Optical systems and apparatuses configured for enabling substantially simultaneous observation of a plurality of points in an array from a common reference point. Without the optical systems and apparatuses disclosed herein, less than all of the plurality of points can be observed substantially simultaneously from the common reference point.

Techniques, systems, and devices are disclosed for implementing a portable lab system for PCR testing. The portable lab system comprises a thermal cycling device including a first well and a second well to receive samples to be thermally cycled, a thermoelectric cooling (TEC) element coupled to the first well and the second well, and a controller to control operation of the TEC element. The portable lab system further includes an electronic interface including a power interface to supply power to the TEC element and the controller of the thermal cycling device to allow the TEC element to transfer energy from the first well to the second well when current flows through the TEC element in a first direction, and from the second well to the first well when current flows through the TEC element in a second direction, and a data interface to collect data from the controller.

A flow cytometry or cell sorting system includes a fluidics system and a flow cell. Under pressure, the fluidics system causes sheath and sample biological fluids to flow. The fluidics system can include a gas bubble to remove and eliminate gas bubbles in the sheath fluid; The flow cell communicates with the fluidics system to receive the sheath fluid, wherein a sample biological fluid flows with cells or particles through the flow cell to be surrounded by the sheath fluid; a deflection chamber under the flow cell to receive the drops of sample biological fluid and sheath fluid out of the flow cell, the deflection chamber to selectively deflect one or more of the drops along one or more deflection paths; and a droplet deposition unit (DDU) system in communication with the deflection chamber to receive selectively deflected drops in the stream of the sample biological fluid with the one or more biological cells or particles into one or more containers.

A flow cytometer or cell sorter system includes a fluidics system and a flow cell. The fluidics system is under pressure to cause a sheath fluid and a sample fluid to flow, the fluidics system including a gas bubble remover eliminating gas bubbles in the sheath fluid; a flow cell coupled in communication with the fluidics system to receive the sheath fluid, wherein a sample fluid flows with cells or particles through the flow cell to be surrounded by the sheath fluid. The flow cell includes a drop drive assembly, a flow cell body, and a cuvette coupled together. The drop drive assembly includes a sample injection tube (SIT) in communication with the fluidics system to receive sample fluid. The flow cell body receives the sample fluid from the sample injection tube and sheath fluid. The flow cell body has a charging port to charge the droplets, the flow cell body having a funnel portion to form a fluid stream of the sample fluid surrounded by the sheath fluid out of an opening; and a cuvette coupled to a base of the flow cell body, the cuvette having a channel to receive the fluid stream of the sample fluid surrounded by the sheath fluid out of the opening, the cuvette being transparent to light and allowing the sample fluid to undergo interrogation in the channel by a plurality of different lasers to determine a plurality of different types of cells or particles therein.

A flow cell body for a flow cytometer or a cell sorter is provided. The flow cell body comprises the following: a three-dimensional opaque (e.g., black) polymer body having top, bottom, left, right, front, and back sides. The opaque polymer body includes the following: a top side opening into a chamber to receive a drop drive assemb

The technology described herein generally relates to microfluidic cartridges configured to amplify and detect polynucleotides extracted from multiple biological samples in parallel. The technology includes a microfluidic substrate, comprising: a plurality of sample lanes, wherein each of the plurality of sample lanes comprises a microfluidic network having, in fluid communication with one another: an inlet; a first valve and a second valve; a first channel leading from the inlet, via the first valve, to a reaction chamber; and a second channel leading from the reaction chamber, via the second valve, to a vent.

A flow control and processing cartridge used in a nucleic acid analysis apparatus includes a cartridge body and a reaction chip. The cartridge body includes plural chambers for storing at least one sample and plural biochemical reagents and buffers, and plural channels connected with the plural chambers. The reaction chip is in conjunction with the cartridge body and includes plural detection wells, at least one main fluid channel connected with the detection wells and adapted to dispense the sample into the detection wells, and at least one gas releasing channel connected with the detection wells and adapted to release gas from the detection wells.

A chemical synthesis platform based on a particularly simple chip is described herein, where reactions take place atop a hydrophobic substrate patterned with a circular hydrophilic liquid trap. The overall supporting hardware (heater, rotating carousel of reagent dispensers, etc.) can be packaged into a very compact format (about the size of a coffee cup). We demonstrate the consistent synthesis of [.sup.18F]fallypride with high yield, and show that protocols optimized using a high-throughput optimization platform we have developed can be readily translated to this device with no changes or reoptimization.

A compact sorting flow cytometer system is disclosed. The system includes a fluidics system having a flow cell and a deflection chamber in communication with the flow cell to receive drops in a stream of a sample biological fluid with one or more biological cells or particles and selectively deflect the drops in the stream of the sample biological fluid with the one or more biological cells or particles; and a droplet deposition unit (DDU) system in communication with the deflection chamber to receive the selectively deflected drops in the stream of the sample biological fluid with the one or more biological cells or particles into one or more containers. The DDU system includes a case or a housing with an open face surround by edges of the case, the case forming a portion of a containment chamber, the case having a top side opening aligned with the deflection chamber to receive the selectively deflected drops in the stream of the sample biological fluid into one or more containers in the containment chamber, a seal mounted around edges of the case, one or more hinges coupled to a bottom portion of the case, and a door coupled to the one or more hinges to pivot the door about the one or more hinges, the door when closed to press against the seal and close off the containment chamber from an external environment.

A method for evacuation of air in a containment chamber of a flow cytometer is disclosed. The method includes turning off a return fan in a first tunnel between an air conditioning chamber and a containment chamber; turning on an evacuation fan in a second tunnel between the air conditioning chamber and the containment chamber, the evacuation fan pulling air out of the containment chamber into the air conditioning chamber, opening a valve in an evacuation vent, the evacuation fan pushing air out of the air conditioning chamber through the evacuation vent into the environment; and continuously running the evacuation fan for a predetermined period of time to evacuate air out of the containment chamber.

A generic point of care based portable device and method thereof as a platform technology for detecting pathogenic infection via nucleic acid based testing achieving sample-to-result integration, comprising the following interconnected stand-alone modules: a thermal unit for executing piece-wise isothermal reactions in a pre-programmable concomitant fashion without necessitating in-between operative intervention; a colorimetric detection unit seamlessly interfaced with smartphone-app based analytics for detecting the target analyte. The said platform technology is thus capable of detecting targeted pathogen-associated RNA by coupling additional complementary DNA probe hybridization combined with isothermal reaction purposed for reverse transcription of RNA followed by amplification of the resulting c-DNA as well as subsequent specific binding of the same in a single user-step in a concomitant fashion and its smartphone-enabled interpretation, in a generic modular format that renders operative suitability outside controlled laboratory environment in a user-friendly manner, with predictive accuracy favorably comparable with gold standard RT-PCR tests.

A hand-held molecular diagnostic test device includes a housing, an amplification (or PCR) module, and a detection module. The amplification module is configured to receive an input sample, and defines a reaction volume. The amplification module includes a heater such that the amplification module can perform a polymerase chain reaction (PCR) on the input sample. The detection module is configured to receive an output from the amplification module and a reagent formulated to produce a signal that indicates a presence of a target amplicon within the input sample. The amplification module and the detection module are integrated within the housing.

A method to extract, amplify and separate nucleic acid in a microfluidic device having a plurality of chambers and channels can include a) introducing cells having nucleic acid to a first chamber of the microfluidic device and subjecting the cells in the first chamber to conditions that lyse the cells. The method can further include b) subjecting the first chamber to centrifugal force, thereby allowing the lysate or a portion thereof having nucleic acid to be distributed to a second chamber through a first channel in the microfluidic device. The method can also include c) combining the lysate or the portion thereof and reagents for amplification of the nucleic acid, thereby providing a second mixture. The method can also include d) subjecting the second chamber to centrifugal force, thereby allowing gas to be expelled from the second mixture.