2022
DOI: 10.1002/elps.202200150
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Microfluidic systems in clinical diagnosis

Abstract: The use of microfluidic devices is highly attractive in the field of biomedical and clinical assessments, as their portability and fast response time have become crucial in providing opportune therapeutic treatments to patients. The applications of microfluidics in clinical diagnosis and point‐of‐care devices are continuously growing. The present review article discusses three main fields where miniaturized devices are successfully employed in clinical applications. The quantification of ions, sugars, and smal… Show more

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Cited by 14 publications
(4 citation statements)
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“…The first electrophoretic separation of intact microbes in the manner of molecules was reported by Armstrong et al in 1999 [598]. Since then, numerous electrophoretic approaches, including a vast range of MCE systems, have been successfully employed for the detection and separation of intact virus, bacterial, and yeast cells [590,599,600]. A new approach in microfluidic devices that exploits nonlinear electrophoretic effects have also been recently proposed for the rapid electrophoretic-based separation of intact microorganisms, microparticles, and proteins [601][602][603][604].…”
Section: Overview Of Methods Development Advances and Recent Applicat...mentioning
confidence: 99%
“…The first electrophoretic separation of intact microbes in the manner of molecules was reported by Armstrong et al in 1999 [598]. Since then, numerous electrophoretic approaches, including a vast range of MCE systems, have been successfully employed for the detection and separation of intact virus, bacterial, and yeast cells [590,599,600]. A new approach in microfluidic devices that exploits nonlinear electrophoretic effects have also been recently proposed for the rapid electrophoretic-based separation of intact microorganisms, microparticles, and proteins [601][602][603][604].…”
Section: Overview Of Methods Development Advances and Recent Applicat...mentioning
confidence: 99%
“…Instead of forming a dynamic distribution of suspended nanodroplets (i.e., an emulsion), single droplets can be formed one at a time with precise control over droplet dimensions. Microfluidic devices have been developed to create reproducible and stable nanodroplets for studies toward nanomedicine and clinical diagnosis, biosensing , and cell studies, environmental analysis and treatment, and chemical and nanomaterial synthesis . Microfluidics work by carefully controlling fluid flow within nanochambers/channels.…”
Section: Nanodroplets As Nanoconfinement Reactorsmentioning
confidence: 99%
“…31 The technology has found numerous applications in biology and biotechnology. 18,[32][33][34][35][36][37][38][39] Currently, this technology is applied for fundamental research 40 , i.e., food screening 41,42 and molecular sensing 43,44 and has proven useful for commercial applications, e.g., PCR testing 45…”
Section: Introductionmentioning
confidence: 99%