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.

A microfluidic device includes a particle sorting region having a first, second and third microfluidic channels, a first array of islands separating the first microfluidic channel from the second microfluidic channel, and a second array of islands separating the first microfluidic channel from the third microfluidic channel, in which the island arrays and the microfluidic channels are arranged so that a first fluid is extracted from the first microfluidic channel into the second microfluidic channel and a second fluid is extracted from the third microfluidic channel into the first microfluidic channel, and so that particles are transferred from the first fluid sample into the second fluid sample within the first microfluidic channel.

A method for a fluorometric assay in a cell-free protein synthesis environment includes providing a multi-well plate. The multi-well plate includes a cover plate and a base provided with a plurality of wells. Each well is formed by one or more side walls, a bottom II and an opening. The cover plate matches the opening. A volume of a reaction cavity of each well is less than 20 μL. Some of the wells in the plurality of wells are in fluid communication with each other. Fluid is provided to some of the wells. The cover plate is placed on a top of the base, and the fluid is in contact with the bottom II of each well and the cover plate, and the multi-well plate is incubated.

A system and method for determining a trajectory parameter of particles, comprising receiving a plurality of particles at a microfluidic channel, applying a force to each particle of the microfluidic channel, acquiring a dataset of each particle, measuring a trajectory of the particle, and determining a trajectory parameter of the particles.

A microfluidic device includes a particle sorting region having a first, second and third microfluidic channels, a first array of islands separating the first microfluidic channel from the second microfluidic channel, and a second array of islands separating the first microfluidic channel from the third microfluidic channel, in which the island arrays and the microfluidic channels are arranged so that a first fluid is extracted from the first microfluidic channel into the second microfluidic channel and a second fluid is extracted from the third microfluidic channel into the first microfluidic channel, and so that particles are transferred from the first fluid sample into the second fluid sample within the first microfluidic channel.

Methods and apparatus for controlling flow in a microfluidic arrangement are disclosed. In one arrangement, a microfluidic arrangement comprises a first liquid held predominantly by surface tension in a shape defining a microfluidic pattern on a surface of a substrate. The microfluidic pattern comprises at least an elongate conduit and a first reservoir. A second liquid is in direct contact with the first liquid and covers the microfluidic pattern. A flow of liquid is driven through the elongate conduit into the first reservoir. The microfluidic pattern and the depth and density of the second liquid are such that the first reservoir grows in volume during the flow of liquid into the first reservoir, without either of the size and shape of an area of contact between the first reservoir and the substrate changing, until an upper portion of the first reservoir detaches from a lower portion of the first reservoir due to buoyancy and rises upwards through the second liquid, thereby allowing the first reservoir to continue to receive liquid from the flow of liquid without any change in the size and shape of the area of contact between the first reservoir and the substrate.

An open microfluidic system is provided. The open microfluidic system including the extreme wettability of exclusive liquid repellency (ELR), open microchannels with high lateral resolution and low profile, various valve arrangements, capable of a broad range flow rates, and capable of spatially and temporally trapping particles in open fluid.

Disclosed herein is a cell culture device and its applications of creating gradient of chemicals or gradient of cells to mimic the in vivo physiological conditions of homeostasis.

A system and method for determining a trajectory parameter of particles, comprising receiving a plurality of particles at a microfluidic channel, applying a force to each particle of the microfluidic channel, acquiring a dataset of each particle, measuring a trajectory of the particle, and determining a trajectory parameter of the particles.

The present disclosure provides a blood vessel-mimicking microfluidic chip for cell co-culture and a use thereof, wherein the microfluidic chip of the present disclosure is a microfluidic chip capable of co-culturing vascular endothelial cells and cancer cells, and can mimic normal vascular tissue, cancer tissue, and cancer-metastatic vascular tissue, and therefore can be widely used in studies associated with cancer, and especially, is suitable in studies on cancer metastasis, intravenous injection environments for cancer treatment, photothermal therapeutic effects on cancer cell, and the like.