The present disclosure provides devices, systems, methods for processing and/or analyzing a biological sample. An analytic device for processing and/or analyzing a biological sample may comprise a moving carriage. The analytic device may be portable. The analytic device may receive instructions for performing an assay from a mobile electronic device external to a housing of the analytic device.

Automated analyzer (2000) comprising a housing (2010, 3010), a robotic arm comprising an end effector (2360), the end effector (2360) comprising a body (2320) rotatably connected to an articulating arm and first (2363a) and second fingers (2363b) coupled to the body (2362) and being moveable relative to each other in a first direction, each of the fingers (2363a, b) having an engagement feature (2361) projecting inwardly from each of the first and second fingers (2363a, b) and toward the other of the first and second fingers (2363a, b). The automated analyzer (2000) further comprises a shuttle platform (2030) for receiving a shuttle (2030) carrying sample containers (03), the containers carrying sample (03) to be evaluated by the analyzer (2000) and the shuttle platform (2030) comprising a jaw assembly that engages the bottom portion of the sample containers when the jaw assembly is in the closed position.

A point-of-care device for detecting nucleic acid is disclosed. The point-of-care device for detecting nucleic acid according to an exemplary embodiment of the present invention includes a rotating body in which a plurality of test tubes containing a sample mixed with heat-generating particles that generate heat when irradiated with light beams are radially coupled around a rotation shaft; a first actuator for rotating the rotating body such that the test tube rotates about the rotation shaft; and an irradiation module for irradiating the light beams to an irradiated area which is set on a rotation path of the test tube, wherein the rotation path includes a non-irradiated area to which the light beams are not irradiated, and wherein the test tube proceeds through the irradiated area and the non-irradiated area on the rotation path according to the rotation of the rotating body.

An automated analyzer capable of continuously performing supply of consumables is realized while continuing measurement is performed, by a simple and small amount of mechanism. An automated analyzer includes a unit that executes processing necessary for sample analysis; a consumable supply unit that supplies consumables necessary for the sample analysis to the unit; and a control device that controls operations of the unit and the consumable supply unit, in which the consumable supply unit includes a consumable container holding portion that holds a consumable storage container in which consumables is aligned and accommodated, a preliminary storage portion that temporarily holds the consumables taken out from the consumable storage container, and a transport mechanism that transports the consumables to the unit, and in which the control device transports and stores at least a portion of the consumables taken out from the consumable storage container in the preliminary storage portion.

A system for collecting a biological sample from a passenger cabin includes a collector for collecting particulate samples positioned within at least one of an outlet flow path or a recirculation flow path. The system includes at least one of an outflow valve positioned in the outlet flow path downstream from the collector or a HEPA (high efficiency particulate air) filter positioned in the recirculation flow path downstream from the collector. A method for collecting particulates from cabin air includes capturing particulates in at least one of an outlet flow path or a recirculation flow path with a collector for a period of time, removing the collector from at least one of the outlet flow path or the recirculation flow path for testing, and inserting a clean collector into at least one of the outlet flow path or the recirculation flow path for use during another period of time.

A storage device (20) stores a gas measuring device (10). The gas measuring device (10) has at least one electrochemical sensor (11) for measuring the concentration of a gas. The storage device (20) has a temperature control device (21) for controlling the temperature of the electrochemical sensor (11). A system (40) includes such a storage device (20) and a gas measuring device (10) that is stored therein. The temperature control device (21) is arranged at the storage device (20) such that the temperature control device (21) is located opposite the electrochemical sensor (11) of the gas measuring device (10) during the temperature control. A process for storing a gas measuring device (10) in such a storage device (20) includes controlling the temperature of the electrochemical sensor (11) of the gas measuring device (10) by the temperature control device (21) during the storage.

A portable medical diagnostic device (100) to collect and analyze one or more biological specimen of a user is provided. The device (100) includes a housing having an interactive display (102) and a keypad (104). The keypad (104) comprises a plurality of selectable keys (106-1 or 106-2). The device (100) includes one or more biological specimen collection modules (108) operatively connected to the housing to receive at least one biological specimen of the user. One or more biological specimen collection modules (108) are communicably coupled with at least one selectable key of the selectable keys (106-1 or 106-2). The device (100) includes one or more sensors (110) provided in each of biological specimen collection module (108), configured to analyze at least one biological specimen received in the associated biological specimen collection module to determine one or more parameters of the biological specimen to be displayed on the interactive display (102).

A holding portion includes a first holding portion and a second holding portion that respectively hold a first cassette holder and a second cassette holder, a chemical liquid bottle holding portion including a first chemical liquid bottle holding portion and a second chemical liquid bottle holding portion, and a paraffin-filled bottle holding portion including a first paraffin-filled bottle holding portion and a second paraffin-filled bottle holding portion. The first cassette holder is inserted into the chemical liquid bottle provided to the first chemical liquid bottle holding portion and the paraffin-filled bottle provided to the first paraffin-filled bottle holding portion. Furthermore, the second cassette holder is inserted into the chemical liquid bottle provided to the second chemical liquid bottle holding portion and the paraffin-filled bottle provided to the second paraffin-filled bottle holding portion.

Disclosed herein are platforms, systems, and methods including a cell culture system that includes a cell culture container comprising a cell culture, the cell culture receiving input cells, a cell imaging subsystem configured to acquire images of the cell culture, a computing subsystem configured to perform a cell culture process on the cell culture according to the images acquired by the cell imaging subsystem, and a cell editing subsystem configured to edit the cell culture to produce output cell products according to the cell culture process.

The self-contained kit comprises methods for receiving and preparing the biological samples for the nucleic acid amplification and sensing the presence of the target assay. The kit consists of a self-heating pack to provide the heat for nucleic acid sample preparation and amplification processes. The change of the amplification is indicated through colorimetric or turbidity sensing and detected through a mobile phone camera and associated mobile application for photographic scanning of physical or chemical differences of the samples to produce the test results.