Antimicrobial resistance(AMR)is a growing global threat,especially in low-and middle-income countries(LMICs),causing prolonged illnesses,heightened antimicrobial use,increased healthcare expenses,and avoidable deaths....Antimicrobial resistance(AMR)is a growing global threat,especially in low-and middle-income countries(LMICs),causing prolonged illnesses,heightened antimicrobial use,increased healthcare expenses,and avoidable deaths.If not tackled,AMR could force 24 million people into severe poverty by 2030 and hinder progress on Sustainable Development Goals(SDGs).AMR spreads through interconnected ecosystems,with humans,animals,and the environment serving as reservoirs.Pharmaceutical wastewater,loaded with antibiotics and resistance genes,poses a significant environmental risk,mainly due to inadequate treatment and irresponsible disposal.The pharmaceutical industry is a notable contributor to environmental antibiotic pollution,with varying effluent management practices.Contaminated pharmaceutical wastewater discharge harms water sources and ecosystems.Urgent collaborative efforts are needed across policymakers,regulators,manufacturers,researchers,civil society,and communities,adopting a One Health approach to curb AMR's spread.Developing global standards for pharmaceutical effluent antibiotic residues,effective treatment methods,and improved diagnostics are vital in addressing AMR's environmental impact while safeguarding public health and the environment.National action plans should encompass comprehensive strategies to combat AMR.Preserving antibiotic efficacy and ensuring sustainable production require a united front from all stakeholders.展开更多
New Delhi metallo-β-lactamase (NDM-1) has created a medical storm ever since it was first reported;as it is active on virtually all clinically used β-lactam antibiotics. NDM-1 rampancy worldwide is now considered a ...New Delhi metallo-β-lactamase (NDM-1) has created a medical storm ever since it was first reported;as it is active on virtually all clinically used β-lactam antibiotics. NDM-1 rampancy worldwide is now considered a nightmare scenario, particularly due to its rapid dissemination. An underlying theme in the majority of recent studies is structural characterization as knowledge of the three-dimensional structure of NDM-1 shall help find connections between its structure and function. Moreover, structural details are even critical in order to reveal the resistance mecha- nism to β-lactam antibiotics. In this perspective, we review structural characteristics of NDM-1 that have been delineated since its first report. We anticipate that these structure-function connections made by its characterization shall further serve as future guidelines for elucidating pathways towards de novo design of functional inhibitors.展开更多
In view of it's strong antibacterial function and minor toxicity,cuprous oxide (Cu2O) is frequently used in various broad-spectrum antibacterial reagents.Nonetheless the undesirable effects of superbugs still rema...In view of it's strong antibacterial function and minor toxicity,cuprous oxide (Cu2O) is frequently used in various broad-spectrum antibacterial reagents.Nonetheless the undesirable effects of superbugs still remain challenging.In this research,a chemical deposition approach is used to prepare a Cu2O@ZrP composite with nanosheet configuration demonstrating excellent dispersibility and antibacterial traits.From systematic analysis,it was inffered that the content of copper in the nanosheet was about 57-188 mg/g while the average thickness of the nanosheets Cu2O formed on ZrP is approximately 0.8 nm.The results of the minimal inhibitory concentration (MIC) revealed that an extremely low loading of Cu2O in Cu2O@ZrP nanosheet can lead to exceptional antibacterial activity.Examined on two various superbugs;i.e.methicillin-resistant staphylococcus aureus (MRSA) and vancomycin-resistant enterococcus (VRE),the composite nanosheet reagent performed over 99% microbial reduction.More intesetingly,the cell growth rate of the Cu2O@ZrP nanosheet was determined to be 20% lower than that of the neat Cu2O,manifesting a weaker cytotoxicity.This unique hybrid nanosheet with intriguing anti-superbug performance promises highly efficient protection for the fabrics,battledress,and medical textiles.展开更多
文摘Antimicrobial resistance(AMR)is a growing global threat,especially in low-and middle-income countries(LMICs),causing prolonged illnesses,heightened antimicrobial use,increased healthcare expenses,and avoidable deaths.If not tackled,AMR could force 24 million people into severe poverty by 2030 and hinder progress on Sustainable Development Goals(SDGs).AMR spreads through interconnected ecosystems,with humans,animals,and the environment serving as reservoirs.Pharmaceutical wastewater,loaded with antibiotics and resistance genes,poses a significant environmental risk,mainly due to inadequate treatment and irresponsible disposal.The pharmaceutical industry is a notable contributor to environmental antibiotic pollution,with varying effluent management practices.Contaminated pharmaceutical wastewater discharge harms water sources and ecosystems.Urgent collaborative efforts are needed across policymakers,regulators,manufacturers,researchers,civil society,and communities,adopting a One Health approach to curb AMR's spread.Developing global standards for pharmaceutical effluent antibiotic residues,effective treatment methods,and improved diagnostics are vital in addressing AMR's environmental impact while safeguarding public health and the environment.National action plans should encompass comprehensive strategies to combat AMR.Preserving antibiotic efficacy and ensuring sustainable production require a united front from all stakeholders.
文摘New Delhi metallo-β-lactamase (NDM-1) has created a medical storm ever since it was first reported;as it is active on virtually all clinically used β-lactam antibiotics. NDM-1 rampancy worldwide is now considered a nightmare scenario, particularly due to its rapid dissemination. An underlying theme in the majority of recent studies is structural characterization as knowledge of the three-dimensional structure of NDM-1 shall help find connections between its structure and function. Moreover, structural details are even critical in order to reveal the resistance mecha- nism to β-lactam antibiotics. In this perspective, we review structural characteristics of NDM-1 that have been delineated since its first report. We anticipate that these structure-function connections made by its characterization shall further serve as future guidelines for elucidating pathways towards de novo design of functional inhibitors.
文摘In view of it's strong antibacterial function and minor toxicity,cuprous oxide (Cu2O) is frequently used in various broad-spectrum antibacterial reagents.Nonetheless the undesirable effects of superbugs still remain challenging.In this research,a chemical deposition approach is used to prepare a Cu2O@ZrP composite with nanosheet configuration demonstrating excellent dispersibility and antibacterial traits.From systematic analysis,it was inffered that the content of copper in the nanosheet was about 57-188 mg/g while the average thickness of the nanosheets Cu2O formed on ZrP is approximately 0.8 nm.The results of the minimal inhibitory concentration (MIC) revealed that an extremely low loading of Cu2O in Cu2O@ZrP nanosheet can lead to exceptional antibacterial activity.Examined on two various superbugs;i.e.methicillin-resistant staphylococcus aureus (MRSA) and vancomycin-resistant enterococcus (VRE),the composite nanosheet reagent performed over 99% microbial reduction.More intesetingly,the cell growth rate of the Cu2O@ZrP nanosheet was determined to be 20% lower than that of the neat Cu2O,manifesting a weaker cytotoxicity.This unique hybrid nanosheet with intriguing anti-superbug performance promises highly efficient protection for the fabrics,battledress,and medical textiles.
