The present disclosure relates to a microfluidic device capable of mimicking a biological microenvironment thereby achieving control of a microenvironment with time through control of the diffusion of target elements between chambers by interrupting or generating fluid flow inside a channel, and a method for manufacturing the same, and the microfluidic device according to an aspect of the present disclosure can mimic the biological microenvironment which changes constantly with time via a simple temporary operation of generating or interrupting fluid flow in the channel mechanically and can control diffusion via a simple method, and accordingly, a complicated microenvironment can be reproduced since the number and arrangement of diffusion chambers and channels can be designed variously.

In certain aspects of the invention, a stackable device includes multiple elements stacked sequentially. A chamber is formed in each of the elements or between adjacent two of the elements, and each chamber is in fluid communication with an input channel and an output channel. The chambers are aligned with each other, and adjacent two chambers are separated from each other by a membrane. In certain aspects of the invention, a system includes at least one stackable device, each stackable device having multiple chambers; and at least one of a perfusion controller, a microformulator, and a microclinical analyzer in fluid communication with the at least one stackable device. In other aspects of the invention, the use of four microformulators, electrodes and an impedance analyzer can measure the impedance spectrum of each barrier in a multi-transwell plate.

A high throughput screening apparatus having a base with channels for receiving a reagent. The channels are spaced across the surface of the base and have one or more walls which extend through the base from a first base surface to a second base surface. A compression member containing a plurality of openings extending through the compression member are positioned across the surface of the compression member, one or more of the openings being positioned for alignment with a corresponding channel in the base. A grip for removably securing the compression member to the base, when a compressible sheet is positioned across the channel between the base and the compression member and fixed by the grip, parts of the compressible sheet are compressed between the base and the compression member to form a seal between the base and the compression member, forming one or more wells for containing the reagent.

The invention provides devices that improve tests for detecting specific cellular, viral, and molecular targets in clinical, industrial, or environmental samples. The invention permits efficient detection of individual microscopic targets at low magnification for highly sensitive testing. The invention does not require washing steps and thus allows sensitive and specific detection while simplifying manual operation and lowering costs and complexity in automated operation. In short, the invention provides devices that can deliver rapid, accurate, and quantitative, easy-to-use, and cost-effective tests.

A method for analyzing a component is provided. The method includes the steps of: (iii) providing the electrophoretic or thermophoretic movement of the component into a second fluid flow; (iv) diverting a part of a first fluid flow, a part of the second fluid flow, or parts of the first fluid flow and the second fluid flow, wherein the diverted part is a third fluid flow which includes, the component; (v) contacting the third fluid flow with a fourth fluid flow, such as to form a laminar flow; (vi) providing the diffusion of the component into the fourth fluid flows.

Apparatus and methods for determining whether a test compound induces cell activity, changes cell activity, prevents cell activity, or inhibits cell activity. An embodiment comprises placing a test compound solution in contact with a cell suspension media containing cells, diffusing the test compound solution into the cell suspension from one or more sides, and detecting activity in the cells with respect to their distance from the side from which the test compound is diffusing. Embodiments may provide an apparatus that allows a side source, a point source, or both, from which a test compound solution diffuses into a cell suspension media and contacts cells. Detecting cell activity may involve detecting activity in a first cell group proximate to the side from which the test compound is diffusing, and detecting activity in a second cell group farther than the first cell group from the side from which the test compound is diffusing.

Methods, systems and kits are described herein for detecting the results of an assay. In particular, the methods, systems and devices of the present disclosure rely on a difference between the diffusion rates of a reporter molecule and an analyte of interest in order to quantify an amount of analyte in a microfluidic device. The analyte may be a secreted product of a biological micro-object.

The invention relates to an ingestible, implantable or wearable medical device comprising a microarray which comprises a bioactive agent capable of interacting with a disease marker biological analyte; a reservoir which comprises at least one therapeutic agent and is capable of releasing the therapeutic agent(s) from the medical device; and a plurality of microchips comprising a microarray scanning device capable of obtaining physical parameter data of an interaction between the disease marker biological analyte with the bioactive agent; a biometric recognition device capable of comparing the physical parameter data with an analyte interaction profile; optionally a therapeutic agent releasing device capable of controlling release of the therapeutic agent from the reservoirs; an interface device capable of facilitating communications between the microarray scanning device, biometric recognition device and the therapeutic agent releasing device; and an energy source to power the medical device. Specifically, the invention relates to a medical device capable of detecting an analyte in a bodily fluid comprising at least one microneedle capable of obtaining a sample of a bodily fluid, a first microchannel through which the sample flows and is in fluid communication with the at least one microneedle, a second microchannel in fluid communication with the first microchannel, through which a buffer flows, wherein the second channel comprises a microarray with a bioactive agent, a microarray scanning device to detect an interaction between the bioactive agent and the analyte in the bodily fluid; and an interface device.

The present invention relates to analytical testing devices including micro-environment sensors and methods for assaying coagulation in a fluid sample applied to the micro-environment sensors, and in particular, performing one or more types of coagulation assays using one or more micro-environment sensors in a single point of care combined test cartridge. For example, the present invention may be directed to test sensor including at least one transducer coated with a polymer layer. The polymer layer comprises a thrombin-cleavable peptide with a detectable moiety.

An apparatus for supporting an array of layers of amphiphilic molecules, the apparatus comprising: a body (11), formed in a surface of the body, an array of sensor wells (10) capable of supporting a layer of amphiphilic molecules (30) across the sensor wells, the sensor wells each containing an electrode (12) for connection to an electrical circuit, and formed in the surface of the body between the sensor wells, flow control wells capable of smoothing the flow of a fluid across the surface.