The present disclosure provides a digital PCR system. The system includes a droplet formation assembly and a droplet orifice assembly. The droplet formation assembly includes a heat conducting plate and a cover plate, at least one inverted U-shaped step is placed on a side surface of the cover plate, the heat conducting plate, the cover plate and the inverted U-shaped step together form a droplet formation chamber having an opening at a bottom. The droplet orifice assembly is connected below the droplet formation assembly, and includes a plurality of droplet orifices, the droplet orifice is connected with the droplet formation chamber, and a vaporization component is placed in the droplet orifice, the vaporization component vaporizes a digital PCR solution in the droplet orifice and rapidly pushes the digital PCR solution into a droplet forming oil in the droplet formation chamber, to form a digital PCR droplet.

Systems for performing cellular analysis and related devices for conditioning environments adjacent chips in such systems. A device for conditioning an environment adjacent a chip in a system for performing cellular analysis, the device includes a cover for being disposed adjacent the chip and comprising a planar body having a top surface, a bottom surface, and an outer edge surface. The cover includes a central opening extending between the top surface and the bottom surface and bounded by an inner edge surface of the cover. The cover also includes a fluid inlet extending into the body from the outer edge surface between the top surface and the bottom surface the fluid inlet arranged to accept a gas to be delivered to the central opening. The cover also includes a plurality of fluid outlets defined in the inner edge surface and in fluid communication with the fluid inlet. The plurality of fluid outlets are arranged to receive the gas from the fluid inlet and exhaust the gas into the central opening.

A fluorescent in-situ hybridization imaging system, including a flow cell to contain a sample to be exposed to fluorescent probes in a reagent; a plurality of reagent reservoirs, each reagent reservoir including a container to hold a liquid reagent; a valve system to control flow from one of a plurality of reagent reservoirs to the flow cell; a pressure source coupled to each of the plurality of reagent reservoirs to apply a positive pressure to liquid reagent in the container and urge the liquid reagent to flow toward the flow cell; and a fluorescence microscope including a variable frequency excitation light source and a camera positioned to receive fluorescently emitted light from the sample.

In this invention, chromatography is integrated on a centrifugal platform to enable low-cost automated purification. Differing from the traditional chromatography method, purification and separation of a centrifugal compound collecting platform disclosed in the present invention mainly uses a centrifugal force to drive the fluid to flow outward in the radial direction when the motor rotates. The compounds to be separated react with the column packing during the flow, and the compounds with different polarities in the sample are gradually separated. The flow of the fluid can be governed by the motor and the geometry of the fluidic design such that compounds with different characteristics can be separated and collected in different collecting chambers.

A closed fluid receiving and sampling container that enables transfer of valuable reaction liquid to a receptacle without risking loss of sterility. The sampling container has a dip tube subassembly with a shorter inlet tube bent towards the wall of the receptacle to prevent or reduce foaming, and a longer outlet tube used to drain the waste liquid once the magnetic beads are trapped by the magnet. The dip tube subassembly is injection molded in one piece and provides a sealed cap also with a vent tube therethrough to enable filling and draining the receptacle without removing the cap, thus keeping the process aseptic. The sampling container is especially useful in the context of magnetic bead separation processes.

Disclosed herein are solvent reservoir systems for steady flow delivery and simultaneous monitoring of solvent level and solvent density within the solvent reservoir systems and methods for monitoring the solvent reservoir systems and providing feedback to a user or adjusting the systems in response to the monitored characteristics.

A biological fluid collection device that receives a sample and provides flow-through blood stabilization technology and a precise sample dispensing function for point-of-care and near patient testing applications is disclosed. A biological fluid collection device of the present disclosure is able to effectuate distributed mixing of a sample stabilizer within a blood sample and dispense the stabilized sample in a controlled manner. In this manner, a biological fluid collection device of the present disclosure enables blood micro-sample management, e.g., passive mixing with a sample stabilizer and controlled dispensing, for point-of-care and near patient testing applications.

Described herein are purge swab apparatuses, purge swabs kits, and methods for collecting a sample using a purge swab. In various embodiments, a purge swab includes an elongated body having a proximal end, a distal end, and a length therebetween. The purge swab further includes a swab head having a proximal end and a distal end wherein the proximal end of the swab head is attached to the distal end of the elongated body and the swab head includes a plurality of openings. The purge swab optionally includes a lumen extending from the proximal or distal end of the elongated body into at least a portion of the swab head, and the lumen is in fluidic communication with the plurality of openings.

Geranyl pyrophosphate (GPP) is a key intermediate molecule in the bioproduction of thousands of natural products. Currently, natural products are either cultivated from plants, synthesized via complex chemical synthesis strategies, or through cell-based factories also known as biofoundries. However, in order to replicate the process in a cell free environment, numerous enzymes and cofactors must be utilized making this approach costly and unviable. In order to make this process viable, a new approach was needed that uses fewer enzymes and cofactors. As described herein, the present invention demonstrates that it is possible to create GPP from glycerol through a short and concise biosynthetic pathway outside of the cell.

The present disclosure provides a biological fluid collection device, such as a blood collection device, that is adapted to receive a multi-component blood sample having a cellular portion and a plasma portion and quickly, efficiently and cost-effectively separate the plasma portion from the sample. A pressure gradient can be applied across a separation member to facilitate movement of the plasma portion ahead of the cellular portion. The present disclosure allows for both passive and active plasma separation and dispensing.