Provided herein, inter alia, are solvent and resin formulations comprising reduced fire and environmental risk, methods for producing sensor device for detection of any analyte, e.g., by printing reactive chemicals and dyes onto a substrate using large scale printing machines. Also provided is a method of preparing the reduced risk formulations and sensor device, and methods of using the sensor device. Further provided is a sensor system including an ink and a solid support. The ink includes at least one reactive chemical or dye, a co-solvent, and a resin composition chosen for reduced fire and environmental impact risk. The ink is applied (e.g., printed) on a surface of the solid support. The reactive chemical or dye is configured to undergo a chemical reaction with gunshot residue (e.g., post blast residues associated with historical and modern day black powders used in bullet manufacture) that produces a presumptive colorimetric indication.

An apparatus for preparing a reagent solution includes an enclosure and a container disposed within the enclosure. The container defines an internal cavity having a compressible volume and defines a passage providing fluidic communication between the internal cavity and the exterior of the container. Optionally, a compressible member is disposed within the internal cavity. A reagent is disposed within the internal cavity.

An automatic nucleic acid extraction cartridge and an automatic nucleic acid extraction system including the same are described herein. The cartridge having a housing that includes a sample port, a cell processing chamber, a wash fluid chamber, a filter assembly comprising a filter member, and a diverter valve having a first and a second reversibly sealable output, wherein each of the sample port and the cell processing chamber, the cell processing chamber and the filter assembly, and the wash fluid chamber and the filter assembly are in one-way fluid communication, and the filter assembly is in fluid communication with the diverter valve and (i) a waste conduit when the diverter valve is biased to the first reversibly sealable output and (ii) a pathogen nucleic acid conduit when the diverter valve is biased to the second reversibly sealable output. The present disclosure further describes methods of using the same.

Methods, devices and systems for analyzing precious samples of cells, including single cells are provided. The methods, devices, and systems in various embodiments of the invention are used to assess genomic heterogeneity, which has been recognized as a central feature of many cancers and plays a critical role in disease initiation, progression, and response to treatment. The methods devices and systems are also used to analyze embryonic biopsies for preimplantation genetic diagnosis (PGD). In one embodiment, the devices, systems and methods provided herein allow for the construction of genomic and RNA-seq libraries without a pre-amplification step.

The invention relates to packaged lyophilized agents. In particular, the present invention relates to compact lyophilized agents that are packaged in flexible containers, and systems for their manufacture and use.

An apparatus for preparing a reagent solution includes an enclosure and a container disposed within the enclosure. The container defines an internal cavity having a compressible volume and defines a passage providing fluidic communication between the internal cavity and the exterior of the container. Optionally, a compressible member is disposed within the internal cavity. A reagent is disposed within the internal cavity.

A system comprising a calorimeter for measuring a heat flux of a sample comprising a recipient space for a sample container containing a sample, a heat sink, a first heat transducer whereby the first heat transducer comprises a heat receiving surface in contact with the sample container when the sample container is positioned in the recipient space and a heat absorbing surface in contact with the heat sink. A second heat sink is provided, whereby the second heat sink has a second heat receiving surface in contact with the heat sink and a second heat absorbing surface in contact with the sample container, when the sample container is positioned in the recipient space.

Apparatus and methods for separating blood components are disclosed in which an apparatus for separating blood generally includes a tube defining a channel and configured for receiving a quantity of blood and a float contained within the tube and having a density which is predefined so that the float is maintained at equilibrium between a first layer formed from a first fractional component of the blood and a second layer formed from a second fractional component of the blood. Upon completion of the centrifugation, the first layer may be removed from the tube while the float isolates the second layer from the first layer.

A blood pack donation system configured for use with a lab-on-a-chip device for biomarker collection during whole blood donation including a blood collection container, a biomarker collection container, a first flow path connected to an opening in the blood collection container and to a first outlet opening of a lab-on-a-chip device, a second flow path connected to an opening in the biomarker collection container and to a second outlet opening of the lab-on-a-chip device, and a third flow path connected to a needle and to an inlet opening of the lab-on-a-chip device. The system may be used in a single pass collection procedure. A second version includes a fourth flow path connected to the first flow path and to the third flow path, with a plurality of flow control components that selectively control flow to provide a single pass collection procedure or a multiple pass collection procedure.

A fluidic chip comprising: a sealing layer having an upper surface and a lower surface; and a formed part comprising a generally planar body having a lower surface sealed with the upper surface of the sealing layer, the generally planar body having a number of through holes and a number of wells in fluid communication with the number of through holes, wherein together with the upper surface of the sealing layer, the number of through holes and the number of wells respectively define a number of fluid inlets and a number of fluid chambers in fluid connection with each other in the fluidic chip.