Abstract: Provided herein, are droplet mixture compositions and systems and methods for forming mixtures of droplets. The system may comprise two or more droplet generation units. Each unit may include at least one first input well, a second input well, and an output well connected to the first and second input wells by channels that form a droplet generator. The combined droplet populations can be mixed, heated, and collected for multiple uses, such as for use as calibration standards for instrument testing and analysis.

Abstract: Method of detection for droplet-based assays. In an exemplary method, an open end of a channel network may be placed into an emulsion. Droplets of the emulsion may be driven along a flow path from the open end, through a confluence region where a dilution fluid is introduced into the flow path from at least one dilution inlet channel to increase an average distance between droplets, and through an examination region disposed downstream of the confluence region. Light may be detected from the examination region as droplets pass through. The channel network may include a droplet inlet channel that meets the at least one dilution inlet channel at the confluence region. The droplet inlet channel may form a tapered region that is sized such that droplets leave the tapered region in single file.

Abstract: Method of transporting droplets for detection. An emulsion disposed in a container and including droplets may be provided. Contact may be created between a tip and the emulsion. The tip may be connected to an examination region and may include an outer tube and an inner tube. The outer tube may form a first open end and surround an enclosed portion of the inner tube. The inner tube may extend out of the first open end to create a projecting portion forming a second open end below the first open end. Droplets of the emulsion may be loaded into the inner tube via the second open end. Loaded droplets may be moved from the inner tube to the examination region. Fluid may be dispensed onto the projecting portion of the inner tube from the first open end formed by the outer tube.

Abstract: This disclosure provides systems, devices, and methods for sample preparation and/or analysis comprising a droplet generator having a first channel in fluid communication with a carrier fluid reservoir and a second channel in fluid communication with a sample reservoir. The first channel and second channel may meet at an intersection that receives a sample from the sample reservoir and a carrier fluid from the carrier fluid reservoir and generates one or more droplets that flow along a droplet channel to a droplet reservoir. An energy application member in thermal communication with the intersection, at least a portion of the droplet channel, the sample reservoir and/or the carrier fluid reservoir may provide energy to an individual droplet of the one or more droplets, such as at the intersection and/or as the droplet moves along the droplet channel to the droplet reservoir.

Abstract: System, including methods and apparatus, for detection of spaced droplets.

Abstract: System, including methods, apparatus, and kits, for forming emulsions. The system may include an instrument and a microfluidic chip received by the instrument. The instrument may apply pressure to prospective emulsion phases held by the chip, to drive formation and collection of emulsions in the chip. In some embodiments, the instrument may stop applying pressure to the chip when a change in pressure meeting a predefined condition is detected by the instrument. The change may indicate that an endpoint of droplet generation has been reached.

Abstract: A droplet detection system comprises a first channel in fluid communication with a carrier fluid reservoir and a second channel in fluid communication with a sample reservoir. The first channel and second channel can meet at an intersection. The sample reservoir can include a sample or partition thereof. During use, an emulsion comprising one or more droplets can be generated at the intersection. The emulsion flows from the intersection along a detection channel to a collection reservoir. A detection assembly that is coupled to at least a portion of the detection channel is configured to detect a signal from the one or more droplets. An energy providing member can be in thermal communication with at least one of the carrier fluid reservoir, the sample reservoir, the intersection, the detection channel and the detection assembly. The energy providing member is configured to transfer energy to the emulsion.

Abstract: System, including methods and compositions, for making and using emulsions that include a silicone oil and a silicone surfactant. The emulsions may include aqueous droplets disposed in a continuous phase that includes a silicone oil and a silicone surfactant. The aqueous droplets may contain an analyte, optionally at partial occupancy, and/or a luminescent (e.g., photoluminescent) reporter. An assay of the analyte may be performed with the droplets. In some cases, signals may be detected from the droplets, and a characteristic of the analyte, such as an analyte level or activity, may be determined based on the signals.

Abstract: System, including methods and apparatus, for detection of spaced droplets.

Abstract: The present disclosure provides assays and devices for forming, spacing, and/or detecting droplets. The droplets may be emulsions composed of two or more immiscible fluids. An emulsion can be a double emulsion, such as water-in-oil droplets that are present in a continuous aqueous phase. The double emulsion can be formed when the water-in-oil droplets are contacted with one or more streams of aqueous fluid(s). This disclosure also provides a variety of additives that can be added to the fluids.

Abstract: This disclosure provides systems, devices, and methods for sample preparation and/or analysis comprising a droplet generator having a first channel in fluid communication with a carrier fluid reservoir and a second channel in fluid communication with a sample reservoir. The first channel and second channel may meet at an intersection that receives a sample from the sample reservoir and a carrier fluid from the carrier fluid reservoir and generates one or more droplets that flow along a droplet channel to a droplet reservoir. An energy application member in thermal communication with the intersection, at least a portion of the droplet channel, the sample reservoir and/or the carrier fluid reservoir may provide energy to an individual droplet of the one or more droplets, such as at the intersection and/or as the droplet moves along the droplet channel to the droplet reservoir.

Abstract: System, including methods, apparatus, compositions, and kits, for assays with an emulsion including capsules. A method of performing an assay is provided. In the method, an aqueous phase may be provided. The aqueous phase may include a sample and an effective concentration of one or more skin-forming proteins. An emulsion may be formed. The emulsion may include droplets of the aqueous phase disposed in a nonaqueous continuous phase. The emulsion may be heated to create an interfacial skin between each droplet and the continuous phase, to transform the droplets into capsules. Assay data related to the sample may be collected from the capsules.

Abstract: System, including methods and apparatus, for transporting droplets from a tip to an examination site for detection.

Abstract: Method of analyzing genomic DNA. Genomic DNA including a target may be obtained. The genomic DNA may be fragmented volitionally to produce fragmented DNA. The fragmented DNA may be passed through a droplet generator to generate aqueous droplets containing the fragmented DNA. An assay may be performed on the droplets to determine a level of the target. In some embodiments, the droplets may contain the genomic DNA at a concentration of at least about five nanograms per microliter, the droplets may be generated at a droplet generation frequency of at least about 50 droplets per second, the droplets may have an average volume of less than about 10 nanoliters per droplet, the droplets may generated at a flow rate of greater than about 50 nanoliters per second, or any combination thereof.

Abstract: System, including methods, apparatus, and kits, for forming emulsions. The system may include an instrument and a microfluidic chip received by the instrument. The instrument may apply pressure to prospective emulsion phases held by the chip, to drive formation and collection of emulsions in the chip. In some embodiments, the instrument may stop applying pressure to the chip when a change in pressure meeting a predefined condition is detected by the instrument. The change may indicate that an endpoint of droplet generation has been reached.

Abstract: System, including methods and apparatus, for detection of spaced droplets.

Abstract: System, including methods, apparatus, compositions, and kits, for assays with an emulsion including capsules. A method of performing an assay is provided. In the method, an aqueous phase may be provided. The aqueous phase may include a sample and an effective concentration of one or more skin-forming proteins. An emulsion may be formed. The emulsion may include droplets of the aqueous phase disposed in a nonaqueous continuous phase. The emulsion may be heated to create an interfacial skin between each droplet and the continuous phase, to transform the droplets into capsules. Assay data related to the sample may be collected from the capsules.

Abstract: System, including methods, apparatus, compositions, and kits, for making and using a stabilized emulsion. A method of generating a stabilized emulsion is provided. In the method, an aqueous phase may be provided. The aqueous phase may include an effective concentration of one or more skin-forming proteins. An emulsion may be formed. The emulsion may include droplets of a dispersed phase disposed in a continuous phase, with the aqueous phase being the continuous phase or the dispersed phase. The emulsion may be heated to create an interfacial skin between each droplet and the continuous phase, to transform the droplets into capsules.