A sample collection and detection device includes a collection cavity. The device further includes a sample collector. The sample collector comprises a collection rod and an absorption element, and the absorption element has a hollow cavity. A part of the collection rod is received in the hollow cavity of the absorption element. A first lug for blocking and locating the absorption element is arranged on the collection rod. Also provided is a method for collecting and detecting sample using the sample collection and detection device.

A colorimetric sensor for detecting an analyte of interest that includes multiple surfaces and a molecularly imprinted polymer defining a cavity shaped to receive an analyte of interest. Each surface defines a void (e.g., a pore or a nanohole) and at least one surface defines a fluid inlet. The sensor is configured such that, when an analyte contacts the molecularly imprinted polymer and becomes disposed within the cavity, a wettability of at least one of the surfaces changes thereby to cause a detectable color change in the sensor. Optionally, the sensor may also include a metal layer at a bottom of each void or nanohole and outside a top of each void or nanohole for use as a plasmon resonance-type sensor.

A lateral flow testing device (1) comprises a main body (3) adapted to support an element (5) for collecting a sample (100), said sample collection element (5) being supported at a distal end (1d) of the testing device (1) and being in fluid communication with one or more testing components (7), the testing components comprising an analyte detection zone for detecting one or more analytes present in said sample. The testing components produce visual information (200) related to said sample (100), thereby informing the user of the outcome of a test. The device incorporates a handle (9) reconfigurable with respect to said main body (3) such that in one or more first handle configurations (11) the handle (9) hinders sight of the visual information (200), and in one or more second handle configurations (13) the handle (9) facilitates the collection of said sample (100) by increasing a distance between a proximal end (1p) of the testing device (1) and the sample collection element (5). The testing device (1) is adapted such that the handle (9) is reconfigurable from at least one of said second handle configurations (13) to at least one of said first handle configurations (11) to hinder sight of the visual information (200) after that said testing has been carried out, therefore improving the privacy of the test.

Devices, systems, and methods for detecting molecules of interest within a collected sample are described herein. In certain embodiments, self-contained sample analysis systems are disclosed, which include a reusable reader component, a disposable cartridge component, and a disposable sample collection component. The reader component may communicate with a remote computing device for the digital transmission of test protocols and test results. In various disclosed embodiments, the systems, components, and methods are configured to identify the presence, absence, and/or quantity of particular nucleic acids, proteins, or other analytes of interest, for example, in order to test for the presence of one or more pathogens or contaminants in a sample.

This system takes in raw cellular material collected using a provided swab, blood collection device, urine collection device, or other sample collection device and transforms that biological material into a digital result, identifying the presence, absence and/or quantity of nucleic acids, proteins, and/or other molecules of interest.

Embodiments of the invention comprise a test strip configured to detect one or more metabolites of progesterone in urine, and optionally further detect one or more additional metabolites or hormones in urine within the same test strip. Embodiments of the invention are methods of utilizing such a test strip in association with avoidance of pregnancy, detection of menopause, and in association with fertility planning purposes. Embodiments of the invention are associated with the incorporation of a test strip within a testing kit, optionally further comprising a digital reader.

This disclosure describes a slide comprising a substrate, a RFID or WISP, and a temperature sensor, wherein the slide is capable of communicating with an external communications device via the RFID or WISP. In some implementations, the RFID or WISP of the slide comprises an antenna, an integrated circuit, a memory unit, and a power source, such that it is capable of measuring and logging data related to time and temperature. In some implementations, the RFID or WISP and temperature sensor are embedded in the substrate to prevent direct contact with mounted specimens. In some implementations the slide further comprises displayed content. In some implementations, the displayed content is linked to a database of information. The various implementations of this invention may describe a slide utilizing any number of the features described above in any combination.

A testing system and method for providing a testing system includes a user interface having a display for displaying information relating to measurements of health data and an input device for receiving information from a user relating to the health data. Provided in connection with the user interface is an autologging feature adapted to provide the user with user-selectable options on the display. Also provided is a statistical operation adapted to provide the user with enhanced information relating to the measurements of health data. Also provided is at least one indicator for indicating information relating to the number of health data readings that are within a target range, the number of health data readings that are above the target range and the number of health data readings that are below the target range.

This invention relates generally to devices, systems, and methods for performing biological assays by using indicators that modify one or more optical properties of the assayed biological samples. The subject methods include generating a reaction product by carrying out a biochemical reaction on the biological sample introduced into a device and reacting the reaction product with an indicator capable of generating a detectable change in an optical property of the biological sample to indicate the presence, absence, or amount of analyte suspected to be present in the sample.

The present disclosure relates to a system, method, and kit for particle detection and analysis. Devices disclosed herein may include at least an optical source, a fluidic chip containing a multiplex bead array, and a detection module, wherein the sample flows within the fluidic chip past a detection window, where the cells or particles are imaged by an image acquisition and analysis module that may include an optical detector. The image acquisition and analysis module counts the labeled particles and software allows for analysis of bead population.