A heating device for testing a biological sample is disclosed. The heating device can include a heat source operable to generate heat. In addition, the heating device can include a controller in communication with the heat source and operable to control heat generation by the heat source to heat a biological sample at less than or equal to about 2 degrees C./s. Furthermore, a heating device for testing a biological sample is disclosed that can include a heat source operable to generate heat to heat a biological sample. The biological sample can be at least partially contained within a removable enclosure distinct from the heating device. Additionally, the heating device can include an enclosure interface associated with the heat source. The enclosure interface can be configured to interface with the enclosure such that heat is transferred from the heat source to the enclosure by conduction.

A microfluidic system for fluid transport is provided. The microfluidic system includes a microfluidic device. The microfluidic device includes an inlet body including an inlet. The microfluidic device includes a base supporting the inlet body. The base includes a channel in fluid communication with the inlet. The base includes one or more sensors formed on a surface of the channel, or one or more sensors formed in one or more wells formed in the surface of the channel. The channel is configured to facilitate flow of the fluid. The fluid includes a plurality of beads. The fluid includes a plurality of suspended cells. The inlet is configured to receive the fluid at an inlet port. The inlet is configured to output the fluid through an opening in fluid communication with the channel. The inlet is configured to provide substantially uniform flow of the fluid across a substantial portion of a horizontal dimension of the channel. The device is configured to compensate for edge effects otherwise present therein. Related methods, apparatuses, systems, techniques and articles are also described.

The present disclosure is drawn to devices and systems for target detection in samples, particularly allergen detection in food samples. The allergen detection system includes a sampler, a disposable analysis cartridge and a detection device with an optimized optical system. The allergen detection utilizes nucleic acid molecules as detection agents and detection probes.

A method is provided comprising loading shells into shell retention chambers of a shell management module, the shells including corresponding reservoirs configured to hold individual quantities of liquid, the shell retention chambers arranged in a predetermined pattern on a platform of the shell management module. The method further comprises orienting discharge ends of the shells along an actuation direction within the shell retention chambers, and covering the discharge ends with closure lids to seal bottoms of the corresponding reservoirs.

The present invention provides systems, devices, kits, and methods for separating blood plasma or serum from whole blood. The present invention further provides systems, devices, and methods for separating a volume of blood plasm a or serum from whole blood.

Methods and systems are provided for point-of-care nucleic acid amplification and detection. One embodiment of the point-of-care molecular diagnostic system includes a cartridge and an instrument. The cartridge can accept a biological sample, such as a urine or blood sample. The cartridge, which can comprise one or more of a loading module, lysis module, purification module and amplification module, is inserted into the instrument which acts upon the cartridge to facilitate various sample processing steps that occur in order to perform a molecular diagnostic test.

In some embodiments, a stand-alone molecular diagnostic test device includes a detection circuit that includes a light emitting device and a light receiving device (e.g., a photodiode) that are arranged to produce an electronic signal associated with a colorimetric output produced by the stand-alone molecular diagnostic test.

Described herein are multimodal test cards. The test cards include a shared architecture with interchangeable test zones. The test cards are particularly useful for diagnostic testing.

The present invention provides a microfluidic devices and methods of use thereof for the concentration and capture of cells. A pulsed non Faradaic electric field is applied relative to a sample under laminar flow, which results to the concentration and capture of charged analyte. Advantageously, pulse timing is selected to avoid problems associated with ionic screening within the channel. At least one of the electrodes within the channel is coated with an insulating layer to prevent a Faradaic current from flowing in the channel. Under pulsed application of a unipolar voltage to the electrodes, charged analyte within the sample is moved towards one of the electrodes via a transient electrophoretic force.

Embodiments of the present invention relate to microfluidic devices and systems comprising such devices for use in the determination of sample characteristics. Certain embodiments relate to methods for determining one or more characteristics of a sample comprising a compound for in vivo use. Aptly, certain embodiments of the present invention relate to devices and methods for assessing radiopharmaceuticals and their suitability for administration to a patient in need thereof.