A discoid sample holder (1), on which a device (2) for carrying out at least one processing step is formed. According to the invention, a slot (3), into which a sampling instrument (4) can be introduced, and a mechanism (5) for releasing a sample from the sampling instrument (4) arranged in the receptacle (3), is formed in the sample holder.

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.

A container comprising: a first panel; a second panel opposing the first panel; a first side; a second side opposing the first side; a third side; a fourth side opposing the third side; wherein each of the sides joins the first panel and the second panel; a chamber defined by the four sides, the first panel, and the second panel, wherein the chamber is configured to receive a biological specimen; a port defined in the first side; a plug inserted into the port; an opening defined in the second side; and a closure element coupled to the opening, wherein the chamber is leak proof.

A sample analyzing method and a sample preparing method are provided. The sample analyzing method includes a sample preparing step, a placing step, and an analyzing step. The sample preparing step includes an obtaining step implemented by obtaining an identification information; and a marking and placing step implemented by placing a sample carrying component having a sample disposed thereon into a marking equipment, allowing the marking equipment to utilize the identification information to form an identification structure on the sample carrying component, and placing the sample carrying component into one of the accommodating slots according to the identification information. The placing step is implemented by taking out the sample carrying component from one of the accommodating slots and placing the sample carrying component into an electron microscope equipment. The analyzing step is implemented by utilizing the electron microscope equipment to photograph the sample to generate an analyzation image.

A device for storage and transport of biological samples. Multiple trays are assembled into a stack with sample tubes constrained between adjacent trays. The surface of each tray has radial grooves sized to hold the sample tubes. Each tray is secured to an adjacent tray with a bolt or snap-fit connector.

In one aspect of the invention, the fluidic device includes a fluidic chip includes a body having a first surface and an opposite, second surface, one or more channels formed in the body in fluidic communications with input ports and output ports for transferring one or more fluids between the input ports and the output ports, and a fluidic chip registration means formed on the first surface for aligning the fluidic chip with a support structure; and an actuator configured to engage with the one or more channels at the second surface of the body for selectively and individually transferring the one or more fluids through the one or more channels from at least one of the input ports to at least one of the output ports at desired flowrates.

The invention discloses a reaction incubation device, an immunity analyzer and a reaction incubation method. The reaction incubation device comprises a reaction unit (10), which is used for bearing and incubating a reaction container; and a transfer unit (20), which is used for removing the reaction container in and out of the reaction unit (10). The reaction unit (10) comprises a rotating device (11). The rotating device (11) is provided with an incubation position which increases a predetermined angle θ at an interval of fixed time T along with the rotating device (11). The transfer unit (20) removes the reaction container out of the incubation position according to variable incubation time ti. With the device, flexible and variable incubation time can be achieved, and the problem of complicated control, low reliability and that high-speed automation is not easy to achieve in the prior art can be solved.

Provided is a biological specimen holder for positioning multiple specimens for imaging by a light-sheet microscope. The specimen holder allows developing plant embryos, small intact animals, or organs to be imaged in the light-sheet microscope in a single setting. The specimen holders significantly improve the imaging conditions with respect to the standard glass capillary system. Also provided is a semi-automatic image processing pipeline that quantifies cell divisions of plants imaged with both the glass capillary and the novel chambers. Plants imaged using the specimen holder undergo cell divisions for a period at least 16 times longer than those imaged with a glass capillary system and allow increased sample throughput and the option of incorporating light emitting diode (LED) lights to generate a light-controlled environment are also advantages.

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.

The equipment item for automatically managing a plurality of biological samples placed in a respective sample jar includes a storage container for sample jars having a plurality of housings, an apparatus with a reader of encoded identification data affixed on the sample jars placed in the container, a device for determining data representative of the position of each sample jar within the container, and a device for rotating the container, and a computer processor connected to the apparatus. The container includes, in the immediate vicinity of each housing, a shape appearing recessed or raised, while the device for determining data representative of the position of each sample jar is defined by a detector for the shape.