Diagnostic systems for sensing biological molecules are disclosed. The diagnostic systems include a fluid control delivery and control system that can be coupled to a diagnostic cartridge that includes a microfluidic device and integrated sensing electronics. The diagnostic systems can be used to sequence biological molecules.

Provided herein, among other aspects, are methods and apparatuses for analyzing particles in a sample. In some aspects, the particles can be analytes, cells, nucleic acids, or proteins and contacted with a tag, partitioned into aliquots, detected by a ranking device, and isolated. The methods and apparatuses provided herein may include a microfluidic chip. In some aspects, the methods and apparatuses may be used to quantify rare particles in a sample, such as cancer cells and other rare cells for disease diagnosis, prognosis, or treatment.

This disclosure describes single-use test cartridges, cell analyzer apparatus, and methods for automatically performing microscopic cell analysis tasks, such as counting blood cells in biological samples. A small unmeasured quantity of a biological sample such as whole blood is placed in the disposable test cartridge which is then inserted into the cell analyzer. The analyzer isolates a precise volume of the biological sample, mixes it with self-contained reagents and transfers the entire volume to an imaging chamber. The geometry of the imaging chamber is chosen to maintain the uniformity of the mixture, and to prevent cells from crowding or clumping, when it is transferred into the imaging chamber. Images of essentially all of the cellular components within the imaging chamber are analyzed to obtain counts per unit volume. The devices, apparatus and methods described may be used to analyze a small quantity of whole blood to obtain counts per unit volume of red blood cells, white blood cells, including sub-groups of white cells, platelets and measurements related to these bodies.

An automated biologic sample extracting system from a set of biological samples with a small footprint with minimal movement of the set of consumables, thereby reducing potential contamination during the extraction process. The extracting system comprising a set of reaction tubes, a storage unit to store a set of consumables; a sample preparation unit; a sample extraction unit; a waste unit; a plurality of robots to move tubes, samples, and boxes, and a programmable control system programmed to process samples in a serial pattern in which a series of samples follow one another to be processed in a time sequence and in succession so that it keeps a fixed processing turnaround time of each sample no matter when a sample would start the process.

The invention relates to a device for synthesising oligonucleotides, comprising: a reagent container receptacle (1) for holding a reagent container support (17) comprising multiple reagent containers (18); an exchangeable microfluid chip (10) comprising a synthesis chamber, fluid connectors and microfluid valves; a control device (5); fluid connecting means (2); wherein the device can be loaded with the microfluid chip (10) and the reagent container support (17) when in a loading position; a chip receptacle (3). To allow cost-effective and prompt synthesis even of small amounts of oligonucleotides, the invention provides for an actuator device (6) to be provided, with which the reagent container receptacle (1), the microfluid chip (10) and the fluid connecting means (2) can be brought from the loading position to an operating position, in which operating position the reagent container receptacle (1), the chip receptacle (3) and the fluid connecting means (2) are positioned relative to each other such that reagents can be conveyed out of the reagent containers (18) towards the synthesis chamber (14) depending on the valve position of the microfluid valves.

A biological sample reaction vessel comprising a reagent storage portion and a push rod movable relative to the reagent storage portion is provided. The reagent storage portion comprises at least one reagent containing cavity, and the reagent containing cavity is sealed by a sealing element; and the push rod is connected to the sealing element, and the push rod is used for cooperation with an external device to separate the sealing element from the reagent storage portion. In reaction, the biological sample reaction vessel cooperates with a test cassette. By inserting the biological sample reaction vessel into the external device, the reagent in the reagent storage portion can be released rapidly.

Provided is a centrifugal separation container for separating a material from tissue and body fluids by using a centrifugal force, including: a first container; a second container; a first piston positioned in the inside of the first container and configured to be movable up and down in the inside of the first container; an elastic body positioned below the first piston in the inside of the first container and configured to elastically bias the first piston upward; a first connecting duct having one end connected to the first container and the other end connected to the second container; and a first control valve operating by a centrifugal force and configured to open and close the first connecting duct.

A system and method for automated single cell capture and processing is described, where the system includes a deck supporting and positioning a set of sample processing elements; a gantry for actuating tools for interactions with the set of sample processing elements supported by the deck; and a base supporting various processing subsystems and a control subsystems in communication with the processing subsystems. The system can automatically execute workflows associated with single cell processing, including mRNA capture, cDNA synthesis, protein-associated assays, and library preparation, for next generation sequencing.

A system for buoyant separation includes a separation container. Additionally or alternatively, the system can include an automated instrument, one or more processing components, and/or any other components. A method for buoyant separation can include any or all of: manipulating the separation container; adding materials to the separation container; removing materials form the separation container; otherwise processing the separation container; and/or any other processes.

A transfer container for a fluid includes a tube, the tube including a conical portion at one end, the tube defining an interior space and one or more fluid passages configured to allow flow of fluid into or out of the interior space of the tube. The transfer container also includes a connector configured to seal the end of the conical portion when the connector is joined only to the conical portion and a pressure control mechanism configured to increase or decrease a pressure in the interior space of the tube. The transfer container can be used in a method including connecting fluid lines to the fluid passages, adding a fluid including cryoprotectant and cells, centrifuging the transfer container, and then connecting the transfer container to a second fluid transfer container containing another fluid. This allows the sterile transfer of fluids and separation of cells from cryoprotectant.