The subject invention pertains to a microfluidic apparatus and methods for screening and isolating a target cell from a population of cells. The apparatus comprises a first microfluidic layer comprising microfluidic channels; a second microfluidic layer comprising microfluidic channels; and a microfluidic cell analysis layer comprising a top hanging blocking structure located directly below each location where the first layer microfluidic channels overlap with the second layer microfluidic channels and a cell trap juxtaposed to each of the top hanging blocking structures. The top hanging blocking structures can close or open the juxtaposed cell trap when either or both the first or second layer microfluidic channels located directly above the top hanging blocking structure are sufficiently pressurized and/or sufficiently depressurized. The methods for screening and isolating a target cell from a population of cells comprise screening the population of cells using the apparatus and isolating the target cell interest therefrom.

Microfluidic devices for modeling three-dimensional tissue structures and methods for making and using the same are described herein.

The present invention generally relates to droplet libraries and to systems and methods for the formation of libraries of droplets. The present invention also relates to methods utilizing these droplet libraries in various biological, chemical, or diagnostic assays.

Systems and methods are disclosed for enhancing the consistency of performance of assays, such as multiplexed assays, by printing features in a particular pattern, such that the outer edge of the pattern has a shape that is substantially similar to the shape of the test well. For example, the pattern is a ring pattern, such that the outer edge of the ring pattern is circular or oval along the bottom of multiplexed wells. The assay substrates prepared according to the methods described result in more accurate, precise, and sensitive chemical and/or biological analyses.

A biochip substrate which is free from cross-contamination due to spot spreading or contact with spots adjacent to each other, and a biochip using the same. A biochip substrate on which multiple valleys for immobilizing biological substances are formed so as to prevent cross-contamination due to spot spreading or contact with spots adjacent to each other, and a biochip using the same are provided. Moreover, it is found out that a desired binding in a target molecule contained in a test sample occurs at a detectable level in a solution system even in the case where a valley have such a small capacity as 1 nL to 10 nL.

Methods and apparatus for detecting, quantifying, enriching, and/or separating bacterial species in fluid sample are provided. The fluid sample is provided as input to a microfluidic passage of a microfluidic device, wherein the microfluidic device comprises at least one electrode disposed adjacent to the microfluidic passage. The at least one electrode is activated to capture bacteria in the sample using dielectrophoresis, wherein the capture efficiency of bacteria is at least 99%.

The invention generally relates to methods for quantifying an amount of enzyme molecules. Systems and methods of the invention are provided for measuring an amount of target by forming a plurality of fluid partitions, a subset of which include the target, performing an enzyme-catalyzed reaction in the subset, and detecting the number of partitions in the subset. The amount of target can be determined based on the detected number.

Supporting apparatus having a columnar first member and a cylindrical second member having an inner surface allowed to face with of an outer surface of the first member, one portion of the first member is inserted in a cylinder defined by the inner surface, a state of the members is allowed to change from a first state to a second state, the first state includes a state in which a predetermined space is ensured, the predetermined space is surrounded by one portion of the inner surface of the second member and an edge surface at one side of the first member that is different from the outer surface, the second state includes a state in which the second member has moved toward a side that is opposite to the one side relative to the first member from a base position of the members in the first state.

The present invention relates to a microfluidic device (2) comprising a support part (21) and a cover part (22) defining together a microchannel (5), said microchannel (5) having a surface, said surface comprising:—a first area (9) which is grafted with a first ligand, and—at least a second area (10) which is distinct from the first area (9) and which is grafted with a second ligand which is different from the first ligand, wherein each ligand is capable of binding to a target, the targets being different from each other. The present invention further relates to a microfluidic detection system comprising the said microfiuidic device, a reservoir adapted for containing a sample to be analysed and a detection device for detecting and quantifying the targets. The present invention relates also to a method for manufacturing such a microfluidic device, as well as a method for analysing a sample containing targets using the said microfluidic device or microfluidic detection system.

The invention generally relates to methods for quantifying an amount of enzyme molecules. Systems and methods of the invention are provided for measuring an amount of target by forming a plurality of fluid partitions, a subset of which include the target, performing an enzyme-catalyzed reaction in the subset, and detecting the number of partitions in the subset. The amount of target can be determined based on the detected number.