The present invention provides a medical analysis device and a cell analysis method, which can capture specific cells such as many types of cancer cells including cancer cells not expressing EpCAM and stem cells. Provided is a medical analysis device including a well portion, the well portion having a hydrophilic silane compound layer formed at least partly on the inner surface thereof.

We describe a microfluidic structure for spacing out droplets, the structure comprising: a main channel for guiding droplets in a spacing fluid; a first inlet for introducing droplets into the main channel; and a second inlet for introducing a spacing fluid into the main channel, wherein a cross-sectional area of the main channel decreases downstream from the first inlet. We also describe a method of spacing out droplets using a microfluidic structure.

A device and method for detecting particles by using electrical impedance measurement, in particular, relating to an improved electrical impedance measurement microfluidic chip and an improved particle detection method. The device comprises a sample injection part, a main channel (4) and an electrical impedance detection part. By means of said device and method, the present invention can accurately distinguish, detect and count different particles.

Systems and methods for detection of a signal from droplets of an emulsion. An exemplary system may comprise a fluid transporter having a tube with an open end for aspirating droplets, a singulator to arrange the droplets in single file and to space the single-file droplets from one another, and a detection channel in optical communication with a detector configured to detect a signal from droplets. In some embodiments, the singulator may have a channel junction at which a stream of droplets in single file is combined with a stream of spacing fluid, and a tapered spacing channel extending downstream from the channel junction toward the detection channel. In some embodiments, the fluid transporter may suck droplet-containing fluid and spacing fluid through the detection channel from respective sources. In some embodiments, droplets may be subjected to a disaggregation routine before they are passed through the detection channel.

A collection device for collecting volatile organic compounds (VOCs) from a living biological sample is disclosed. The collection device comprises a housing defining an interior chamber and an inlet and outlet each fluidly communicating with the interior chamber. The housing is formed by an upper surface, a lower surface, and a substantially circular sidewall extending between the upper and lower surfaces. The interior chamber comprises a substantially cylindrical volume enclosed by the housing and configured to receive the living biological sample. The inlet and the outlet may extend through the upper surface and may be substantially diametrically opposed with respect to the circular sidewall. The collection device may be configured to pass fluid in a substantially laminar flow path through the inlet, across the interior chamber, and out of the outlet. At least a portion of the housing may comprise a substantially transparent material configured to transmit light therethrough.

A variety of devices and methods are provided for separating or enriching circulating tumor cells in a biological sample such as whole blood. In some aspects, the devices are multi-stage devices including at least (i) a filtering stage, (ii) a sheath flow stage for ferrohydrodynamic separation of magnetically labelled white blood cells, and (iii) a focusing stage for marker-independent and size-independent focusing of magnetically labeled particles so as to separate or enrich unlabeled rare cells in the biological sample. The devices and methods are, in some aspects, capable of high throughput in excess of 6 milliliters per hour while achieving high separation (>95%) of the unlabeled rare cells.

A method for fluid transport includes receiving fluid at an inlet port of an inlet. The fluid is outputted through an opening of the inlet into a channel. A first ratio of a first distance to a second distance is substantially equal to a cubic root of a second ratio between a first length dimension and a second length dimension of the inlet, the first distance being measured from an entrance of the inlet port to a first position within the inlet, the second distance being measured from the entrance of the inlet port to a second position within the inlet, the first length dimension and the second length dimension each being measured along a direction orthogonal to a measurement direction along the first distance and the second distance, the first length dimension and the second length dimension being measured at the first position and the second position, respectively.

Blood typing systems and methods are provided. In one embodiment, the method may be achieved by applying a sample to a surface of a substrate having one or more binding agents immobilized thereon, wherein the one or more binding agents are capable of binding to one or more substances in the sample; substantially removing unbound material from at least a portion of the substrate having immobilized binding agent; and detecting substances bound to the one or more binding agents immobilized on the substrate; wherein the applying the sample to the surface of the substrate step is concurrent with the removing unbound material from at least a portion of the substrate step. Systems and other methods are also described and illustrated.

A microfluidic sorting device and method employing dielectrophoresis (DEP) induced field flow separations are described herein. The microfluidic sorting device has a microchannel and an array of electrodes disposed along the microchannel. The electrodes may be oriented at an angle relative to the microchannel. Non-mammalian samples such as plant samples flow in the microchannel and through the electrode array. Current is passed through the electrodes causing a DEP force to be exerted on the samples. This force may generate a torque that causes one type of sample to rotate and slide along the electrodes, thus separating the samples by type. The separated samples are collected in different output channels

A cartridge for delivering a payload to cells of a cell suspension is provided, wherein the cartridge comprises an input channel that delivers the cell suspension to a first plurality of branch channels, and wherein the first plurality of branch channels each deliver the cell suspension into a respective one or a plurality of microfluidic chips or filters. Cell suspension exiting a microfluidic chip or filter flows into a respective one of a second plurality of branch channels, and is then delivered to an output channel by which it exits the cartridge. The cartridge may comprise a plurality of removable covers that hold the chips or filters in place against a body of the cartridge in which the input channel, output channel, and branch channels are formed.