BACKGROUND Organ transplantation has emerged as a globally prevalent therapeutic modality for end-stage organ failure,yet the post-transplantation trajectory is increasingly complicated by a spectrum of metabolic sequ...BACKGROUND Organ transplantation has emerged as a globally prevalent therapeutic modality for end-stage organ failure,yet the post-transplantation trajectory is increasingly complicated by a spectrum of metabolic sequelae,with obesity emerging as a critical clinical challenge.AIM To systematically review the multifactorial mechanisms underlying obesity following organ transplantation and to integrate evidence from pharmacological,behavioral,and molecular perspectives,thereby providing a foundation for targeted interventions.METHODS We conducted a systematic search in PubMed and Web of Science for literature published from 2020 to 15 July 2025.The search strategy incorporated terms including“obesity”,“overweight”and“post organ transplantation”.Only randomized controlled trials,meta-analyses,and systematic reviews were included.Non-empirical publications and irrelevant studies were excluded.Data extraction and quality assessment were performed by two independent reviewers,with disagreements resolved by a third researcher.RESULTS A total of 1457 articles were initially identified,of which 146 met the inclusion criteria.These studies encompassed liver,kidney,heart,and lung transplant recipients.Key findings indicate that immunosuppressive drugs-especially corticosteroids and calcineurin inhibitors-promote hyperphagia,insulin resistance,and dyslipidemia.Post-transplant sedentary behavior and hypercaloric diets further contribute to positive energy balance.At the molecular level,immunosuppressants disrupt adipokine signaling(e.g.,leptin and adiponectin),induce inflammatory and oxidative stress responses,and activate adipogenic pathways leading to lipid accumulation.CONCLUSION Post-transplant obesity arises from a complex interplay of pharmacological,behavioral,and molecular factors.A multidisciplinary approach-incorporating pharmacological modification,nutritional management,physical activity,and molecular-targeted therapies-is essential to mitigate obesity and improve transplant outcomes.Further large-scale and mechanistic studies are warranted to establish evidence-based preventive and treatment strategies.展开更多
Triclosan(TCS) poses harmful risks to ecosystems and human health owing to its endocrine-disrupting effects.Therefore,developing an efficient and sustainable technology to degrade TCS is urgently needed.Herein,cobalt ...Triclosan(TCS) poses harmful risks to ecosystems and human health owing to its endocrine-disrupting effects.Therefore,developing an efficient and sustainable technology to degrade TCS is urgently needed.Herein,cobalt oxyhydroxide @covalent organic frameworks(CoOOH@COFs) S-scheme heterojunction was synthesized,which combined the visible-light-driven photocatalysis and peroxymonosulfate(PMS) activation to synergistically generate abundant reactive oxygen species(ROSs) for TCS degradation.The degradation efficiency of TCS reached 100 % within 8 min in the Vis-CoOOH@COFs/PMS system,and the reaction rate constant was 0.456 min^(-1),which was nearly 1.90 and 2.85 times that of single Co OOH and COFs,and2.36 times that under dark condition,respectively.The density functional theory(DFT) calculations confirmed the energy band bending of CoOOH@COFs and S-scheme charge transport from COFs to Co OOH.Both experimental and theoretical analyses indicated that Co OOH@COFs in photocatalytic-PMS activation systems synergistically facilitated photo-generated carrier separation,enhanced interfacial electron transfer,accelerated PMS activation,and generated multiple ROSs.In particular,photogenerated electrons(e^(-))accelerated the Co(Ⅲ)/Co(Ⅱ) redox cycle,while the PMS captured the e-,which significantly decreased the charge combination of Co OOH@COFs.Radicals(O_(2)^(·-),^(·)OH,and SO_(4)^(·-)) and non-radicals(such as ^(1)O_(2),h^(+),and e^(-)) were both presented in the Vis-CoOOH@COFs/PMS system,with O_(2)^(-) playing a dominant role in TCS degradation.Furthermore,the pathway of TCS degradation and toxicity of intermediates were explored by DFT calculation and transformation product identification.Importantly,the environmentally friendly CoOOH@COFs S-scheme heterojunction exhibited excellent stability and reusability.In conclusion,this study innovatively designed an S-scheme heterojunction in the photocatalytic-PMS activation system,providing guidance and theoretical support for efficient and eco-friendly wastewater treatment.展开更多
In the quest to enhance energy efficiency and reduce environmental impact in the transportation sector,the recovery of waste heat from diesel engines has become a critical area of focus.This study provided an exhausti...In the quest to enhance energy efficiency and reduce environmental impact in the transportation sector,the recovery of waste heat from diesel engines has become a critical area of focus.This study provided an exhaustive thermodynamic analysis optimizing Organic Rankine Cycle(ORC)systems forwaste heat recovery fromdiesel engines.Thestudy assessed the performance of five candidateworking fluids—R11,R123,R113,R245fa,and R141b—under a range of operating conditions,specifically varying overheat temperatures and evaporation pressures.The results indicated that the choice of working fluid substantially influences the system’s exergetic efficiency,net output power,and thermal efficiency.R245fa showed an outstanding net output power of 30.39 kW at high overheat conditions,outperforming R11,which is significant for high-temperature waste heat recovery.At lower temperatures,R11 and R113 demonstrated higher exergetic efficiencies,with R11 reaching a peak exergetic efficiency of 7.4%at an evaporation pressure of 10 bar and an overheat of 10℃.The study also revealed that controlling the overheat and optimizing the evaporation pressure are crucial for enhancing the net output power of the ORC system.Specifically,at an evaporation pressure of 30 bar and an overheat of 0℃,R113 exhibited the lowest exergetic destruction of 544.5 kJ/kg,making it a suitable choice for minimizing irreversible losses.These findings are instrumental for understanding the performance of ORC systems in waste heat recovery applications and offer valuable insights for the design and operation of more efficient and environmentally friendly diesel engine systems.展开更多
The author puts forward the proposition of Complexity and Self Organized Criticality of Solid Earth System in the light of: (1) the science of complexity studies the mechanisms of emergence of complexity and is...The author puts forward the proposition of Complexity and Self Organized Criticality of Solid Earth System in the light of: (1) the science of complexity studies the mechanisms of emergence of complexity and is the science of the 21st century, (2) the study of complexity of the earth system would be one of the growing points occupying a strategic position in the development of geosciences in the 21st century. By the proposition we try to cogitate from a new viewpoint the ancient yet ever new solid earth system. The author abstracts the fundamental problem of the solid earth system from the essence of the generalized geological systems and processes which reads: the complexity and self organized criticality of the global nature, structure and dynamical behavior of the whole solid earth system emerging from the multiple coupling and superposition of non linear interactions among the multicomponents of the earths material and the multiple generalized geological (geological, geophysical, and geochemical) processes . Starting from this cognizance the author proposes eight major themes and the methodology of researches on the complexity and self organized criticality of the solid earth system.展开更多
Organic material combined with inorganic fertilizer has been shown to greatly improve crop yield and maintain soil fertility globally. However, it remains unclear if crop yield and soil fertility can be sustained in t...Organic material combined with inorganic fertilizer has been shown to greatly improve crop yield and maintain soil fertility globally. However, it remains unclear if crop yield and soil fertility can be sustained in the long term under the combined application of organic and inorganic fertilizers. Three long-term field trials were conducted to investigate the effects of organic amendments on the grain sustainable yield index(SYI), soil fertility index(SFI)and nutrient balance in maize–wheat cropping systems of central and southern China during 1991–2019. Five treatments were included in the trials: 1) no fertilization(control);2) balanced mineral fertilization(NPK);3) NPK plus manure(NPKM);4) high dose of NPK plus manure(1.5NPKM);and 5) NPK plus crop straw(NPKS). Over time, the grain yields of wheat and maize showed an increasing trend in all four fertilization treatments at the Yangling(YL) and Zhengzhou(ZZ) locations, while they declined at Qiyang(QY). The grain yield in the NPKM and 1.5NPKM treatments gradually exceeded that of the NPK and NPKS treatments at the QY site. The largest SYI was recorded in the NPKM treatment across the three sites, suggesting that inorganic fertilizer combined with manure can effectively improve crop yield sustainability. Higher SYI values were recorded at the YL and ZZ sites than at the QY site, possibly because the soil was more acid at QY. The key factors affecting grain yield were soil available phosphorus(AP) and available potassium(AK) at the YL and ZZ sites, and pH and AP at the QY site.All fertilization treatments resulted in soil N and P surpluses at the three sites, but soil K surpluses were recorded only at the QY site. The SFI was greater in the 1.5NPKM, NPKM and NPKS treatments than in the NPK treatment by 13.3–40.0 and 16.4–63.6% at the YL and ZZ sites, respectively, and was significantly higher in the NPKM and 1.5NPKM treatments than in the NPK and NPKS treatments at the QY site. A significant, positive linear relationship was found between SFI and crop yield, and SYI and nutrient balance, indicating that grain yield and its sustainability significantly increased with increasing soil fertility. The apparent N, P and K balances positively affected SFI.This study suggests that the appropriate amount of manure mixed with mineral NPK fertilizer is beneficial to the development of sustainable agriculture, which effectively increases the crop yield and yield sustainability by improving soil fertility.展开更多
Cell cultured meat has been extensively studied as an environmentally friendly,energy-saving and more effective technology.However,there are many technical bottlenecks,especially the regulatory mechanism and manufactu...Cell cultured meat has been extensively studied as an environmentally friendly,energy-saving and more effective technology.However,there are many technical bottlenecks,especially the regulatory mechanism and manufacturing method of in vitro myogenesis.Based on an edible modified silk protein scaffold,with 3D culturing,in situ differentiated and transcriptome analysis,this study describes novel scaffolds and fabrication methods for cell cultured meat.The results showed that the effective space and utilization efficiency for cell culture of the scaffold is 26–1000 that of the traditional culture dish;it could form a tissue-like structure.Transcriptomics revealed the regulatory pathways and key factors of different cycles.It clarifies that the multi-cycle process of myoblast myogenesis in vitro is different from the single feedback regulation in vivo.More importantly,a novel scaffold-based cell cultured meat manufacturing method was developed,further develop a new tissue culture solution that is different from existing cell culture meat production.For manufacturing processes,it provides a new cell culture meat technology system,provides a theoretical basis for the regulation of cell proliferation and muscle growth,and lays the technical foundation for in situ tissue culture of cell cultured meat in vitro.展开更多
To make agricultural systems sustainable in terms of their greenness and efficiency,optimizing the tillage and fertilization practices is essential.To assess the effects of tilling and fertilization practices in wheat...To make agricultural systems sustainable in terms of their greenness and efficiency,optimizing the tillage and fertilization practices is essential.To assess the effects of tilling and fertilization practices in wheat-maize cropping systems,a three-year field experiment was designed to quantify the carbon footprint(CF)and energy efficiency of the cropping systems in the North China Plain.The study parameters included four tillage practices(no tillage(NT),conventional tillage(CT),rotary tillage(RT),and subsoiling rotary tillage(SRT))and two fertilizer regimes(inorganic fertilizer(IF)and hybrid fertilizer with organic and inorganic components(HF)).The results indicated that the most prominent energy inputs and greenhouse gas(GHG)emissions could be ascribed to the use of fertilizers and fuel consumption.Under the same fertilization regime,ranking the tillage patterns with respect to the value of the crop yield,profit,CF,energy use efficiency(EUE)or energy productivity(EP)for either wheat or maize always gave the same sequence of SRT>RT>CT>NT.For the same tillage,the energy consumption associated with HF was higher than IF,but its GHG emissions and CF were lower while the yield and profit were higher.In terms of overall performance,tilling is more beneficial than NT,and reduced tillage practices(RT and SRT)are more beneficial than CT.The fertilization regime with the best overall performance was HF.Combining SRT with HF has significant potential for reducing CF and increasing EUE,thereby improving sustainability.Adopting measures that promote these optimizations can help to overcome the challenges posed by a lack of food security,energy crises and ecological stress.展开更多
Membrane technology holds significant potential for augmenting or partially substituting conventional separation techniques,such as heatdriven distillation,thereby reducing energy consumption.Organic solvent nanofiltr...Membrane technology holds significant potential for augmenting or partially substituting conventional separation techniques,such as heatdriven distillation,thereby reducing energy consumption.Organic solvent nanofiltration represents an advanced membrane separation technology capable of discerning molecules within a molecular weight range of approximately 100-1000 Da in organic solvents,offering low energy requirements and minimal carbon footprints.Molecular separation in non-polar solvent system,such as toluene,n-hexane,and n-heptane,has gained paramount importance due to their extensive use in the pharmaceutical,biochemical,and petrochemical industries.In this review,we presented recent advancements in membrane materials,membrane fabrication techniques and their promising applications for separation in nonpolar solvent system,encompassing hydrocarbon separation,bioactive molecule purification and organic solvent recovery.Furthermore,this review highlighted the challenges and opportunities associated with membrane scale-up strategies and the direct translation of this promising technology into industrial applications.展开更多
The rapid growth of artificial intelligence has accelerated data generation,which increasingly exposes the limitations faced by traditional computational architectures,particularly in terms of energy consumption and d...The rapid growth of artificial intelligence has accelerated data generation,which increasingly exposes the limitations faced by traditional computational architectures,particularly in terms of energy consumption and data latency.In contrast,data-centric computing that integrates processing and storage has the potential of reducing latency and energy usage.Organic optoelectronic synaptic transistors have emerged as one type of promising devices to implement the data-centric com-puting paradigm owing to their superiority of flexibility,low cost,and large-area fabrication.However,sophisticated functions including vector-matrix multiplication that a single device can achieve are limited.Thus,the fabrication and utilization of organic optoelectronic synaptic transistor arrays(OOSTAs)are imperative.Here,we summarize the recent advances in OOSTAs.Various strategies for manufacturing OOSTAs are introduced,including coating and casting,physical vapor deposition,printing,and photolithography.Furthermore,innovative applications of the OOSTA system integration are discussed,including neuromor-phic visual systems and neuromorphic computing systems.At last,challenges and future perspectives of utilizing OOSTAs in real-world applications are discussed.展开更多
BACKGROUND In the absence of effective antimicrobials,transplant surgery is not viable,and antirejection immunosuppressants cannot be administered,as resistant infections compromise the life-saving goal of organ trans...BACKGROUND In the absence of effective antimicrobials,transplant surgery is not viable,and antirejection immunosuppressants cannot be administered,as resistant infections compromise the life-saving goal of organ transplantation.AIM To evaluate the efficacy of antimicrobials in preventing resistance in solid organ transplant recipients.METHODS A systematic review was conducted using a search methodology consistent with the preferred reporting items for systematic reviews and meta-analyses.This review included randomized clinical trials that evaluated the efficacy of antimicrobial agents(prophylactic or therapeutic)aimed at preventing antimicrobial resistance.The search strategy involved analyzing multiple databases,including PubMed/MEDLINE,Web of Science,Embase,Scopus,and SciELO,as well as examining gray literature sources on Google Scholar.A comprehensive electronic database search was conducted from the databases’inception until May 2024,with no language restrictions.RESULTS After the final phase of the eligibility assessment,this systematic review ultimate-ly included 7 articles.A total of 2318 patients were studied.The most studied microorganisms were cytomegalovirus,although vancomycinresistant enterococci,Clostridioides difficile,and multidrug-resistant Enterobacterales were also analyzed.The antimicrobials used in the interventions were mainly maribavir,valganciclovir,gancic-lovir,and colistin-neomycin.Of concern,all clinical trials showed significant proportions of resistant microorga-nisms after the interventions,with no statistically significant differences between the groups(mean resistance 13.47%vs 14.39%),except for two studies that demonstrated greater efficacy of maribavir and valganciclovir(mean resistance 22.2%vs 41.1%in the control group;P<0.05).The total reported deaths in three clinical trials were 75,and there were 24 graft rejections in two studies.CONCLUSION All clinical trials reported significant proportions of antimicrobial-resistant microorganisms following interventions.More high-quality randomized clinical trials are needed to corroborate these results.展开更多
The productive evaluation of cocoa in this research is proposed through an assessment of soil quality and crop health in an organic production system(SPO)Taisha canton and a conventional production system(SPCv)Morona ...The productive evaluation of cocoa in this research is proposed through an assessment of soil quality and crop health in an organic production system(SPO)Taisha canton and a conventional production system(SPCv)Morona canton.Methodology:Altieri and Nicholls establish a diagnosis of chemical,physical,biological and health indicators,with weightings high(10),medium(5)and low(1).Results:SPO soil quality,reflects weights 10(high)for ammonium ion,zinc,copper,iron,manganese,moisture retention,biological activity,compaction,apparent density,residue status,color,organic matter,root development,erosion incidence,5(medium)potassium,phosphorus,calcium,sulfur,pH,texture,1(low)magnesium,boron,topsoil depth,for crop health values of 10(high)appearance,crop growth,stress resistance or tolerance,weed competition,agrosilvopastoral system,plant diversity and management system,5(medium)potential yield,incidence of pests and diseases.The SPCv soil quality presented a weighting of 10(high)for nitrogen,zinc,copper,iron,biological activity,compaction,bulk density,color,organic matter,root development,erosion incidence,5(medium)manganese,pH,texture,moisture retention,residue status,1(low)potassium,phosphorus,calcium,magnesium,sulfur,boron,topsoil depth,crop health 10(high)crop appearance and growth,stress resistance or tolerance,weed competition,agrosilvopastoral system,plant diversity,management system,potential yield,5(medium)incidence of pests and diseases,1(low)surrounding natural diversity.Conclusions:The SPO for soil quality:7.41 and for crop health:7.59 weighted as sustainable,while the SPCv for soil quality:6 and crop health:6.76,resulting in a moderately sustainable production system.展开更多
This article has been compiled and edited by China Report ASEAN based on an interview with the FAO Office of Youth and Women.As the Food and Agriculture Organization of the United Nations(FAO)celebrates its 80th anniv...This article has been compiled and edited by China Report ASEAN based on an interview with the FAO Office of Youth and Women.As the Food and Agriculture Organization of the United Nations(FAO)celebrates its 80th anniversary,the spotlight is shifting from solely honouring its longstanding mission to also highlighting the dynamic participation of youth and women in driving positive changes in agrifood systems.展开更多
Organ transplantation has long been recognized as an effective treatment for endstage organ failure,metabolic diseases,and malignant tumors.However,graft rejection caused by major histocompatibility complex mismatch r...Organ transplantation has long been recognized as an effective treatment for endstage organ failure,metabolic diseases,and malignant tumors.However,graft rejection caused by major histocompatibility complex mismatch remains a significant challenge.While modern immunosuppressants have made significant strides in reducing the incidence and risk of rejection,they have not been able to eliminate it completely.The intricate mechanisms underlying transplant rejection have been the subject of intense investigation by transplant immunologists.Among these factors,autophagy has emerged as a key player.Autophagy is an evolutionarily conserved mechanism in eukaryotic cells that mediates autophagocytosis and cellular protection.This process is regulated by autophagy-related genes and their encoded protein families,which maintain the material and energetic balance within cells.Additionally,autophagy has been reported to play crucial roles in the development,maturation,differentiation,and responses of immune cells.In the complex immune environment following transplantation,the role and mechanisms of autophagy are gradually being revealed.In this review,we aim to explore the current understanding of the role of autophagy in solid organ rejection after transplantation.Furthermore,we delve into the therapeutic advancements achieved by targeting autophagy involved in the rejection process.展开更多
The exponential growth of antibiotic-resistant bacteria and antibiotic-resistant genes(ARGs)in soil-crop systems in recent years has posed a great challenge to ecological security and human health.While many studies h...The exponential growth of antibiotic-resistant bacteria and antibiotic-resistant genes(ARGs)in soil-crop systems in recent years has posed a great challenge to ecological security and human health.While many studies have documented the residues of ARGs in soils and crops,but little is known about who drives the proliferation of ARGs in farming systems and what their underlying mechanisms are.Herein,we explored the occurrence and proliferating behavior of ARGs in soil-crop environments in terms of root secretions and plant volatiles.This review highlighted that plant root secretions and volatile organic compounds(VOCs)served as key substances mediating the development of antibiotic resistance in the soil-crop system.Still,there is controversy here as to plant root secretions promote the ARGs proliferation or inhibit.Some studies indicated that root secretions can suppress the colonization of ARGs,mainly attributed by the production of bluntedmetabolic enzymes and blocking of cellular exocytosis systems.Whereas the others have evidenced that root secretions can promote ARGs proliferation,primarily by altering the structure of microbial communities to influence species interactions and thus indirectly affect the proliferation of ARGs.Also,VOCs can act as molecular signals to convey antibiotic resistance information to their neighbors,which in turn drive the up-regulation of ARGs expression.Even so,the mechanism by which VOC-driven antibiotic resistance acquisition and proliferation need to be further probed.Overall,this review contributed to the development of products and technologies to impede the ARGs proliferation in agricultural environment.展开更多
Cold seeps are oases for biological communities on the sea floor around hydrocarbon emission pathways.Microbial utilization of methane and other hydrocarbons yield products that fuel rich chemosynthetic communities at...Cold seeps are oases for biological communities on the sea floor around hydrocarbon emission pathways.Microbial utilization of methane and other hydrocarbons yield products that fuel rich chemosynthetic communities at these sites.One such site in the cold seep ecosystem of Krishna-Godavari basin(K-G basin)along the east coast of India,discovered in Feb 2018 at a depth of 1800 m was assessed for its bacterial diversity.The seep bacterial communities were dominated by phylum Proteobacteria(57%),Firmicutes(16%)and unclassified species belonging to the family Helicobacteriaceae.The surface sediments of the seep had maximum OTUs(operational taxonomic units)(2.27×10^(3))with a Shannon alpha diversity index of 8.06.In general,environmental parameters like total organic carbon(p<0.01),sulfate(p<0.001),sulfide(p<0.05)and methane(p<0.01)were responsible for shaping the bacterial community of the cold seep ecosystem in the K-G Basin.Environmental parameters play a significant role in changing the bacterial diversity richness between different cold seep environments in the oceans.展开更多
In this study,we present a self-driven photoelectrocatalytic(SD-PEC)system that effectively treats complex uranium-bearing wastewaters for both uranium recovery and organic matter decomposition while generating power....In this study,we present a self-driven photoelectrocatalytic(SD-PEC)system that effectively treats complex uranium-bearing wastewaters for both uranium recovery and organic matter decomposition while generating power.The system utilizes a titanium dioxide nanorod array(TNR)photoelectrode coupled with a silicon solar cell to optimize electron transport,while the cathode is composed of a carbon fiber coated with carboxylated carbon nanotubes(CCNT/CF),which efficiently reduce UO_(2)^(2+).The results demonstrate significant removal efficiency of uranium(complete removal in 25 min at a rate constant of~0.248 min^(-1)),as well as substantial degradation of organic impurities.Furthermore,the system generates sufficient power output to light an LED lamp and exhibits superior performance under various complex wastewater conditions,including simulated seawater and real uranium tailings wastewater.These findings underscore the potential of the SD-PEC system as a versatile approach for sustainable treatment and energy recovery of radioactive wastewater.The significance of this research extends to global environmental challenges,offering an innovative solution for managing radioactive wastewater while simultaneously contributing to renewable energy generation.展开更多
Organic electrochemical transistors have emerged as a solution for artificial synapses that mimic the neural functions of the brain structure,holding great potentials to break the bottleneck of von Neumann architectur...Organic electrochemical transistors have emerged as a solution for artificial synapses that mimic the neural functions of the brain structure,holding great potentials to break the bottleneck of von Neumann architectures.However,current artificial synapses rely primarily on electrical signals,and little attention has been paid to the vital role of neurotransmitter-mediated artificial synapses.Dopamine is a key neurotransmitter associated with emotion regulation and cognitive processes that needs to be monitored in real time to advance the development of disease diagnostics and neuroscience.To provide insights into the development of artificial synapses with neurotransmitter involvement,this review proposes three steps towards future biomimic and bioinspired neuromorphic systems.We first summarize OECT-based dopamine detection devices,and then review advances in neurotransmitter-mediated artificial synapses and resultant advanced neuromorphic systems.Finally,by exploring the challenges and opportunities related to such neuromorphic systems,we provide a perspective on the future development of biomimetic and bioinspired neuromorphic systems.展开更多
Schizophrenia is characterized by psychotic symptoms,negative symptoms,and cognitive deficits,profoundly affecting individuals and their families.The etiology is multifactorial,involving genetic,endocrine,and immunolo...Schizophrenia is characterized by psychotic symptoms,negative symptoms,and cognitive deficits,profoundly affecting individuals and their families.The etiology is multifactorial,involving genetic,endocrine,and immunological risk factors.It is thought that schizophrenia is exclusively linked to alterations in brain structure and function,while the relationship between the brain and many organs may lack sufficient attention.Increasing evidence indicates abnormalities of the interactions between the brain and many organs in patients with schizophrenia.Inter-organ crosstalk affects the onset,course,and management of schizophrenia.Besides,the complex relationship between autonomic nervous system,endocrine system,and immune system further facilitates the development of schizophrenia.The present review summarizes the relationships between the brain and multiple organ systems in schizophrenia,providing new perspectives on the underlying pathophysiological mechanisms of schizophrenia.展开更多
This work investigates a combined cooling,heating,and power(CCHP)generation system utilizing waste energy.A cascade-CCHP system is developed,consisting of a 23.65-kWe organic Rankine cycle(ORC),a 4.00-kW adsorption ch...This work investigates a combined cooling,heating,and power(CCHP)generation system utilizing waste energy.A cascade-CCHP system is developed,consisting of a 23.65-kWe organic Rankine cycle(ORC),a 4.00-kW adsorption chiller,a 4.11-kW absorption chiller,a 15.99-kW drying room,and an incinerator of 150 kg/h.A net energy production of 36.08 kWh is achieved from a CCHP energy efficiency of 9.98%.The levelized cost for producing a total energy output of 2,020,592 kWh over a lifespan of 20 years is approximately 0.106 USD/kWh.The life cycle assessment(LCA)yields a single score of approximately 0.000151 Pt,mainly attributed to raw materials used in the construction process of 87.16%.In addition,the combustion ash is processed into concrete blocks measuring 39 cm×19 cm×7 cm,in accordance with the Industrial Product Standard(TIS)58-2533,with a water absorption value below 5%and a compressive strength exceeding 25 kg/cm2.The CCHP system demonstrates a novel method of waste-to-energy(WtE),and the construction material from waste combustion ash can also support a new concept of waste-to-zero(WtZ).展开更多
Currently,in almost all work on transition metal-mediated transformation of dinitrogen(N_(2))into organic compounds,the C-N bond formation steps are fulfilled through the interaction between metal-dinitrogen[M-N_(2)]c...Currently,in almost all work on transition metal-mediated transformation of dinitrogen(N_(2))into organic compounds,the C-N bond formation steps are fulfilled through the interaction between metal-dinitrogen[M-N_(2)]complexes and carbon based substrates.The preparation steps of[M-N_(2)]complexes are incompatible with the reaction conditions of the N−C bond formation,which has prevented catalysis.Herein,we report a chemical cycle that does not involve the preparation steps of[M-N_(2)]complexes.In the presence of Ni(CO)_(4) and SbF_(5) catalysts,this chemical cycle can convert mixed phosphonium-sulfonium bisylide R_(3)P=C=SPh_(2) and N_(2) into diazomethylenephosphoranes R_(3)P=C=N_(2).The C-N bond formation steps in this work are achieved through the direct reaction of N_(2) molecules with carbene 3,which is a metal-carbon based[M-C]complex.The computed free energy barrier for the reaction between carbene 3 and N_(2) is 24.06 kcal/mol,indicating that this reaction can occur at room temperature.Theoretical calculations show that the above chemical cycle is feasible in terms of kinetics and thermodynamics and is a true catalytic system for directly introducing N_(2) into organic compounds under mild conditions.Additionally,compared to traditional carbenes CR_(2) with two electron-sharing bonds between carbon and substituent R,the predicted carbene 3'(R_(2)P^(Me)→C:→Ni(CO)_(3))and carbene 3(R_(2)P^(Me)→C:→Ni(CO)_(2))in this work have unique electronic structures,which feature two P→C and C→Ni donor-acceptor bonds.The weak C→Ni bonds of carbene 3'and carbene 3 are critical for the regeneration of transition metal catalysts Ni(CO)_(4).This also means that the predicted carbene 3'and carbene 3 will have richer chemical properties to be discovered than traditional carbene CR_(2).This work also preliminarily predicted that carbene 3'has the potential to activate CO,indicating that this work may open the door to activating other important small molecules.展开更多
基金Supported by the National Natural Science Foundation of China,No.82305376the Youth Talent Support Project of the China Acupuncture and Moxibustion Association,No.2024-2026ZGZJXH-QNRC005+2 种基金the 2024 Jiangsu Province Youth Science and Technology Talent Support Project,No.JSTJ-2024-3802025 Jiangsu Provincial Science and Technology Think Tank Program Project,No.JSKX0125035and 2025 College Student Innovation Training Program Project,No.X202510315373。
文摘BACKGROUND Organ transplantation has emerged as a globally prevalent therapeutic modality for end-stage organ failure,yet the post-transplantation trajectory is increasingly complicated by a spectrum of metabolic sequelae,with obesity emerging as a critical clinical challenge.AIM To systematically review the multifactorial mechanisms underlying obesity following organ transplantation and to integrate evidence from pharmacological,behavioral,and molecular perspectives,thereby providing a foundation for targeted interventions.METHODS We conducted a systematic search in PubMed and Web of Science for literature published from 2020 to 15 July 2025.The search strategy incorporated terms including“obesity”,“overweight”and“post organ transplantation”.Only randomized controlled trials,meta-analyses,and systematic reviews were included.Non-empirical publications and irrelevant studies were excluded.Data extraction and quality assessment were performed by two independent reviewers,with disagreements resolved by a third researcher.RESULTS A total of 1457 articles were initially identified,of which 146 met the inclusion criteria.These studies encompassed liver,kidney,heart,and lung transplant recipients.Key findings indicate that immunosuppressive drugs-especially corticosteroids and calcineurin inhibitors-promote hyperphagia,insulin resistance,and dyslipidemia.Post-transplant sedentary behavior and hypercaloric diets further contribute to positive energy balance.At the molecular level,immunosuppressants disrupt adipokine signaling(e.g.,leptin and adiponectin),induce inflammatory and oxidative stress responses,and activate adipogenic pathways leading to lipid accumulation.CONCLUSION Post-transplant obesity arises from a complex interplay of pharmacological,behavioral,and molecular factors.A multidisciplinary approach-incorporating pharmacological modification,nutritional management,physical activity,and molecular-targeted therapies-is essential to mitigate obesity and improve transplant outcomes.Further large-scale and mechanistic studies are warranted to establish evidence-based preventive and treatment strategies.
文摘Triclosan(TCS) poses harmful risks to ecosystems and human health owing to its endocrine-disrupting effects.Therefore,developing an efficient and sustainable technology to degrade TCS is urgently needed.Herein,cobalt oxyhydroxide @covalent organic frameworks(CoOOH@COFs) S-scheme heterojunction was synthesized,which combined the visible-light-driven photocatalysis and peroxymonosulfate(PMS) activation to synergistically generate abundant reactive oxygen species(ROSs) for TCS degradation.The degradation efficiency of TCS reached 100 % within 8 min in the Vis-CoOOH@COFs/PMS system,and the reaction rate constant was 0.456 min^(-1),which was nearly 1.90 and 2.85 times that of single Co OOH and COFs,and2.36 times that under dark condition,respectively.The density functional theory(DFT) calculations confirmed the energy band bending of CoOOH@COFs and S-scheme charge transport from COFs to Co OOH.Both experimental and theoretical analyses indicated that Co OOH@COFs in photocatalytic-PMS activation systems synergistically facilitated photo-generated carrier separation,enhanced interfacial electron transfer,accelerated PMS activation,and generated multiple ROSs.In particular,photogenerated electrons(e^(-))accelerated the Co(Ⅲ)/Co(Ⅱ) redox cycle,while the PMS captured the e-,which significantly decreased the charge combination of Co OOH@COFs.Radicals(O_(2)^(·-),^(·)OH,and SO_(4)^(·-)) and non-radicals(such as ^(1)O_(2),h^(+),and e^(-)) were both presented in the Vis-CoOOH@COFs/PMS system,with O_(2)^(-) playing a dominant role in TCS degradation.Furthermore,the pathway of TCS degradation and toxicity of intermediates were explored by DFT calculation and transformation product identification.Importantly,the environmentally friendly CoOOH@COFs S-scheme heterojunction exhibited excellent stability and reusability.In conclusion,this study innovatively designed an S-scheme heterojunction in the photocatalytic-PMS activation system,providing guidance and theoretical support for efficient and eco-friendly wastewater treatment.
基金funded by the Huaiyin Institute of Technology—Institute of Smart Energy.
文摘In the quest to enhance energy efficiency and reduce environmental impact in the transportation sector,the recovery of waste heat from diesel engines has become a critical area of focus.This study provided an exhaustive thermodynamic analysis optimizing Organic Rankine Cycle(ORC)systems forwaste heat recovery fromdiesel engines.Thestudy assessed the performance of five candidateworking fluids—R11,R123,R113,R245fa,and R141b—under a range of operating conditions,specifically varying overheat temperatures and evaporation pressures.The results indicated that the choice of working fluid substantially influences the system’s exergetic efficiency,net output power,and thermal efficiency.R245fa showed an outstanding net output power of 30.39 kW at high overheat conditions,outperforming R11,which is significant for high-temperature waste heat recovery.At lower temperatures,R11 and R113 demonstrated higher exergetic efficiencies,with R11 reaching a peak exergetic efficiency of 7.4%at an evaporation pressure of 10 bar and an overheat of 10℃.The study also revealed that controlling the overheat and optimizing the evaporation pressure are crucial for enhancing the net output power of the ORC system.Specifically,at an evaporation pressure of 30 bar and an overheat of 0℃,R113 exhibited the lowest exergetic destruction of 544.5 kJ/kg,making it a suitable choice for minimizing irreversible losses.These findings are instrumental for understanding the performance of ORC systems in waste heat recovery applications and offer valuable insights for the design and operation of more efficient and environmentally friendly diesel engine systems.
文摘The author puts forward the proposition of Complexity and Self Organized Criticality of Solid Earth System in the light of: (1) the science of complexity studies the mechanisms of emergence of complexity and is the science of the 21st century, (2) the study of complexity of the earth system would be one of the growing points occupying a strategic position in the development of geosciences in the 21st century. By the proposition we try to cogitate from a new viewpoint the ancient yet ever new solid earth system. The author abstracts the fundamental problem of the solid earth system from the essence of the generalized geological systems and processes which reads: the complexity and self organized criticality of the global nature, structure and dynamical behavior of the whole solid earth system emerging from the multiple coupling and superposition of non linear interactions among the multicomponents of the earths material and the multiple generalized geological (geological, geophysical, and geochemical) processes . Starting from this cognizance the author proposes eight major themes and the methodology of researches on the complexity and self organized criticality of the solid earth system.
基金supported by the National Natural Science Foundation of China(42177341)the Natural Science Basic Research Program of Shanxi,China(202203021222138).
文摘Organic material combined with inorganic fertilizer has been shown to greatly improve crop yield and maintain soil fertility globally. However, it remains unclear if crop yield and soil fertility can be sustained in the long term under the combined application of organic and inorganic fertilizers. Three long-term field trials were conducted to investigate the effects of organic amendments on the grain sustainable yield index(SYI), soil fertility index(SFI)and nutrient balance in maize–wheat cropping systems of central and southern China during 1991–2019. Five treatments were included in the trials: 1) no fertilization(control);2) balanced mineral fertilization(NPK);3) NPK plus manure(NPKM);4) high dose of NPK plus manure(1.5NPKM);and 5) NPK plus crop straw(NPKS). Over time, the grain yields of wheat and maize showed an increasing trend in all four fertilization treatments at the Yangling(YL) and Zhengzhou(ZZ) locations, while they declined at Qiyang(QY). The grain yield in the NPKM and 1.5NPKM treatments gradually exceeded that of the NPK and NPKS treatments at the QY site. The largest SYI was recorded in the NPKM treatment across the three sites, suggesting that inorganic fertilizer combined with manure can effectively improve crop yield sustainability. Higher SYI values were recorded at the YL and ZZ sites than at the QY site, possibly because the soil was more acid at QY. The key factors affecting grain yield were soil available phosphorus(AP) and available potassium(AK) at the YL and ZZ sites, and pH and AP at the QY site.All fertilization treatments resulted in soil N and P surpluses at the three sites, but soil K surpluses were recorded only at the QY site. The SFI was greater in the 1.5NPKM, NPKM and NPKS treatments than in the NPK treatment by 13.3–40.0 and 16.4–63.6% at the YL and ZZ sites, respectively, and was significantly higher in the NPKM and 1.5NPKM treatments than in the NPK and NPKS treatments at the QY site. A significant, positive linear relationship was found between SFI and crop yield, and SYI and nutrient balance, indicating that grain yield and its sustainability significantly increased with increasing soil fertility. The apparent N, P and K balances positively affected SFI.This study suggests that the appropriate amount of manure mixed with mineral NPK fertilizer is beneficial to the development of sustainable agriculture, which effectively increases the crop yield and yield sustainability by improving soil fertility.
基金funded under the National key research and development plan(2021YFC2101404)Chinese Academy of Engineering Strategic Research and Consulting Project(2023-XZ-79,2022-30-19).
文摘Cell cultured meat has been extensively studied as an environmentally friendly,energy-saving and more effective technology.However,there are many technical bottlenecks,especially the regulatory mechanism and manufacturing method of in vitro myogenesis.Based on an edible modified silk protein scaffold,with 3D culturing,in situ differentiated and transcriptome analysis,this study describes novel scaffolds and fabrication methods for cell cultured meat.The results showed that the effective space and utilization efficiency for cell culture of the scaffold is 26–1000 that of the traditional culture dish;it could form a tissue-like structure.Transcriptomics revealed the regulatory pathways and key factors of different cycles.It clarifies that the multi-cycle process of myoblast myogenesis in vitro is different from the single feedback regulation in vivo.More importantly,a novel scaffold-based cell cultured meat manufacturing method was developed,further develop a new tissue culture solution that is different from existing cell culture meat production.For manufacturing processes,it provides a new cell culture meat technology system,provides a theoretical basis for the regulation of cell proliferation and muscle growth,and lays the technical foundation for in situ tissue culture of cell cultured meat in vitro.
基金supported by research grants from the Natural Science Foundation of Shandong Province,China(ZR2020MC092)the Key Research and Development Project of Shandong Province,China(2019TSCYCX-33)the Key Research and Development Project of Shandong Province,China(LJNY202025).
文摘To make agricultural systems sustainable in terms of their greenness and efficiency,optimizing the tillage and fertilization practices is essential.To assess the effects of tilling and fertilization practices in wheat-maize cropping systems,a three-year field experiment was designed to quantify the carbon footprint(CF)and energy efficiency of the cropping systems in the North China Plain.The study parameters included four tillage practices(no tillage(NT),conventional tillage(CT),rotary tillage(RT),and subsoiling rotary tillage(SRT))and two fertilizer regimes(inorganic fertilizer(IF)and hybrid fertilizer with organic and inorganic components(HF)).The results indicated that the most prominent energy inputs and greenhouse gas(GHG)emissions could be ascribed to the use of fertilizers and fuel consumption.Under the same fertilization regime,ranking the tillage patterns with respect to the value of the crop yield,profit,CF,energy use efficiency(EUE)or energy productivity(EP)for either wheat or maize always gave the same sequence of SRT>RT>CT>NT.For the same tillage,the energy consumption associated with HF was higher than IF,but its GHG emissions and CF were lower while the yield and profit were higher.In terms of overall performance,tilling is more beneficial than NT,and reduced tillage practices(RT and SRT)are more beneficial than CT.The fertilization regime with the best overall performance was HF.Combining SRT with HF has significant potential for reducing CF and increasing EUE,thereby improving sustainability.Adopting measures that promote these optimizations can help to overcome the challenges posed by a lack of food security,energy crises and ecological stress.
基金supported by the National Natural Science Foundation of China(Grant No.2230081973)Shanghai Pilot Program for Basic Research(22TQ1400100-4).
文摘Membrane technology holds significant potential for augmenting or partially substituting conventional separation techniques,such as heatdriven distillation,thereby reducing energy consumption.Organic solvent nanofiltration represents an advanced membrane separation technology capable of discerning molecules within a molecular weight range of approximately 100-1000 Da in organic solvents,offering low energy requirements and minimal carbon footprints.Molecular separation in non-polar solvent system,such as toluene,n-hexane,and n-heptane,has gained paramount importance due to their extensive use in the pharmaceutical,biochemical,and petrochemical industries.In this review,we presented recent advancements in membrane materials,membrane fabrication techniques and their promising applications for separation in nonpolar solvent system,encompassing hydrocarbon separation,bioactive molecule purification and organic solvent recovery.Furthermore,this review highlighted the challenges and opportunities associated with membrane scale-up strategies and the direct translation of this promising technology into industrial applications.
基金supported by the National Key Research and Development Program of China(2021YFA1101303)the National Natural Science Foundation of China(62374115)the Innovation Program of Shanghai Municipal Education Commission(2021-01-07-00-07-E00096).
文摘The rapid growth of artificial intelligence has accelerated data generation,which increasingly exposes the limitations faced by traditional computational architectures,particularly in terms of energy consumption and data latency.In contrast,data-centric computing that integrates processing and storage has the potential of reducing latency and energy usage.Organic optoelectronic synaptic transistors have emerged as one type of promising devices to implement the data-centric com-puting paradigm owing to their superiority of flexibility,low cost,and large-area fabrication.However,sophisticated functions including vector-matrix multiplication that a single device can achieve are limited.Thus,the fabrication and utilization of organic optoelectronic synaptic transistor arrays(OOSTAs)are imperative.Here,we summarize the recent advances in OOSTAs.Various strategies for manufacturing OOSTAs are introduced,including coating and casting,physical vapor deposition,printing,and photolithography.Furthermore,innovative applications of the OOSTA system integration are discussed,including neuromor-phic visual systems and neuromorphic computing systems.At last,challenges and future perspectives of utilizing OOSTAs in real-world applications are discussed.
文摘BACKGROUND In the absence of effective antimicrobials,transplant surgery is not viable,and antirejection immunosuppressants cannot be administered,as resistant infections compromise the life-saving goal of organ transplantation.AIM To evaluate the efficacy of antimicrobials in preventing resistance in solid organ transplant recipients.METHODS A systematic review was conducted using a search methodology consistent with the preferred reporting items for systematic reviews and meta-analyses.This review included randomized clinical trials that evaluated the efficacy of antimicrobial agents(prophylactic or therapeutic)aimed at preventing antimicrobial resistance.The search strategy involved analyzing multiple databases,including PubMed/MEDLINE,Web of Science,Embase,Scopus,and SciELO,as well as examining gray literature sources on Google Scholar.A comprehensive electronic database search was conducted from the databases’inception until May 2024,with no language restrictions.RESULTS After the final phase of the eligibility assessment,this systematic review ultimate-ly included 7 articles.A total of 2318 patients were studied.The most studied microorganisms were cytomegalovirus,although vancomycinresistant enterococci,Clostridioides difficile,and multidrug-resistant Enterobacterales were also analyzed.The antimicrobials used in the interventions were mainly maribavir,valganciclovir,gancic-lovir,and colistin-neomycin.Of concern,all clinical trials showed significant proportions of resistant microorga-nisms after the interventions,with no statistically significant differences between the groups(mean resistance 13.47%vs 14.39%),except for two studies that demonstrated greater efficacy of maribavir and valganciclovir(mean resistance 22.2%vs 41.1%in the control group;P<0.05).The total reported deaths in three clinical trials were 75,and there were 24 graft rejections in two studies.CONCLUSION All clinical trials reported significant proportions of antimicrobial-resistant microorganisms following interventions.More high-quality randomized clinical trials are needed to corroborate these results.
文摘The productive evaluation of cocoa in this research is proposed through an assessment of soil quality and crop health in an organic production system(SPO)Taisha canton and a conventional production system(SPCv)Morona canton.Methodology:Altieri and Nicholls establish a diagnosis of chemical,physical,biological and health indicators,with weightings high(10),medium(5)and low(1).Results:SPO soil quality,reflects weights 10(high)for ammonium ion,zinc,copper,iron,manganese,moisture retention,biological activity,compaction,apparent density,residue status,color,organic matter,root development,erosion incidence,5(medium)potassium,phosphorus,calcium,sulfur,pH,texture,1(low)magnesium,boron,topsoil depth,for crop health values of 10(high)appearance,crop growth,stress resistance or tolerance,weed competition,agrosilvopastoral system,plant diversity and management system,5(medium)potential yield,incidence of pests and diseases.The SPCv soil quality presented a weighting of 10(high)for nitrogen,zinc,copper,iron,biological activity,compaction,bulk density,color,organic matter,root development,erosion incidence,5(medium)manganese,pH,texture,moisture retention,residue status,1(low)potassium,phosphorus,calcium,magnesium,sulfur,boron,topsoil depth,crop health 10(high)crop appearance and growth,stress resistance or tolerance,weed competition,agrosilvopastoral system,plant diversity,management system,potential yield,5(medium)incidence of pests and diseases,1(low)surrounding natural diversity.Conclusions:The SPO for soil quality:7.41 and for crop health:7.59 weighted as sustainable,while the SPCv for soil quality:6 and crop health:6.76,resulting in a moderately sustainable production system.
文摘This article has been compiled and edited by China Report ASEAN based on an interview with the FAO Office of Youth and Women.As the Food and Agriculture Organization of the United Nations(FAO)celebrates its 80th anniversary,the spotlight is shifting from solely honouring its longstanding mission to also highlighting the dynamic participation of youth and women in driving positive changes in agrifood systems.
基金Supported by the National Natural Science Foundation of China,No.82100691China Postdoctoral Science Foundation,No.2021M693631.
文摘Organ transplantation has long been recognized as an effective treatment for endstage organ failure,metabolic diseases,and malignant tumors.However,graft rejection caused by major histocompatibility complex mismatch remains a significant challenge.While modern immunosuppressants have made significant strides in reducing the incidence and risk of rejection,they have not been able to eliminate it completely.The intricate mechanisms underlying transplant rejection have been the subject of intense investigation by transplant immunologists.Among these factors,autophagy has emerged as a key player.Autophagy is an evolutionarily conserved mechanism in eukaryotic cells that mediates autophagocytosis and cellular protection.This process is regulated by autophagy-related genes and their encoded protein families,which maintain the material and energetic balance within cells.Additionally,autophagy has been reported to play crucial roles in the development,maturation,differentiation,and responses of immune cells.In the complex immune environment following transplantation,the role and mechanisms of autophagy are gradually being revealed.In this review,we aim to explore the current understanding of the role of autophagy in solid organ rejection after transplantation.Furthermore,we delve into the therapeutic advancements achieved by targeting autophagy involved in the rejection process.
基金supported by the Youth innovation Program of Chinese Academy of Agricultural Sciences(No.Y2023QC32)the foundation of Tianjin Natural Science Foundation(No.22JCQNJC01460)the Science and Technology Innovation Project of Chinese Academy of Agricultural Sciences(Agro-Environmental Protection Institute,Ministry of Agricultural and Rural Affairs)and the Youth Talent Project of Agro-Environmental Protection Institute,Ministry of Agricultural and Rural Affairs(Xu Yan).
文摘The exponential growth of antibiotic-resistant bacteria and antibiotic-resistant genes(ARGs)in soil-crop systems in recent years has posed a great challenge to ecological security and human health.While many studies have documented the residues of ARGs in soils and crops,but little is known about who drives the proliferation of ARGs in farming systems and what their underlying mechanisms are.Herein,we explored the occurrence and proliferating behavior of ARGs in soil-crop environments in terms of root secretions and plant volatiles.This review highlighted that plant root secretions and volatile organic compounds(VOCs)served as key substances mediating the development of antibiotic resistance in the soil-crop system.Still,there is controversy here as to plant root secretions promote the ARGs proliferation or inhibit.Some studies indicated that root secretions can suppress the colonization of ARGs,mainly attributed by the production of bluntedmetabolic enzymes and blocking of cellular exocytosis systems.Whereas the others have evidenced that root secretions can promote ARGs proliferation,primarily by altering the structure of microbial communities to influence species interactions and thus indirectly affect the proliferation of ARGs.Also,VOCs can act as molecular signals to convey antibiotic resistance information to their neighbors,which in turn drive the up-regulation of ARGs expression.Even so,the mechanism by which VOC-driven antibiotic resistance acquisition and proliferation need to be further probed.Overall,this review contributed to the development of products and technologies to impede the ARGs proliferation in agricultural environment.
文摘Cold seeps are oases for biological communities on the sea floor around hydrocarbon emission pathways.Microbial utilization of methane and other hydrocarbons yield products that fuel rich chemosynthetic communities at these sites.One such site in the cold seep ecosystem of Krishna-Godavari basin(K-G basin)along the east coast of India,discovered in Feb 2018 at a depth of 1800 m was assessed for its bacterial diversity.The seep bacterial communities were dominated by phylum Proteobacteria(57%),Firmicutes(16%)and unclassified species belonging to the family Helicobacteriaceae.The surface sediments of the seep had maximum OTUs(operational taxonomic units)(2.27×10^(3))with a Shannon alpha diversity index of 8.06.In general,environmental parameters like total organic carbon(p<0.01),sulfate(p<0.001),sulfide(p<0.05)and methane(p<0.01)were responsible for shaping the bacterial community of the cold seep ecosystem in the K-G Basin.Environmental parameters play a significant role in changing the bacterial diversity richness between different cold seep environments in the oceans.
基金supported by the National Natural Science Foundation of China(Nos.52170083,51808143)the Science and Technology Innovation Program of Hunan Province(No.2022RC1125)the Hunan Provincial Natural Science Foundation of China(No.2021JJ20007)。
文摘In this study,we present a self-driven photoelectrocatalytic(SD-PEC)system that effectively treats complex uranium-bearing wastewaters for both uranium recovery and organic matter decomposition while generating power.The system utilizes a titanium dioxide nanorod array(TNR)photoelectrode coupled with a silicon solar cell to optimize electron transport,while the cathode is composed of a carbon fiber coated with carboxylated carbon nanotubes(CCNT/CF),which efficiently reduce UO_(2)^(2+).The results demonstrate significant removal efficiency of uranium(complete removal in 25 min at a rate constant of~0.248 min^(-1)),as well as substantial degradation of organic impurities.Furthermore,the system generates sufficient power output to light an LED lamp and exhibits superior performance under various complex wastewater conditions,including simulated seawater and real uranium tailings wastewater.These findings underscore the potential of the SD-PEC system as a versatile approach for sustainable treatment and energy recovery of radioactive wastewater.The significance of this research extends to global environmental challenges,offering an innovative solution for managing radioactive wastewater while simultaneously contributing to renewable energy generation.
基金supported by the National Natural Science Foundation of China(Grant No.62074163)Beijing Natural Science Foundation(Grant No.JQ24030).
文摘Organic electrochemical transistors have emerged as a solution for artificial synapses that mimic the neural functions of the brain structure,holding great potentials to break the bottleneck of von Neumann architectures.However,current artificial synapses rely primarily on electrical signals,and little attention has been paid to the vital role of neurotransmitter-mediated artificial synapses.Dopamine is a key neurotransmitter associated with emotion regulation and cognitive processes that needs to be monitored in real time to advance the development of disease diagnostics and neuroscience.To provide insights into the development of artificial synapses with neurotransmitter involvement,this review proposes three steps towards future biomimic and bioinspired neuromorphic systems.We first summarize OECT-based dopamine detection devices,and then review advances in neurotransmitter-mediated artificial synapses and resultant advanced neuromorphic systems.Finally,by exploring the challenges and opportunities related to such neuromorphic systems,we provide a perspective on the future development of biomimetic and bioinspired neuromorphic systems.
基金Supported by Beijing Traditional Chinese Medicine Scientific and Technological Development Fund Project,No.BJZYYB-2023-66Beijing Natural Science Foundation,No.7212050the Capital’s Funds for Health Improvement and Research,No.2020-4-2126.
文摘Schizophrenia is characterized by psychotic symptoms,negative symptoms,and cognitive deficits,profoundly affecting individuals and their families.The etiology is multifactorial,involving genetic,endocrine,and immunological risk factors.It is thought that schizophrenia is exclusively linked to alterations in brain structure and function,while the relationship between the brain and many organs may lack sufficient attention.Increasing evidence indicates abnormalities of the interactions between the brain and many organs in patients with schizophrenia.Inter-organ crosstalk affects the onset,course,and management of schizophrenia.Besides,the complex relationship between autonomic nervous system,endocrine system,and immune system further facilitates the development of schizophrenia.The present review summarizes the relationships between the brain and multiple organ systems in schizophrenia,providing new perspectives on the underlying pathophysiological mechanisms of schizophrenia.
基金National Research Council of Thailand(NRCT)and the School of Renewable Energy and Maejo University for the project to produce and develop graduates in renewable energy for ASEAN countries for graduate students(2021).
文摘This work investigates a combined cooling,heating,and power(CCHP)generation system utilizing waste energy.A cascade-CCHP system is developed,consisting of a 23.65-kWe organic Rankine cycle(ORC),a 4.00-kW adsorption chiller,a 4.11-kW absorption chiller,a 15.99-kW drying room,and an incinerator of 150 kg/h.A net energy production of 36.08 kWh is achieved from a CCHP energy efficiency of 9.98%.The levelized cost for producing a total energy output of 2,020,592 kWh over a lifespan of 20 years is approximately 0.106 USD/kWh.The life cycle assessment(LCA)yields a single score of approximately 0.000151 Pt,mainly attributed to raw materials used in the construction process of 87.16%.In addition,the combustion ash is processed into concrete blocks measuring 39 cm×19 cm×7 cm,in accordance with the Industrial Product Standard(TIS)58-2533,with a water absorption value below 5%and a compressive strength exceeding 25 kg/cm2.The CCHP system demonstrates a novel method of waste-to-energy(WtE),and the construction material from waste combustion ash can also support a new concept of waste-to-zero(WtZ).
文摘Currently,in almost all work on transition metal-mediated transformation of dinitrogen(N_(2))into organic compounds,the C-N bond formation steps are fulfilled through the interaction between metal-dinitrogen[M-N_(2)]complexes and carbon based substrates.The preparation steps of[M-N_(2)]complexes are incompatible with the reaction conditions of the N−C bond formation,which has prevented catalysis.Herein,we report a chemical cycle that does not involve the preparation steps of[M-N_(2)]complexes.In the presence of Ni(CO)_(4) and SbF_(5) catalysts,this chemical cycle can convert mixed phosphonium-sulfonium bisylide R_(3)P=C=SPh_(2) and N_(2) into diazomethylenephosphoranes R_(3)P=C=N_(2).The C-N bond formation steps in this work are achieved through the direct reaction of N_(2) molecules with carbene 3,which is a metal-carbon based[M-C]complex.The computed free energy barrier for the reaction between carbene 3 and N_(2) is 24.06 kcal/mol,indicating that this reaction can occur at room temperature.Theoretical calculations show that the above chemical cycle is feasible in terms of kinetics and thermodynamics and is a true catalytic system for directly introducing N_(2) into organic compounds under mild conditions.Additionally,compared to traditional carbenes CR_(2) with two electron-sharing bonds between carbon and substituent R,the predicted carbene 3'(R_(2)P^(Me)→C:→Ni(CO)_(3))and carbene 3(R_(2)P^(Me)→C:→Ni(CO)_(2))in this work have unique electronic structures,which feature two P→C and C→Ni donor-acceptor bonds.The weak C→Ni bonds of carbene 3'and carbene 3 are critical for the regeneration of transition metal catalysts Ni(CO)_(4).This also means that the predicted carbene 3'and carbene 3 will have richer chemical properties to be discovered than traditional carbene CR_(2).This work also preliminarily predicted that carbene 3'has the potential to activate CO,indicating that this work may open the door to activating other important small molecules.
