites were identified.Glutamic acid,glycerol,and 1-octadecanoyl-sn-glycero-3-phosphocholine(LysoPC(18:0))were further recognized as potential biomarkers.Imbalances in metabolic pathways such as alanine,aspartate,and glutamate metabolism as well as the citrate cycle(tricarboxylic acid cycle)were analyzed.These imbalances may influence the pathogenesis of ischemic stroke by altering biological processes such as excitotoxicity,oxidative stress,inflammation,and energy metabolism.The identification and analysis of these potential biomarkers may provide valuable targets and strategies for prediction,diagnosis,and prognostic assessment of ischemic stroke.展开更多
BACKGROUND Diabetes is characterized by insulin resistance as well as impaired insulin production,withβ-cell dysfunction playing a critical role in disease progression.Exercise is known to improve insulin sensitivity...BACKGROUND Diabetes is characterized by insulin resistance as well as impaired insulin production,withβ-cell dysfunction playing a critical role in disease progression.Exercise is known to improve insulin sensitivity,but its effects on pancreatic islet quality and function remain poorly understood.This work hypothesized that swimming training enhances glycemic control and insulin secretion by upregulating the insulin-like growth factor 1(IGF-1)/phosphatidylinositol 3-kinase/protein kinase B(PI3K/AKT)pathway in streptozotocin(STZ)-induced diabetic rats.AIM To investigate the effects of swimming on pancreatic islet quality and function in STZ-induced diabetic rats via the IGF-1/PI3K/AKT pathway.METHODS Twenty-six Sprague-Dawley rats were grouped into diabetic and control groups,with each group further split into exercise and sedentary subgroups.Diabetic rats were induced with STZ.The exercise groups underwent swimming training for 60 minutes/day,5 days/week,for 8 weeks.Body weight,food intake,blood glucose,insulin,lipids,and muscle glycogen were measured.Pancreatic islet morphology and the protein expression levels of IGF-1,PI3K,and AKT were analyzed.Data were analyzed using two-way repeated-measure ANOVA,followed by Tukey’s post-hoc test.RESULTS Exercise training significantly improved body weight[diabetic exercise group(D-Ex):390.66±50.14 g vs diabetic sedentary group(D-Sed):315.89±50.12 g,P<0.05],reduced blood glucose(D-Ex:12.21±4.43 mmol/L vs D-Sed:17.79±2.05 mmol/L,P<0.05),and increased insulin levels(D-Ex:53.50±15.31 pmol/L vs D-Sed:25.31±10.23 pmol/L,P<0.05)in diabetic rats.It also enhanced islet morphology,increased IGF-1 expression,and activated the PI3K/AKT pathway(P<0.05).In-vitro experiments confirmed that IGF-1 positively regulated insulin expression and inhibitedβ-cell apoptosis via the PI3K/AKT pathway.CONCLUSION Exercise training improves pancreatic islet quality and function in diabetic rats by modulating the IGF-1/PI3K/AKT pathway,highlighting its therapeutic potential for diabetes management.展开更多
Environment serves as the pivotal medium to produce fermented food,with fluctuations in environmental factors exerting a profound impact on the modulation of fermentation microbial communities.Such shifts are crucial ...Environment serves as the pivotal medium to produce fermented food,with fluctuations in environmental factors exerting a profound impact on the modulation of fermentation microbial communities.Such shifts are crucial for the distinctiveness of fermented food flavor and the variability in quality.Chinese liquor(Baijiu)is one of the typical representatives of spontaneous fermented food.In this review,the multifaceted relationship between regional environmental attributes and the fermentation dynamics of Baijiu was examined,with a spotlight on the strong-flavor,sauce-flavor,and light-flavor varieties.It reveals the influence of regional environmental factors and brewing environmental factors on microbial function and metabolism,which results in the formation of unique flavor characteristics of Baijiu.The 9 main factors affecting the microecology of Baijiu fermentation were further explored,including environmental sensitivity,microbial interactions,biogeographic patterns,and key abiotic factors such as temperature and humidity.Environmental factor management is crucial for controlling microbial community in fermentation.Intelligent detection of the fermentation system is combined with artificial intelligence to realize the digitalization of Baijiu fermentation,with a view to further studying the environmental mechanism or quantitative control relationship of natural fermentation,improving the environmental stability of natural fermentation,and promoting the mechanization and intelligence of fermentation production.展开更多
Abstract:Microwave-based destressing is regarded as a promising approach for proactively preventing and controlling rockbursts in deep hard rock.As the fracturing degree of microwave-induced boreholes is affected by b...Abstract:Microwave-based destressing is regarded as a promising approach for proactively preventing and controlling rockbursts in deep hard rock.As the fracturing degree of microwave-induced boreholes is affected by borehole diameter,water content,mineral content,etc.,it is difficult to establish relationships between them.The research aims to unify various factors with heating rate and temperature,and establish a microwave parameter design method based thereon.Tests on microwave-induced borehole fracturing in hard rock with different or similar heating rates and temperatures under true triaxial stress were conducted.The test results show that both heating rate and temperature promote radial fracture of the rock,but have little effect on the development of axial fractures.Compared with heating rate,temperature is a more critical factor influencing microwave-induced fracturing.The effects of the heating rate on rock fracturing become noticeable only at higher temperatures.When the heating rate and temperature are similar but the diameter of the boreholes is different,the crack distribution,total length,wave velocity attenuation,and fracture process are similar.It is feasible to reverse-design microwave parameters under different borehole diameters based on the heating rate and temperature.Thermal fracturing of basalt shows a distinct threshold effect between 150℃ and 195℃(with an average of about 175℃),and the heating rate and borehole diameter exert minor influences thereon.The results provide guidance for the design of microwave parameters in practice.展开更多
UV-absorbing additives have recently been demonstrated to be effective interfacial modifiers that simultaneously enhance the UV stability and crystallization of halide perovskite.However,the underlying mechanisms conc...UV-absorbing additives have recently been demonstrated to be effective interfacial modifiers that simultaneously enhance the UV stability and crystallization of halide perovskite.However,the underlying mechanisms concerning UV absorption,defect passivation,and efficacy optimization of these additives remain unresolved.Herein,two UV tautomeric absorbers(UV320 and UV327)are selected as defect-passivators for perovskites.The keto-enol tautomeric evolution processes and corresponding defect passivation performance/mechanism of both the original molecules and their tautomers are thoroughly compared and elucidated through experimental characterizations and density functional theory calculations.The additional carbonyl(-C=O)groups generated through the keto-enol tautomeric process triggered by the Cl atom in UV327 ultimately provide superior chemical coordination and enhanced defect-passivation capability compared to the original counterparts.Moreover,the versatility of K-UV327 is further demonstrated by its optimization of SnO_(2)film quality,interfacial energy band alignment,charge extraction efficiency,and defect state suppression.The photodetector optimized by UV327's tautomer achieves an ultralow dark current density of 3.22×10^(-10)A cm^(-2),an enhanced linear dynamic range of 94.14 d B,and a fast response time of 23.35/26.19μs.Notably,unencapsulated devices maintain a stable response at 3900 Hz following 300 h exposure to 40%±5%relative humidity and 30 h UV irradiation.展开更多
Electron beam selective melting (EBSM) is a promising additive manufacturing (AM) technology. The EBSM process consists of three major procedures:(1) spreading a powder layer, (2) preheating to slightly sinte...Electron beam selective melting (EBSM) is a promising additive manufacturing (AM) technology. The EBSM process consists of three major procedures:(1) spreading a powder layer, (2) preheating to slightly sinter the powder, and (3) selectively melting the powder bed. The highly transient multi-physics phenomena involved in these procedures pose a significant challenge for in situ experimental observation and measurement. To advance the understanding of the physical mechanisms in each procedure, we leverage high- fidelity modeling and post-process experiments. The models resemble the actual fabrication procedures, including (1) a powder-spreading model using the discrete element method (DEM), (2) a phase field (PF) model of powder sintering (solid-state sintering), and (3) a powder-melting (liquid-state sintering) model using the finite volume method (FVM). Comprehensive insights into all the major procedures are provided, which have rarely been reported. Preliminary simulation results (including powder particle packing within the powder bed, sintering neck formation between particles, and single-track defects) agree qualitatively with experiments, demonstrating the ability to understand the mechanisms and to guide the design and optimization of the experimental setup and manufacturing process.展开更多
Manipulation of light-matter interaction is critical in modern physics, especially in the strong coupling regime, where the generated half-light, half-matter bosonic quasiparticles as polaritons are important for fund...Manipulation of light-matter interaction is critical in modern physics, especially in the strong coupling regime, where the generated half-light, half-matter bosonic quasiparticles as polaritons are important for fundamental quantum science and applications of optoelectronics and nonlinear optics. Two-dimensional transition metal dichalcogenides (TMDs) are ideal platforms to investigate the strong coupling because of their huge exciton binding energy and large absorption coefficients. Further studies on strong exciton-plasmon coupling by combining TMDs with metallic nanostructures have generated broad interests in recent years. However, because of the huge plasmon radiative damping, the observation of strong coupling is significantly limited at room temperature. Here, we demonstrate that a large Rabi splitting (~300 meV) can be achieved at ambient conditions in the strong coupling regime by embedding Ag-WS2 heterostructure in an optical microcavity. The generated quasiparticle with part-plasmon, part-exciton and part-light is analyzed with Hopfield coefficients that are calculated by using three-coupled oscillator model. The resulted plasmon-exciton polaritonic hybrid states can efficiently enlarge the obtained Rabi splitting, which paves the way for the practical applications of polaritonic devices based on ultrathin materials.展开更多
Laser scanning confocal endomicroscope(LSCEM)has emerged as an imaging modality which provides noninvasive,in vivo imaging of biological tissue on a microscopic scale.Scientific visualizations for LSCEM datasets captu...Laser scanning confocal endomicroscope(LSCEM)has emerged as an imaging modality which provides noninvasive,in vivo imaging of biological tissue on a microscopic scale.Scientific visualizations for LSCEM datasets captured by current imaging systems require these datasets to be fully acquired and brought to a separate rendering machine.To extend the features and capabilities of this modality,we propose a system which is capable of performing realtime visualization of LSCEM datasets.Using field-programmable gate arrays,our system performs three tasks in parallel:(1)automated control of dataset acquisition;(2)imaging-rendering system synchronization;and(3)realtime volume rendering of dynamic datasets.Through fusion of LSCEM imaging and volume rendering processes,acquired datasets can be visualized in realtime to provide an immediate perception of the image quality and biological conditions of the subject,further assisting in realtime cancer diagnosis.Subsequently,the imaging procedure can be improved for more accurate diagnosis and reduce the need for repeating the process due to unsatisfactory datasets.展开更多
基金supported by the National Natural Science Foundation of China,No.82104144(to LZ)The Fifth Affiliated Hospital of Sun Yat-sen University of Outstanding Young Talents Cultivation Program,No.3320104100322(to WC)+1 种基金“Five Five”Young Talents Program,No.220904094231(to LZ)the Guangdong-Hong Kong-Macao University Joint Laboratory of Interventional Medicine Foundation of Guangdong Province,No.2023LSYS001(to WC).
文摘Ischemic stroke,a neurological impairment caused by cerebral vascular occlusion,accounts for 87%of the cases of stroke.Recent studies have shown that changes in the abundance of metabolites can directly reveal the cellular phenotypes and identify the clinical implications of stroke diagnosis and therapy.However,systematic research to clarify the relationship between biomarkers and the mechanisms of ischemic stroke remains limited.In this study,we reviewed articles on ischemic stroke metabolites from 2005 to 2024,identified metabolites showing significant changes,and constructed a metabolite database based on the findings from 128 studies.The database included 125 differential metabolites detected in a middle cerebral artery occlusion mouse model,246 detected in an middle cerebral artery occlusion rat model,and 764 identified in ischemic stroke patient samples.Differential metabolites from various samples were then screened and classified into positive and negative categories based on their correlation with stroke prognoses.Based on this analysis,three positive metabolites and two negative metabolites were identified.Glutamic acid,glycerol,and 1-octadecanoyl-sn-glycero-3-phosphocholine(LysoPC(18:0))were further recognized as potential biomarkers.Imbalances in metabolic pathways such as alanine,aspartate,and glutamate metabolism as well as the citrate cycle(tricarboxylic acid cycle)were analyzed.These imbalances may influence the pathogenesis of ischemic stroke by altering biological processes such as excitotoxicity,oxidative stress,inflammation,and energy metabolism.The identification and analysis of these potential biomarkers may provide valuable targets and strategies for prediction,diagnosis,and prognostic assessment of ischemic stroke.
文摘BACKGROUND Diabetes is characterized by insulin resistance as well as impaired insulin production,withβ-cell dysfunction playing a critical role in disease progression.Exercise is known to improve insulin sensitivity,but its effects on pancreatic islet quality and function remain poorly understood.This work hypothesized that swimming training enhances glycemic control and insulin secretion by upregulating the insulin-like growth factor 1(IGF-1)/phosphatidylinositol 3-kinase/protein kinase B(PI3K/AKT)pathway in streptozotocin(STZ)-induced diabetic rats.AIM To investigate the effects of swimming on pancreatic islet quality and function in STZ-induced diabetic rats via the IGF-1/PI3K/AKT pathway.METHODS Twenty-six Sprague-Dawley rats were grouped into diabetic and control groups,with each group further split into exercise and sedentary subgroups.Diabetic rats were induced with STZ.The exercise groups underwent swimming training for 60 minutes/day,5 days/week,for 8 weeks.Body weight,food intake,blood glucose,insulin,lipids,and muscle glycogen were measured.Pancreatic islet morphology and the protein expression levels of IGF-1,PI3K,and AKT were analyzed.Data were analyzed using two-way repeated-measure ANOVA,followed by Tukey’s post-hoc test.RESULTS Exercise training significantly improved body weight[diabetic exercise group(D-Ex):390.66±50.14 g vs diabetic sedentary group(D-Sed):315.89±50.12 g,P<0.05],reduced blood glucose(D-Ex:12.21±4.43 mmol/L vs D-Sed:17.79±2.05 mmol/L,P<0.05),and increased insulin levels(D-Ex:53.50±15.31 pmol/L vs D-Sed:25.31±10.23 pmol/L,P<0.05)in diabetic rats.It also enhanced islet morphology,increased IGF-1 expression,and activated the PI3K/AKT pathway(P<0.05).In-vitro experiments confirmed that IGF-1 positively regulated insulin expression and inhibitedβ-cell apoptosis via the PI3K/AKT pathway.CONCLUSION Exercise training improves pancreatic islet quality and function in diabetic rats by modulating the IGF-1/PI3K/AKT pathway,highlighting its therapeutic potential for diabetes management.
基金financially supported by the National Natural Science Foundation of China(22138004)National Treasure Ecological Research Synergetic Innovation Center.
文摘Environment serves as the pivotal medium to produce fermented food,with fluctuations in environmental factors exerting a profound impact on the modulation of fermentation microbial communities.Such shifts are crucial for the distinctiveness of fermented food flavor and the variability in quality.Chinese liquor(Baijiu)is one of the typical representatives of spontaneous fermented food.In this review,the multifaceted relationship between regional environmental attributes and the fermentation dynamics of Baijiu was examined,with a spotlight on the strong-flavor,sauce-flavor,and light-flavor varieties.It reveals the influence of regional environmental factors and brewing environmental factors on microbial function and metabolism,which results in the formation of unique flavor characteristics of Baijiu.The 9 main factors affecting the microecology of Baijiu fermentation were further explored,including environmental sensitivity,microbial interactions,biogeographic patterns,and key abiotic factors such as temperature and humidity.Environmental factor management is crucial for controlling microbial community in fermentation.Intelligent detection of the fermentation system is combined with artificial intelligence to realize the digitalization of Baijiu fermentation,with a view to further studying the environmental mechanism or quantitative control relationship of natural fermentation,improving the environmental stability of natural fermentation,and promoting the mechanization and intelligence of fermentation production.
基金the financial support from the Na-tional Key Research and Development Program of China(Grant No.2023YFC2907202)the Postdoctoral Fellowship Program of CPSF(Grant No.GZB20240129).
文摘Abstract:Microwave-based destressing is regarded as a promising approach for proactively preventing and controlling rockbursts in deep hard rock.As the fracturing degree of microwave-induced boreholes is affected by borehole diameter,water content,mineral content,etc.,it is difficult to establish relationships between them.The research aims to unify various factors with heating rate and temperature,and establish a microwave parameter design method based thereon.Tests on microwave-induced borehole fracturing in hard rock with different or similar heating rates and temperatures under true triaxial stress were conducted.The test results show that both heating rate and temperature promote radial fracture of the rock,but have little effect on the development of axial fractures.Compared with heating rate,temperature is a more critical factor influencing microwave-induced fracturing.The effects of the heating rate on rock fracturing become noticeable only at higher temperatures.When the heating rate and temperature are similar but the diameter of the boreholes is different,the crack distribution,total length,wave velocity attenuation,and fracture process are similar.It is feasible to reverse-design microwave parameters under different borehole diameters based on the heating rate and temperature.Thermal fracturing of basalt shows a distinct threshold effect between 150℃ and 195℃(with an average of about 175℃),and the heating rate and borehole diameter exert minor influences thereon.The results provide guidance for the design of microwave parameters in practice.
基金the financial support from Xingdian Creative Industry Talent Project of Yunnan Province(No.XDYC-CYCX-2024-0025)Science and Technology Special Projects of Southwest United Graduate School and Innovative Team of Yunnan Province。
文摘UV-absorbing additives have recently been demonstrated to be effective interfacial modifiers that simultaneously enhance the UV stability and crystallization of halide perovskite.However,the underlying mechanisms concerning UV absorption,defect passivation,and efficacy optimization of these additives remain unresolved.Herein,two UV tautomeric absorbers(UV320 and UV327)are selected as defect-passivators for perovskites.The keto-enol tautomeric evolution processes and corresponding defect passivation performance/mechanism of both the original molecules and their tautomers are thoroughly compared and elucidated through experimental characterizations and density functional theory calculations.The additional carbonyl(-C=O)groups generated through the keto-enol tautomeric process triggered by the Cl atom in UV327 ultimately provide superior chemical coordination and enhanced defect-passivation capability compared to the original counterparts.Moreover,the versatility of K-UV327 is further demonstrated by its optimization of SnO_(2)film quality,interfacial energy band alignment,charge extraction efficiency,and defect state suppression.The photodetector optimized by UV327's tautomer achieves an ultralow dark current density of 3.22×10^(-10)A cm^(-2),an enhanced linear dynamic range of 94.14 d B,and a fast response time of 23.35/26.19μs.Notably,unencapsulated devices maintain a stable response at 3900 Hz following 300 h exposure to 40%±5%relative humidity and 30 h UV irradiation.
文摘Electron beam selective melting (EBSM) is a promising additive manufacturing (AM) technology. The EBSM process consists of three major procedures:(1) spreading a powder layer, (2) preheating to slightly sinter the powder, and (3) selectively melting the powder bed. The highly transient multi-physics phenomena involved in these procedures pose a significant challenge for in situ experimental observation and measurement. To advance the understanding of the physical mechanisms in each procedure, we leverage high- fidelity modeling and post-process experiments. The models resemble the actual fabrication procedures, including (1) a powder-spreading model using the discrete element method (DEM), (2) a phase field (PF) model of powder sintering (solid-state sintering), and (3) a powder-melting (liquid-state sintering) model using the finite volume method (FVM). Comprehensive insights into all the major procedures are provided, which have rarely been reported. Preliminary simulation results (including powder particle packing within the powder bed, sintering neck formation between particles, and single-track defects) agree qualitatively with experiments, demonstrating the ability to understand the mechanisms and to guide the design and optimization of the experimental setup and manufacturing process.
基金the National Key Research and Development Program of China (Grant No. 2017YFA0205700)National Basic Research Program of China (Grant No. 2015CB932403, 2017YFA0206000)+3 种基金National Natural Science Foundation of China (Grant Nos. 11674012, 61521004, 21790364, 61422501, and 11374023)Beijing Natural Science Foundation (Z180011, and L140007)Foundation for the Author of National Excellent Doctoral Dissertation of PR China (Grant No. 201420)National Program for Support of Top-notch Young Professionals (Grant No. W02070003).
文摘Manipulation of light-matter interaction is critical in modern physics, especially in the strong coupling regime, where the generated half-light, half-matter bosonic quasiparticles as polaritons are important for fundamental quantum science and applications of optoelectronics and nonlinear optics. Two-dimensional transition metal dichalcogenides (TMDs) are ideal platforms to investigate the strong coupling because of their huge exciton binding energy and large absorption coefficients. Further studies on strong exciton-plasmon coupling by combining TMDs with metallic nanostructures have generated broad interests in recent years. However, because of the huge plasmon radiative damping, the observation of strong coupling is significantly limited at room temperature. Here, we demonstrate that a large Rabi splitting (~300 meV) can be achieved at ambient conditions in the strong coupling regime by embedding Ag-WS2 heterostructure in an optical microcavity. The generated quasiparticle with part-plasmon, part-exciton and part-light is analyzed with Hopfield coefficients that are calculated by using three-coupled oscillator model. The resulted plasmon-exciton polaritonic hybrid states can efficiently enlarge the obtained Rabi splitting, which paves the way for the practical applications of polaritonic devices based on ultrathin materials.
文摘Laser scanning confocal endomicroscope(LSCEM)has emerged as an imaging modality which provides noninvasive,in vivo imaging of biological tissue on a microscopic scale.Scientific visualizations for LSCEM datasets captured by current imaging systems require these datasets to be fully acquired and brought to a separate rendering machine.To extend the features and capabilities of this modality,we propose a system which is capable of performing realtime visualization of LSCEM datasets.Using field-programmable gate arrays,our system performs three tasks in parallel:(1)automated control of dataset acquisition;(2)imaging-rendering system synchronization;and(3)realtime volume rendering of dynamic datasets.Through fusion of LSCEM imaging and volume rendering processes,acquired datasets can be visualized in realtime to provide an immediate perception of the image quality and biological conditions of the subject,further assisting in realtime cancer diagnosis.Subsequently,the imaging procedure can be improved for more accurate diagnosis and reduce the need for repeating the process due to unsatisfactory datasets.
