Methods of generating organoids on multi-well plates are provided by depositing a polymeric solution comprising cells under conditions which result in a homogenous population of organoids, which can be used for high throughput analysis for drug screening and for determining treatment regimens of a drug.

The present invention provides a device for producing a large number of uniform spheroids by an easy method. The spheroid-producing device (1) at least includes a first surface (11), a second surface (12), and a plurality of wall surfaces (13). The second surface (12) faces the first surface (11). The respective wall surfaces (13) constitute a plurality of holes penetrating through the first surface and the second surface. In addition, an equivalent diameter of inscribed circles of openings in the first surface (11) is greater than an equivalent diameter of inscribed circles of openings in the second surface (12).

Devices, systems, and their methods of use, for generating and collecting droplets are provided. The device includes a collection region comprising a side wall canted at an angle. The invention further provides multiplex devices that increase droplet formation.

A method of handling an adherent cell in a microdroplet assaying system by conjugating an adherent cell to a microbead is provided. The method 50 comprises the steps of: loading a first plurality of microdroplets into a microfluidic space, wherein each of the first microdroplet 5 contains a microbead 52 and a first fluid; loading a second plurality of microdroplets into the microfluidic space, wherein each of the second microdroplet contains an adherent cell and a second fluid 54; merging the first plurality of microdroplets and the second plurality of microdroplets to form a plurality of merged microdroplets 56, each merged microdroplets containing the first and second fluids, at least one microbead and at least one adherent cell; and10 agitating each of the merged microdroplets 58 to cause the first and second fluids in each of the merged microdroplets to move such that at least one adherent cell adhere to the at least one microbead. [FIG. 1] 15

A micro-droplet plate including at least one fixed element which is a rigid flat support which has an upper face and a lower face, having, on said upper face, wells connected together by microchannels, said wells being delimited by a hydrophobic rim and crossed by a hole, where said wells and said microchannels define at least one microfluidic circuit; and moving elements, received in said wells through said holes, which are cylinders having an upper base and a lower base. The moving elements move, even independently of each other, along their vertical axis, and the upper base of said moving elements includes a hydrophilic surface with relief items.

A method of maintaining at least one component in an aqueous microdroplet dispersed in conditioned oil to form an emulsion is provided. The method comprising the steps of supplementing an unconditioned oil with at least one component to form a conditioned oil; and providing the aqueous microdroplet comprising at least one component, wherein the microdroplet is dispersed in the conditioned oil to form an emulsion, such that the partitioning of the component from the microdroplet into the conditioned oil is reduced, wherein the maintenance of the component within the microdroplet is based on the partition coefficient value of the component being equal to or more than zero; or equilibrating the unconditioned oil with a media or a buffer containing at least one component to form the conditioned oil, such that the partitioning of the component from the aqueous microdroplet into the conditioned oil is reduced, wherein the maintenance of the component within the microdroplet is based on the concentration of the component in the conditioned oil being equivalent to or in excess of the product of the partition coefficient and the concentration of the component in the microdroplet. A method of method of making conditioned oil is also provided.

A three-dimensional culture method includes: providing a cell suspension, the cell suspension containing a cell (12C) and a culture medium (14M); providing a solid surface (10S), the solid surface having a plurality of raised portions (10Sp) whose height is not less than 10 nm and not more than 1 mm; attaching a liquid drop (16D) of the cell suspension to the solid surface (10S); and culturing the cell (12C) in the liquid drop (16D) under such conditions that a direction of gravity exerted on the liquid drop (16D) is toward the solid surface (10S).

A spheroid generator includes a body part; a main injection part which is formed in the body part so that a cancer cell solution is injected and configured to stop the flow of the cancer cell solution when the cancer cell solution comes into contact with a culture medium; and a sub-injection part which is formed in the body part so that an anticancer substance or a stromal cell solution is injected, and communicates with the main injection part so that the injected anticancer substance or stromal cell solution flows to the main injection part.

Devices, systems, and associated methods are provided for manipulating and/or determining one or more characteristics of cells contained within a biological sample. In particular a device and methods of use thereof are provided, the device comprising a sorting component configured to separate cell-containing microdroplets from empty ones into a population of cell-containing first microdroplets; a microdroplet manipulation component configured to manipulate the first microdroplets using real or virtual electrowetting electrodes, and an optical detection system configured to detect an optical signal from the microdroplets via the one or more detection windows.

A method for monitoring a reaction and a reaction system are provided. The reaction system includes at least one vessel for the reaction medium, which is in fluid communication with an injection tube; at least one vessel for a carrier fluid that is immiscible with the reaction medium, which is in fluid communication with a reaction tube; the injection tube being mounted so as to lead into the reaction tube such that individual drops of the reaction medium can be injected into the reaction tube and into the immiscible carrier fluid, so as to form a train of reaction chambers; at least one detector for monitoring a reaction; a means for classifying the reaction chambers; and at least one means for recirculating reaction chambers in front of at least one detector for monitoring a reaction.