We report on an inertial focussing based microfluidics technology for concentrating waterborne protozoa, achieving a 96% recovery rate of Cryptosporidium parvum and 86% for Giardia lamblia at a throughput (mL/min) capable of replacing centrifugation. The approach can easily be extended to other parasites and also bacteria
Protozoa and bacteria can easily cause disease in humans, specifically E. coli, Plasmodium falciparu...
We have designed, built, and evaluated a microfluidic device that uses deterministic lateral displac...
Detecting pathogenic bacteria in food or other biological samples with lab-on-a-chip (LOC) devices r...
We report on an inertial focussing based microfluidics technology for concentrating waterborne proto...
This work focuses on the development of a microfluidic platform (lab on a chip) for the measurement ...
Ce travail de recherche porte sur le développement d’une plateforme microfluidique de type laboratoi...
Each year, waterborne diseases have caused approximate 2 million deaths based on World Health Organi...
We present an integrated microfluidic system for performing isolation and concentration of Phytophth...
Severe epidemics in North America due to consumption of polluted water containing pathogens such as ...
Inertial focusing is a promising microfluidic technology for concentration and separation of particl...
Abstract Background Protecting drinking water supplies from pathogens such as Cryptosporidium parvum...
Protecting drinking water supplies from pathogens such as Cryptosporidium parvum is a major concern ...
Detecting waterborne pathogens is a challenging task because of their low concentration in water and...
Early detection of pathogenic microorganisms is pivotal to diagnosis and prevention of health and sa...
Many modern filtration technologies are incapable of the complete removal of Cryptosporidium oocysts...
Protozoa and bacteria can easily cause disease in humans, specifically E. coli, Plasmodium falciparu...
We have designed, built, and evaluated a microfluidic device that uses deterministic lateral displac...
Detecting pathogenic bacteria in food or other biological samples with lab-on-a-chip (LOC) devices r...
We report on an inertial focussing based microfluidics technology for concentrating waterborne proto...
This work focuses on the development of a microfluidic platform (lab on a chip) for the measurement ...
Ce travail de recherche porte sur le développement d’une plateforme microfluidique de type laboratoi...
Each year, waterborne diseases have caused approximate 2 million deaths based on World Health Organi...
We present an integrated microfluidic system for performing isolation and concentration of Phytophth...
Severe epidemics in North America due to consumption of polluted water containing pathogens such as ...
Inertial focusing is a promising microfluidic technology for concentration and separation of particl...
Abstract Background Protecting drinking water supplies from pathogens such as Cryptosporidium parvum...
Protecting drinking water supplies from pathogens such as Cryptosporidium parvum is a major concern ...
Detecting waterborne pathogens is a challenging task because of their low concentration in water and...
Early detection of pathogenic microorganisms is pivotal to diagnosis and prevention of health and sa...
Many modern filtration technologies are incapable of the complete removal of Cryptosporidium oocysts...
Protozoa and bacteria can easily cause disease in humans, specifically E. coli, Plasmodium falciparu...
We have designed, built, and evaluated a microfluidic device that uses deterministic lateral displac...
Detecting pathogenic bacteria in food or other biological samples with lab-on-a-chip (LOC) devices r...
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