Diabetic wounds(DWs)are a major complication of diabetes mellitus,characterized by a complex patho-physiological microenvironment that is associated with elevated morbidity and mortality.Conventional management strate...Diabetic wounds(DWs)are a major complication of diabetes mellitus,characterized by a complex patho-physiological microenvironment that is associated with elevated morbidity and mortality.Conventional management strategies often fail to address the multifaceted nature of these wounds effectively.Recent advancements in understanding the mechanisms of DW healing have spurred the development of a plethora of bioactive dressings designed to interact with and modulate the DW microenvironment.These innovations have culminated in the introduction of the“microenvironment-sensitive with on-demand management”paradigm aimed at delivering precision therapy responsive to dynamic changes within DW.Despite these advancements,the current literature lacks a comprehensive review that cate-gorizes and evaluates active,passive,and on-demand approaches that address the DW microenviron-ment.Herein,we describe the unique pathogenic mechanisms and microenvironmental characteristics that distinguish DW from normal acute wounds.This review provides an extensive overview of contem-porary active and passive management strategies incorporating on-demand management principles designed for DW microenvironments.Furthermore,it addresses the principal challenges faced in this therapeutic domain and outlines the potential innovations that can enhance the efficacy and specificity of bioactive dressings.The insights presented here aim to guide further research and development in the on-demand management of DW to improve patient outcomes by aligning personalized therapy modali-ties with the pathophysiological realities of DW.展开更多
L-arginine is a highly nitrogenous amino acid with a wide range of applications in feed,pharmaceuticals and food.Here we developed an Escherichia coli chassis strain for L-arginine production by enhancing the L-argini...L-arginine is a highly nitrogenous amino acid with a wide range of applications in feed,pharmaceuticals and food.Here we developed an Escherichia coli chassis strain for L-arginine production by enhancing the L-arginine synthesis pathway,which produced 58.8 g/L in 5-L bioreactor with a yield of 0.30 g/g glucose.With subsequent systematic engineering strategy focusing on enhancing the nitrogen utilization by adjusting the NH4+uptake and synchronization-related precursor carbamoyl phosphate pathway,the L-arginine production was increased by 37%,however,the cell growth was inhibited by these gene modifications.To conquer this,Nucleoside Triphosphate(NTP)supply was firstly enhanced by regulating the purine pathway,which was beneficial for cellular repair and enhancing strain's stress resistance.Meanwhile,weakening the L-arginine import system reduces L-arginine consumption and conserves ATP.The final strain produced 102.4 g/L L-arginine,with a yield of 0.48 g/g glucose in 5-L bioreactor.The innovative approach of synergistic adjusting ammonia uptake and the purine pathway,balanced cell growth and boosted L-arginine production,offering valuable guidance for in-dustrial microbial synthesis of other nitrogen-rich chemicals.展开更多
CO_(2) enhanced shale gas recovery(CO_(2)-ESGR)has attracted extensive attention as it can improve the shale gas recovery efficiency and sequestrate CO_(2) simultaneously.In this study,the relationship between mineral...CO_(2) enhanced shale gas recovery(CO_(2)-ESGR)has attracted extensive attention as it can improve the shale gas recovery efficiency and sequestrate CO_(2) simultaneously.In this study,the relationship between mineral composition,pore structure,CH_(4) and CO_(2) adsorption behavior as well as selective adsorption coefficient of CO_(2) over CH_(4)(αCO_(2)/CH_(4))in marine and continental shales at different temperatures was investigated.The results illustrated that shale with higher total organic carbon(TOC),higher clay minerals and lower brittle mineral contents has a larger micropores and mesopores volume and specific surface area.TOC content was positively correlated with fractal dimension Df.Both CH_(4) and CO_(2) adsorption capacity in shale have positive correlations with TOC and clay mineral content.CO_(2) adsorption capacity of the all the tested shale samples were greater than CH_(4),and theαCO_(2)/CH_(4) of shale were larger than 1.00,which indicated that using CO_(2)-ESGR technology to improve the gas recovery is feasible in these shale gas reservoirs.A higher TOC content and in shale corresponding to a lowerαCO_(2)/CH_(4) due to the organic matters show stronger affinity on CH_(4) than that on CO_(2).Shale with a higher brittle mineral content corresponding to a higherαCO_(2)/CH_(4),and no obvious correlation betweenαCO_(2)/CH_(4) and clay mineral content in shale was observed due to the complexity of the clay minerals.TheαCO_(2)/CH_(4) of shale were decreased with increasing temperature for most cases,which indicated that a lower temperature is more favorable for the application of CO_(2)-ESGR technique.展开更多
The global chemical industry market is steadily improving after the pandemic.According to statistics from the European Chemical Industry Council(CEFIC),the industry's market value was 4.4 trillion dollars in 2022 ...The global chemical industry market is steadily improving after the pandemic.According to statistics from the European Chemical Industry Council(CEFIC),the industry's market value was 4.4 trillion dollars in 2022 and is projected to rise to 9.0 trillion dollars by 2030[1,2].Chemical manufacturing produces more than70,000 diverse products each year,ranging from agricultural chemicals,basic chemicals,specialty chemicals,and consumer products to pharmaceuticals.展开更多
Racemize 2-hydroxybutyric acid is usually synthesized by organic methods and needs additional deracemization to obtain optically pure enantiomers for industrial application.Here we present a cascade biocatalysis syste...Racemize 2-hydroxybutyric acid is usually synthesized by organic methods and needs additional deracemization to obtain optically pure enantiomers for industrial application.Here we present a cascade biocatalysis system in Escherichia coli BL21 which employed L-threonine deaminase(TD),NAD-dependent L-lactate dehydrogenase(LDH)and alcohol dehydrogenase(ADH)for producing optically pure(S)-2-hydroxybutyric acid((S)-2-HBA)from bulk chemical L-threonine.To solve the mismatch in the conversion rate and the consumption rate of intermediate 2-oxobutyric acid(2-OBA)formed in the multi-enzyme catalysis reaction,ribosome binding site regulation strategy was explored to control TD expression levels,achieving an eightfold alteration in the conversion rate of 2-OBA.With the optimized activity ratio of the three enzymes and using ADH for NADH regeneration,the recombinant strain ADH-r53 showed increased production of(S)-2-HBA with the highest titer of 129 g/L and molar yield of 93%within 24 h,which is approximately 1.65 times that of the highest yield reported so far.Moreover,(S)-2-HBA could easily be purified by distillation,making it have great potential for industrial application.Additionally,our results indicated that constructing a tunable multi-enzyme-coordinate expression system in single cell had great significance in biocatalysis of hydroxyl acids.展开更多
The pore structure of caprock plays an important role in underground gas storage security, as it significantly influences the sealing capacity of caprock. However, the pore structure evolution of caprock with the cycl...The pore structure of caprock plays an important role in underground gas storage security, as it significantly influences the sealing capacity of caprock. However, the pore structure evolution of caprock with the cyclic stress perturbations triggered by the cyclic gas injection or extraction remains unclear. In this study, the pore structure changes of mudstone caprock under cyclic loading and unloading were obtained by the nuclear magnetic resonance (NMR) tests system, then the influence of the changes on the breakthrough pressure of caprock was discussed. The results indicated that the pore structure changes are depending on the stress loading-unloading path and stress level. In the first cyclic, at the loading stage, with the increase of confining stress, the NMR T2 spectrum curve moved to the left, the NMR signal amplitude of the first peak increased, while the amplitude of the second peak decreased gradually. This indicated that the larger pores of mudstone are compressed and transformed into smaller pores, then the number of macropores decreased and the number of micro- and mesopores increased. For a certain loading-unloading cycle, the porosity curve of mudstone in the loading process is not coincide with that in the unloading process, the porosity curve in the loading process was located below that in the unloading process, which indicated that the pore structure change is stress path dependent. With the increase of cycle numbers, the total porosity shown an increasing trend, indicating that the damage of mudstone occurred under the cyclic stress load-unload effects. With the increase of porosity, the breakthrough pressure of mudstone decreased with the increase of the cyclic numbers, which may increase the gas leakage risk. The results can provide significant implication for the underground gas storage security evaluation.展开更多
基金supported by the National Natural Science Foundation of China(22408078,82401057,32101170)the Zhejiang Province Postdoctoral Excellence Funding Program-Special Support(ZJ2024004).
文摘Diabetic wounds(DWs)are a major complication of diabetes mellitus,characterized by a complex patho-physiological microenvironment that is associated with elevated morbidity and mortality.Conventional management strategies often fail to address the multifaceted nature of these wounds effectively.Recent advancements in understanding the mechanisms of DW healing have spurred the development of a plethora of bioactive dressings designed to interact with and modulate the DW microenvironment.These innovations have culminated in the introduction of the“microenvironment-sensitive with on-demand management”paradigm aimed at delivering precision therapy responsive to dynamic changes within DW.Despite these advancements,the current literature lacks a comprehensive review that cate-gorizes and evaluates active,passive,and on-demand approaches that address the DW microenviron-ment.Herein,we describe the unique pathogenic mechanisms and microenvironmental characteristics that distinguish DW from normal acute wounds.This review provides an extensive overview of contem-porary active and passive management strategies incorporating on-demand management principles designed for DW microenvironments.Furthermore,it addresses the principal challenges faced in this therapeutic domain and outlines the potential innovations that can enhance the efficacy and specificity of bioactive dressings.The insights presented here aim to guide further research and development in the on-demand management of DW to improve patient outcomes by aligning personalized therapy modali-ties with the pathophysiological realities of DW.
基金supported by the National Key Research and Development Program of China(2022YFA0911800)the Key Research Development Program of Zhejiang Province(2024C03012)2023 Zhejiang Province postdoctoral research project preferential funding(ZJ2023159).
文摘L-arginine is a highly nitrogenous amino acid with a wide range of applications in feed,pharmaceuticals and food.Here we developed an Escherichia coli chassis strain for L-arginine production by enhancing the L-arginine synthesis pathway,which produced 58.8 g/L in 5-L bioreactor with a yield of 0.30 g/g glucose.With subsequent systematic engineering strategy focusing on enhancing the nitrogen utilization by adjusting the NH4+uptake and synchronization-related precursor carbamoyl phosphate pathway,the L-arginine production was increased by 37%,however,the cell growth was inhibited by these gene modifications.To conquer this,Nucleoside Triphosphate(NTP)supply was firstly enhanced by regulating the purine pathway,which was beneficial for cellular repair and enhancing strain's stress resistance.Meanwhile,weakening the L-arginine import system reduces L-arginine consumption and conserves ATP.The final strain produced 102.4 g/L L-arginine,with a yield of 0.48 g/g glucose in 5-L bioreactor.The innovative approach of synergistic adjusting ammonia uptake and the purine pathway,balanced cell growth and boosted L-arginine production,offering valuable guidance for in-dustrial microbial synthesis of other nitrogen-rich chemicals.
基金financially supported by the National Natural Science Foundation of China(Grant Nos.51774060,U19B2009)the Program for Changjiang Scholars and Innovative Research Team in University(IRT_17R112)+1 种基金the Basic Research and Frontier Exploration Projects in Chongqing(cstc2019jcyj-msxmX0053,cstc2019yszx-jcyjX0007)Shaanxi innovation capability support plan(2019KJXX-023).
文摘CO_(2) enhanced shale gas recovery(CO_(2)-ESGR)has attracted extensive attention as it can improve the shale gas recovery efficiency and sequestrate CO_(2) simultaneously.In this study,the relationship between mineral composition,pore structure,CH_(4) and CO_(2) adsorption behavior as well as selective adsorption coefficient of CO_(2) over CH_(4)(αCO_(2)/CH_(4))in marine and continental shales at different temperatures was investigated.The results illustrated that shale with higher total organic carbon(TOC),higher clay minerals and lower brittle mineral contents has a larger micropores and mesopores volume and specific surface area.TOC content was positively correlated with fractal dimension Df.Both CH_(4) and CO_(2) adsorption capacity in shale have positive correlations with TOC and clay mineral content.CO_(2) adsorption capacity of the all the tested shale samples were greater than CH_(4),and theαCO_(2)/CH_(4) of shale were larger than 1.00,which indicated that using CO_(2)-ESGR technology to improve the gas recovery is feasible in these shale gas reservoirs.A higher TOC content and in shale corresponding to a lowerαCO_(2)/CH_(4) due to the organic matters show stronger affinity on CH_(4) than that on CO_(2).Shale with a higher brittle mineral content corresponding to a higherαCO_(2)/CH_(4),and no obvious correlation betweenαCO_(2)/CH_(4) and clay mineral content in shale was observed due to the complexity of the clay minerals.TheαCO_(2)/CH_(4) of shale were decreased with increasing temperature for most cases,which indicated that a lower temperature is more favorable for the application of CO_(2)-ESGR technique.
基金supported by the Strategic Research and Consulting Project of Science and Technology Committee of China National Petroleum Corporation(2023DQ0706)the National Key Research and Development Program of China(2021YFC2102902)。
文摘The global chemical industry market is steadily improving after the pandemic.According to statistics from the European Chemical Industry Council(CEFIC),the industry's market value was 4.4 trillion dollars in 2022 and is projected to rise to 9.0 trillion dollars by 2030[1,2].Chemical manufacturing produces more than70,000 diverse products each year,ranging from agricultural chemicals,basic chemicals,specialty chemicals,and consumer products to pharmaceuticals.
基金This work was funded by the National Key Research and Development Program of China(2018YFA0900300)the National Natural Science Foundation of China(31770058,32070035)+3 种基金Natural Science Foundation of Jiangsu Province(BK20181205)the Key Research and Development Program of Ningxia Hui Autonomous Region(No.2019BCH01002)the national first-class discipline program of Light Industry Technology and Engineering(LITE2018-06)the 111 Project(111-2-06).
文摘Racemize 2-hydroxybutyric acid is usually synthesized by organic methods and needs additional deracemization to obtain optically pure enantiomers for industrial application.Here we present a cascade biocatalysis system in Escherichia coli BL21 which employed L-threonine deaminase(TD),NAD-dependent L-lactate dehydrogenase(LDH)and alcohol dehydrogenase(ADH)for producing optically pure(S)-2-hydroxybutyric acid((S)-2-HBA)from bulk chemical L-threonine.To solve the mismatch in the conversion rate and the consumption rate of intermediate 2-oxobutyric acid(2-OBA)formed in the multi-enzyme catalysis reaction,ribosome binding site regulation strategy was explored to control TD expression levels,achieving an eightfold alteration in the conversion rate of 2-OBA.With the optimized activity ratio of the three enzymes and using ADH for NADH regeneration,the recombinant strain ADH-r53 showed increased production of(S)-2-HBA with the highest titer of 129 g/L and molar yield of 93%within 24 h,which is approximately 1.65 times that of the highest yield reported so far.Moreover,(S)-2-HBA could easily be purified by distillation,making it have great potential for industrial application.Additionally,our results indicated that constructing a tunable multi-enzyme-coordinate expression system in single cell had great significance in biocatalysis of hydroxyl acids.
基金the National Natural Science Foundation of China(Grant No.52174107)the Basic Research and Frontier Exploration Projects in Chongqing(No.cstc2021 yszx-jcyjX0010).
文摘The pore structure of caprock plays an important role in underground gas storage security, as it significantly influences the sealing capacity of caprock. However, the pore structure evolution of caprock with the cyclic stress perturbations triggered by the cyclic gas injection or extraction remains unclear. In this study, the pore structure changes of mudstone caprock under cyclic loading and unloading were obtained by the nuclear magnetic resonance (NMR) tests system, then the influence of the changes on the breakthrough pressure of caprock was discussed. The results indicated that the pore structure changes are depending on the stress loading-unloading path and stress level. In the first cyclic, at the loading stage, with the increase of confining stress, the NMR T2 spectrum curve moved to the left, the NMR signal amplitude of the first peak increased, while the amplitude of the second peak decreased gradually. This indicated that the larger pores of mudstone are compressed and transformed into smaller pores, then the number of macropores decreased and the number of micro- and mesopores increased. For a certain loading-unloading cycle, the porosity curve of mudstone in the loading process is not coincide with that in the unloading process, the porosity curve in the loading process was located below that in the unloading process, which indicated that the pore structure change is stress path dependent. With the increase of cycle numbers, the total porosity shown an increasing trend, indicating that the damage of mudstone occurred under the cyclic stress load-unload effects. With the increase of porosity, the breakthrough pressure of mudstone decreased with the increase of the cyclic numbers, which may increase the gas leakage risk. The results can provide significant implication for the underground gas storage security evaluation.
