Abstract: A sample carrier may include a sample preparation module and an amplification module. A sample mixes with a lysis medium and a nucleic acid amplification medium in the sample preparation module and then flows into a plurality of microfluidic chambers in the amplification module. The microfluidic chambers have disposed therein primers configured to initiate amplification of one or more target nucleic acid sequences corresponding to one or more pathogens. The sample carrier is inserted into an apparatus that includes a plurality of Sight sources and a camera. The light sources illuminate the microfluidic chambers with excitation light, a fluorophore emits fluorescence light indicative of nucleic acid amplification in response to the excitation-light, and the camera captures images of the microfluidic chambers. A target nucleic acid sequence in the sample is indicated by the images showing an increasing fluorescence in a microfluidic chamber that has the primers for that sequence.

Abstract: A sample carrier may include a sample preparation module and an amplification module. A sample mixes with a lysis medium and a nucleic acid amplification medium in the sample preparation module and then flows into a plurality of microfluidic chambers in the amplification module. The microfluidic chambers have disposed therein primers configured to initiate amplification of one or more target nucleic acid sequences corresponding to one or more pathogens. The sample carrier is inserted into an apparatus that includes a plurality of Sight sources and a camera. The light sources illuminate the microfluidic chambers with excitation light, a fluorophore emits fluorescence light indicative of nucleic acid amplification in response to the excitation-light, and the camera captures images of the microfluidic chambers. A target nucleic acid sequence in the sample is indicated by the images showing an increasing fluorescence in a microfluidic chamber that has the primers for that sequence.

Abstract: Provided are methods and systems that characterize a property of a particle suspended in a fluid sample in a label-free manner. Detection elements are provided fluidically adjacent upstream and downstream from a modulation element. Fluid sample containing particles flows across a first detection element and a first particle parameter detected for each particle that passes the first detection element or a first aggregate particle parameter for a plurality of particles that pass the first detection element. The particles flow from the first detection element to a first modulation element, wherein the first modulation element effects a change in a property of the particles flowing past the first modulation element. A second detection element then detects the particle parameter again or a second aggregate particle parameter for a plurality of particles that pass the second detection element. Comparing the first and second particle or aggregate parameters thereby characterizes the particle property.