As a promising concept,microfluidic paper-based analytical devices(μPADs)have seen rapid development in recent years.In this study,a new method of fabricatingμPADs by atom stamp printing(ASP)is proposed and studied....As a promising concept,microfluidic paper-based analytical devices(μPADs)have seen rapid development in recent years.In this study,a new method of fabricatingμPADs by atom stamp printing(ASP)is proposed and studied.The advantages of this new method compared to other methods include its low cost,ease of operation,high production efficiency,and high resolution(the minimum widths of the hydrophilic channels and hydrophobic barriers are 328 and 312μm,respectively).As a proof of concept,μPADs fabricated with the ASP method were used to detect different concentrations of Cu^(2+)via a colorimetric method.Moreover,combined with a distance-based detection method,these devices achieved a Cu^(2+)detection limit of down to 1mg/L.In addition,a new paper-based solid–liquid extraction device(PSED)based on a three-dimensional(3D)μPAD with a“3+2”structure and a recyclable extraction mode was developed.Specifically,using the characteristics of paper filtration and capillary force,the device completed multiple extraction and filtration steps from traditional solid–liquid extraction processes with high efficiency.The developed PSED platform allows the detection of heavy metal ions much more cheaply and simply and with a faster response time at the point of care,and it has great promise for applications in food safety and environmental pollution in resource-limited areas.展开更多
基金This work is sponsored by the National Natural Science Foundation of China(No.51505128)the Tackling Key Scientific and Technological Problems in Henan Province Fund(No.182102410061)。
文摘As a promising concept,microfluidic paper-based analytical devices(μPADs)have seen rapid development in recent years.In this study,a new method of fabricatingμPADs by atom stamp printing(ASP)is proposed and studied.The advantages of this new method compared to other methods include its low cost,ease of operation,high production efficiency,and high resolution(the minimum widths of the hydrophilic channels and hydrophobic barriers are 328 and 312μm,respectively).As a proof of concept,μPADs fabricated with the ASP method were used to detect different concentrations of Cu^(2+)via a colorimetric method.Moreover,combined with a distance-based detection method,these devices achieved a Cu^(2+)detection limit of down to 1mg/L.In addition,a new paper-based solid–liquid extraction device(PSED)based on a three-dimensional(3D)μPAD with a“3+2”structure and a recyclable extraction mode was developed.Specifically,using the characteristics of paper filtration and capillary force,the device completed multiple extraction and filtration steps from traditional solid–liquid extraction processes with high efficiency.The developed PSED platform allows the detection of heavy metal ions much more cheaply and simply and with a faster response time at the point of care,and it has great promise for applications in food safety and environmental pollution in resource-limited areas.