A medical testing apparatus for a user to help to authenticate and track the process of a test kit that is received into the medical test apparatus, the test kit includes components of an extended nasal/oral swab, a buffer tube, a reagent disposed within the buffer tube, a nozzle cap, and a test card, the kit is for testing for a presence or a non-presence of an infection that utilizes an internet connected electronic device with a camera for communication to third parties. The apparatus includes a test stand that is configured to partially receive the electronic device and to partially receive the test kit in a positional alignment to for the camera to record an unique identification code for each test kit component, and for the camera user facial recognition, further the test stand camera records infection status.

A test strip including: a first site that's a detection site, where a first antibody specifically binding to the substance to be measured is immobilized on a porous carrier; a second site that's a specimen liquid addition site, where a second labeled antibody binding to the substance to be measured and having a recognition site different from that of the first antibody is retained on a porous carrier to be movable; and a third site that is a specimen liquid or developer addition site, where colored microparticles bound with a substance binding to a label substance of the second antibody are retained on a porous carrier to be movable, wherein the second site is provided between the first and the third sites, and the specimen liquid or developer can move, due to capillarity, from the second site to the first and from the third to the first site.

A test strip holder includes: a holding member at which at least a portion of a lower side of an inner periphery is a cylindrical surface having a cylindrical shape, and at whose interior a test strip is held, and at which a direction of an imaginary central axis of the cylindrical surface is a horizontal direction or a direction inclined with respect to a vertical direction; an opening portion provided in an outer surface of the holding member; a sorting member rotating at an interior of the holding member around a rotation axis that coincides with the central axis; a pushing piece projecting out from a distal end edge, which is parallel to the central axis, at the sorting member in a direction of rotation of the sorting member; and a sorting piece projecting out from a distal end of the pushing piece toward the cylindrical surface.

A test strip container includes: an accommodating member in which a test strip is accommodated; a moving member moving the test strip therein; a door member opening and closing at a side surface of the accommodating member to discharge the test strip out of the accommodating member, and cutting the interior and the exterior of the accommodating member off from each other when closed; a door accommodating portion covering the door member, in which the door member can open and close; and a discharge opening cutting the interior and an exterior of the door accommodating portion off from each other when closed, and is provided at the door accommodating portion so as to open and close to discharge the test strip to the exterior of the door accommodating portion, the discharge opening being able to open when the accommodating member is closed by the door member.

The disclosure describes an integrated fluid sample test strip comprising: an inlet for receiving solutions comprising a fluid sample and a substrate solution, the inlet comprising a retention valve for temporarily retaining each solution to thereby reduce air flow through the valve; a reaction chamber to receive the solutions via the retention valve, the chamber functionalized with bioreceptor(s); a capillary pump to receive from the reaction chamber the solution(s), the pump comprising vent hole(s); a test chamber to receive the substrate solution from the reaction chamber, the test chamber comprising test electrodes for a biosensing test of the substrate solution; a hydrophobic vent hole coupled to the test chamber to allow a flow of solution from the reaction chamber into the test chamber when the vent hole is unsealed and to allow a flow of solution from the reaction chamber to the capillary pump when the vent hole is sealed.

A detection device, the device comprising a sample liquid bearing device (300), test strips (200), a test strips bearing plate (100) and a signal acquisition positioning assisting device, wherein the sample liquid bearing device (300) comprises two or more samples cells (320) used for containing sample liquid, each of the test strips (200) at least comprises an identity information bearing part (250), a developing part (220) and a capillary part (210), the test strip bearing plate (100) is used for placing the test strips (200) in the same circular ring in a circumferential array radial manner, and the signal acquisition positioning assisting device is arranged on the test strip bearing plate and is used for positioning the test strips.

Provided herein are systems and methods for a point of need testing system. In some embodiments, the point of need testing system includes a first collector and a sample amplifier. The first collector is configured to collect a first biofluid sample. The sample amplifier includes an inlet dimensioned to receive the first biofluid sample. The sample amplifier further includes a filter, a heater, and a second collector. In some embodiments, a reader can be used with the sample amplifier to read a second biofluid produced by the sample amplifier.

Method, apparatus, and computer program product are provided for anonymized diagnosis using lateral flow assays. In some embodiments, a test card includes one or more lateral flow assay (LFA) with one or more test patterns (e.g., full line, partial line, dot), one or more dummy patterns, and one or more control patterns. To visually encode LFA results, at manufacture, one or more lines/dots containing true results of the LFA(s) each has a position mixed with other “dummy” lines/dots, in randomized position patterns selected from among a plurality of possible position patterns. An optical machine-readable representation of data (e.g., QR code) is attached to the test card and encodes test card identification information (e.g., lot number, serial number, test type) associated with the test card. In some embodiments, a passcode card having a scrapeable coating that conceals a passcode associated with the test card is removably attached to the test card.

A system for analyzing a physiological sample includes a cartridge configured to attach to the skin of a subject. The cartridge includes: a processing fluid pack that is configured to release a processing fluid stored therein, a diagnostic test strip, and a vacuum pin. The system also includes a lancet with a needle. The lancet is configured to deploy the needle upon engagement with the cartridge to draw a physiological sample from the subject. The vacuum pin is configured to create a vacuum within the cartridge to draw the released processing fluid and the drawn physiological sample to the diagnostic test strip.

The disclosure relates to methods of manufacturing and using a single layer microfluidic for detecting target analytes, including obtaining a single layer sheet of paper; depositing wax boundaries onto the paper in a plurality of patterns including a main channel, fluid transfer channels, and an independent diagnostic area corresponding to each fluid transfer channel; melting the wax through the paper; depositing diagnostic components onto the diagnostic areas; depositing a continuous wax backing; and cutting devices from the paper. The disclosure also relates to a method of capturing an image of the micro fluidic device to generate diagnostic results corresponding to the diagnostic components by: identifying at least two panels from the image; and determining a color for each panel of the at least two panels; and generating for display, using the computing device, a graphical user-interface including at least one component visualizing the diagnostic results.