Submicron-precision particle characterization in microfluidic impedance cytometry with double differential electrodes
Jianwei Zhong, Minhui Liang, Ye Ai
Abstract
= 0.99938). It also shows that population ratios of differently sized beads in mixture samples are consistent with the results given by commercial fluorescence-based flow cytometry (within ∼1% difference). This work provides a label-free approach with submicron precision for sizing and counting microscale and submicron particles, and a new avenue of designing electrode configurations with a feature of suppressing the electrical noise for accomplishing a high signal-to-noise ratio in a wide range of frequencies. This novel double differential impedance sensing system paves a new pathway for real-time analysis and accurate particle screening in pathological and pharmacological research.
Topics & Concepts
MicrofluidicsSizingMicroscale chemistryMaterials scienceElectrical impedanceElectrodeMiniaturizationCytometryNanotechnologyDielectrophoresisOptoelectronicsPopulationAnalytical Chemistry (journal)Flow cytometryChemistryElectrical engineeringEngineeringChromatographyDemographyMathematics educationMathematicsSociologyGeneticsBiologyPhysical chemistryOrganic chemistryMicrofluidic and Bio-sensing TechnologiesBiosensors and Analytical DetectionElectrical and Bioimpedance Tomography