The present invention discloses a mobile laboratory for use in environment testing, comprising a laboratory casing, lifting hooks are provided at four corners of a top part of an outer wall of the laboratory casing, a supporting frame is provided beneath a bottom of the laboratory casing, an testing room is provided in one side of the laboratory casing and beneficial effects are: by providing lifting hooks, it is convenient to lift and move the mobile laboratory, change orientation as per usage conditions with a transportation vehicle and to build quickly a mobile laboratory for use in the testing site; and the signal transceiver transmits testing data collected by near-infrared spectroscopy, biosensor technology, biochip detection technology, ATP bioluminescence method, immunological analysis method and immunological analysis method by QR code tags, RFID tags, cameras, temperature sensors, sound sensors, vibration sensors, pressure sensors, RFID readers, QR code readers, and single-chip microcomputers.

A MEMS-based particle manipulation system which uses a particle manipulation stage and a plurality of laser interrogation regions. The laser interrogation regions may be used to assess the effectiveness or accuracy of the particle manipulation stage. In one exemplary embodiment, the particle manipulation stage is a microfabricated, flap-type fluid valve, which sorts a target particle from non-target particles in a fluid stream. The laser interrogation stages are disposed in the microfabricated fluid channels at the input and output of the flap-type sorting valve. The laser interrogation regions may be used to assess the effectiveness or accuracy of the sorting, and to control or adjust sort parameters during the sorting process. One or more feedback loops may be used to improve the particle manipulation process, based on data acquired during the first interrogation and/or during a downstream confirmation. Artificial intelligence techniques may be used to good effect.

This invention is in the field of medical devices. Specifically, the present invention provides fluidic systems having a plurality of reaction sites surrounded by optical barriers to reduce the amount of optical cross-talk between signals detected from various reaction sites. The invention also provides a method of manufacturing fluidic systems and methods of using the systems.

As one example, an apparatus includes a dielectric microsensor having a microfluidic chamber that includes a capacitive sensing structure. The microfluidic chamber is adapted to receive a volume of a blood sample, and a bioactive agent is adapted to interact with the blood sample, as a sample under test (SUT), within the microfluidic chamber. A transmitter can provide an input radio frequency (RF) signal to the dielectric microsensor, and a receiver can receive an output RF signal from the dielectric microsensor. A computing device is configured to compute dielectric permittivity values for the SUT based on the output RF signal over a time interval in which the dielectric permittivity values are representative of the bioactive agent interacting with the blood sample over the time interval. The computing device is further configured to provide a readout representative of hemostatic dysfunction for the blood sample based on the dielectric permittivity values.

The invention relates to a testing device with a testing assembly for lateral flow assay. The testing assembly comprises liquid sample receiving interface arranged on a support structure defining a plane. The liquid sample receiving interface is configured to receive a liquid sample. The testing assembly comprises at least one testing strip fluidly connected to the liquid sample receiving interface. The testing strip comprises a capillary wick fluidly connected to the liquid sample receiving interface and including at least one test portion, the test portion comprising at least one respective reacting material configured for reacting in a predetermined manner to at least one specific analyte. The testing device comprises an optical sensor, arranged and configured for detecting light reflected from the at least one test portion and for converting the detected light into an electrical signal representing an intensity and/or a color of the detected light. The testing device further comprises a conversion unit for converting the electrical signal into digital data representing the intensity and/or the color of the detected light, and a transmitter unit for wirelessly transmitting digital data.

A flexible heating apparatus can heat a heated body. The flexible heating apparatus includes a flexible carrier, a heating unit and a control module. The heating unit is at least one layer arranged inside the flexible carrier. The control module is arranged inside the flexible carrier and is electrically connected to the heating unit. Moreover, the control module is connected to an external electric apparatus, and is controlled by the external electric apparatus to control the heating unit to proceed a heating control to the heated body.

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 composition for urine glucose detection includes a fixing agent, an indicator and glucose oxidase, wherein the fixing agent includes one or more selected from the group consisting of a soap base, gelatin, and natural fatty acids.

A container carrier for carrying a sample container along a track is presented. The container carrier comprises a holding portion for receiving and holding a sample container and a base portion. A radio frequency identification (RFID) tag containing identifying information is provided with an antenna for wireless communication of the RFID tag with a reader device of the diagnostics system to read the identifying information. The RFID tag is on the holding portion. An arrangement for a diagnostics system is provided comprising container carriers and a track with a transport mechanism for moving the container carriers along a transportation lane. The transport mechanism defines a transport plane along which the container carriers move. A reader device reads the identifying information from the RFID tags. The reader device comprising a reader antenna above the transport plane to generate and emit a reader field for wireless communication with the RFID tag's antenna.

A molecular diagnostics apparatus is provided. The molecular diagnostics apparatus is adapted to perform DNA chain replication to one sample. The molecular diagnostics apparatus includes a bracket, a central control module, a motor, a magnetic unit, a rotational carrier, a detection module and at least one power supply coil. The central control module is disposed on the bracket. The motor is disposed on the bracket, wherein the central control module drives the motor. The magnetic unit is disposed on the bracket, wherein the magnetic unit provides a magnetic field. The motor is adapted to rotate the rotational carrier. The rotational carrier is rotated relative to the bracket. The sample is disposed on the rotational carrier. The detection module is disposed on the rotational carrier. The power supply coil is coupled to the detection module, and disposed on the rotational carrier. The molecular diagnostics apparatus of the embodiment has a simpler structure and better reliability.