The present invention relates to a microfluidic device (1) for cultivating cells, in particular for generating brain organoids, comprising at least two fluid channels (2) positioned essentially opposite to each other and a main chamber (3) located between the fluid channels (2), wherein the main chamber (3) comprises at least one preferably sealable access opening, and each of the at least two fluid channels (2) is fluidly connected to the main chamber (3) at at least one point of contact (4), wherein a slotted structure (5) is provided at each point of contact (4) separating the main chamber (3) from the respective fluid channel (2), wherein the slotted structure (5) is permeable to a liquid.

An apparatus for patterning biological cells, and a method of patterning and coculturing biological cells using the apparatus. The apparatus includes a fluidic structure having an outlet and a plurality of inlets, the fluidic structure is arranged to facilitate a flow of a plurality of different cells in a cell suspension therethrough, wherein each of the plurality of inlets is arranged to facilitate a loading of the plurality of different cells from a plurality of supplies into the fluidic structure; and a flow controlling device arranged to control the flow of the plurality of different cells through the fluidic structure and/or the loading of the plurality of different cells from the plurality of supplies through the plurality of inlets; wherein the fluidic structure is further arranged to facilitate a simultaneous observation of the plurality of different cells arranged in a predetermined pattern in the fluidic structure.

A lateral-flow assay device includes a substrate having a sample addition zone and a wash addition zone downstream thereof along a fluid flow path through which a sample flows. The fluid flow path is configured to receive a wash fluid in the wash addition zone. A hydrophilic surface is arranged in the wash addition zone. Flow constriction(s) are spaced apart from the fluid flow path and arranged to define, with the hydrophilic surface, a reservoir configured to retain the wash fluid by formation of a meniscus between the hydrophilic surface and the flow constriction(s). The fluid flow path draws the wash fluid from the reservoir by capillary pressure. Apparatus for analyzing a fluidic sample and methods of displacing a fluidic sample in a fluid flow path of an assay device are also described.

The invention is a device for quantitatively collecting pooled samples from multiwell plates.

Methods, devices, and systems for performing nebulization of a sample from a fluid channel of a microfluidic device are described. The systems or devices disclosed herein may comprise microfluidic devices that comprise a gas channel used for nebulization of the sample at a fluid outlet of the microfluidic device. In some instances, the disclosed devices may be designed to perform isoelectric focusing followed by further characterization of the separated analytes using electrospray ionization coupled with nebulization to introduce the samples into a mass spectrometer. The disclosed methods, devices, and systems provide for fast, accurate separation and characterization of protein analyte mixtures or other biological molecules by isoelectric point.

The present invention provides methods and devices for simple, low power, automated processing of biological samples through multiple sample preparation and assay steps. The methods and devices described facilitate the point-of-care implementation of complex diagnostic assays in equipment-free, non-laboratory settings.

Disclosed in one aspect is a method for performing a complete blood count (CBC) on a sample of whole blood by metering a predetermined amount of the whole blood and mixing it with a predetermined amount of diluent and stain and transferring a portion thereof to an imaging chamber of fixed dimensions and utilizing an automated microscope with digital camera and cell counting and recognition software to count every white blood cell and red blood corpuscle and platelet in the sample diluent/stain mixture to determine the number of red cells, white cells, and platelets per unit volume, and analyzing the white cells with cell recognition software to classify them.

A capillary chamber for performing chemical and physical analysis using a plurality of whole blood samples is presented. Following a loading of the whole blood samples into a plastic tube, the whole blood samples are distributed into a collection chamber and the capillary chamber has means of adding respective vaccines or similar biological products into each capillary tubes. The whole blood is then analyzed using standard microscopic techniques with sufficient resolution and contrast to record the chemical and physical properties of the blood immediately after withdrawal.

A sample analysis substrate includes a substrate; a first holding chamber; a reaction chamber; a first flow path having a first opening and a second opening respectively connected with the first holding chamber and reaction chamber; a main chamber; a second flow path having a third opening and a fourth opening respectively connected with the reaction chamber and the main chamber; and a magnet accommodation chamber capable of accommodating a magnet. The first opening is located closer to a rotation shaft than the second opening. The second opening is located closer to the rotation shaft than the third opening. The magnet accommodation chamber is located at a position at which, in the case where the magnet is accommodated in the magnet accommodation chamber, the magnet captures magnetic particles in the main chamber. The sample analysis substrate is rotatable to transfer a liquid.

Exemplary spatial genomics systems may include a flow cell and a fluid manifold. The flow cell may define an open interior, a fluid inlet to a first end of the open interior, and a fluid outlet to a second end of the open interior opposite the first end. The fluid manifold may include a body defining a plurality of fluid inlet lumens, a fluid outlet lumen, and a fluid waste lumen. Each of the plurality of fluid inlet lumens may be fluidly coupled with the fluid outlet lumen. The fluid outlet lumen may be fluidly coupled with the flow cell. The fluid manifold may include a plurality of fluid switches. Each of the plurality of fluid switches may be fluidly coupled with a respective one of the plurality of fluid inlet lumens. The fluid waste lumen may be fluidly coupled with the fluid outlet of the flow cell.