Abstract: This invention relates to reagents and methods for increasing specificity and efficiency of genome editing by CRISPR associated (Cas) protein systems, more particularly by Cas:guide RNA complexes, by blocking off-target nucleic acids from cleavage by Cas:guide RNA complexes.

Abstract: The present invention relates to guide RNAs comprising adaptor segments having one or more modifications, and their use in homologous recombination by CRISPR:Cas systems. The modified adaptor segments are resistant to degradation by RNaseH. The present invention also relates to a dual guide RNA strategy in which a first guide RNA directs a Cas enzyme to make a double-strand break at a first target sequence, and a second guide RNA comprises an adaptor segment attached to a donor polynucleotide, and binds a second target sequence that is offset from the first target sequence.

Abstract: The invention relates generally to methods and apparatus that measure one or more properties of an individual cell type in a non-contact co-culture. More specifically, the invention relates to a novel multiwell plate that allows separate but simultaneous metabolic measurements of cell populations in non-contact co culture.

Abstract: This invention relates to reagents and methods for increasing specificity and efficiency of genome editing by CRISPR associated (Cas) protein systems, more particularly by Cas:guide RNA complexes, by blocking off-target nucleic acids from cleavage by Cas:guide RNA complexes.

Abstract: The present invention relates to guide RNAs comprising adaptor segments having one or more modifications, and their use in homologous recombination by CRISPR:Cas systems. The modified adaptor segments are resistant to degradation by RNaseH. The present invention also relates to a dual guide RNA strategy in which a first guide RNA directs a Cas enzyme to make a double-strand break at a first target sequence, and a second guide RNA comprises an adaptor segment attached to a donor polynucleotide, and binds a second target sequence that is offset from the first target sequence.

Abstract: A microfluidic disk for concentrating particles includes a plurality of distribution channels and separation channels. A sample fluid is flowed through the distribution channels while the disk is spun. Particles of the sample fluid flow into the separation channels where they accumulate. The particles in the separation channels may be subjected to an analysis.

Abstract: A microfluidic device for separating target components from a source fluid includes one or more source channels connected to one or more collection channels by one or more transfer channels. The target components of the source fluid can be magnetic or bound to magnetic particles using a know binding agent. A source fluid containing magnetically bound target components can be pumped through the source channel of the microfluidic device. A magnetic field gradient can be applied to the source fluid in the source channel causing the magnetically bound target components to migrate through the transfer channel into the collection channel. The collection channel can include a collection fluid that is stagnant until a predefined volume of source fluid is processed or a predefined volume of target components accumulate in the collection channel, at which point collection fluid can be pumped into the collection channel to flush the target components out of the collection channel.

Abstract: A dialysis like therapeutic (DLT) device is provided. The DLT device includes at least one source channel connected at least one collection channels by one or more transfer channels. Fluid contacting surface of the channels can be an anti-fouling surface such as slippery liquid-infused porous surface (SLIPS). Fluids can be flown at high flow rates through the channels. The target components of the source fluid can be magnetic or bound to magnetic particles using an affinity molecule. A source fluid containing magnetically bound target components can be pumped through the source channel of the microfluidic device. A magnetic field gradient can be applied to the source fluid in the source channel causing the magnetically bound target components to migrate through the transfer channel into the collection channel. The collection channel can include a collection fluid to flush the target components out of the collection channel. The target components can be subsequently analyzed for detection and diagnosis.

Abstract: A system and method for removing a target species from a fluid source is provided. The system includes a reciprocating fluid cleansing device, including a processing chamber with a port at a first end for fluid passage and a movable plunger at a second end, wherein the plunger in contact with a fluid includes a motorized mixing element for mixing the fluid with species-targeting magnetic particles. Motion of the plunger in a first direction transfers a first volume of the fluid from the fluid source into the processing chamber. Motion of the plunger in a second direction transfers the first volume of the fluid from the processing chamber to a fluid destination. At least one magnetic element provides a magnetic field gradient within the processing chamber. A connector connects the port of the first processing chamber to the fluid source and the fluid destination.

Abstract: A microfluidic device of a diagnostic and detection system includes an inlet port connected by one or more microchannels to an outlet port and includes a capture and visualization chamber (CVC) connected to at least one microchannel. A fluid to be analyzed can be mixed with magnetic microbeads that have an affinity to become bound to target components, such as pathogens in the fluid. The fluid including the magnetically bound target components can be injected through the microfluidic device. Magnetic field gradient, such as provided by permanent or electro-magnets, can be applied to the fluid and the magnetically bound target components flowing through the microfluidic device to cause the magnetically bound target components to migrate into the (CVC) and become separated from the fluid.

Abstract: A method and apparatus for continuously separating or concentrating particles that includes flowing two fluids in laminar flow through a magnetic field gradient which causes target particles to migrate to a waste fluid stream, and collecting each fluid stream after being flowed through the magnetic field gradient.

Abstract: A microfluidic device for separating target components from a source fluid includes one or more source channels connected to one or more collection channels by one or more transfer channels. The target components of the source fluid can be magnetic or bound to magnetic particles using a know binding agent. A source fluid containing magnetically bound target components can be pumped through the source channel of the microfluidic device. A magnetic field gradient can be applied to the source fluid in the source channel causing the magnetically bound target components to migrate through the transfer channel into the collection channel. The collection channel can include a collection fluid that is stagnant until a predefined volume of source fluid is processed or a predefined volume of target components accumulate in the collection channel, at which point collection fluid can be pumped into the collection channel to flush the target components out of the collection channel.

Abstract: A method and apparatus for continuously separating or concentrating particles that includes flowing two fluids in laminar flow through a magnetic field gradient which causes target particles to migrate to a waste fluid stream, and collecting each fluid stream after being flowed through the magnetic field gradient.