Methods of concentrating beads in a droplet and/or loading beads on a fluidic device are provided, including among other things, a method of concentrating beads in a droplet, the method comprising: (a) providing a droplet actuator comprising: (i) an interior droplet operations volume; and (ii) a reservoir exterior to the interior volume; (iii) a droplet established in a liquid path extending from the reservoir into the interior volume; (b) providing magnetically responsive beads in the portion of the droplet which is in the reservoir; (c) magnetically attracting the magnetically responsive beads through the liquid path into the portion of the droplet which is in the interior volume; and (d) forming a droplet comprising one or more of the magnetically responsive beads in the interior volume.

The present invention relates to fluidic devices for preparing, processing, storing, preserving, and/or analyzing samples. In particular, the devices and related systems and methods allow for preservation or storage of samples (e.g., biospecimen samples) by using one or more of a bridge, a membrane, and/or a desiccant.

The present invention relates to portable devices for point-of-care diagnostics that can perform measurements on a sample (e.g., blood, serum, saliva, or urine) and relay data to an external device for, e.g., data analysis. The device can comprise a paper-based diagnostic substrate and a base substrate that include electronic circuitry and electronic elements necessary for performing the measurements. The device can also comprise an antenna for near field communication with an external device. Another aspect of the invention relates to methods of using these devices.

The invention relates to a microfluidic system comprising a magnetic source (150) and two chambers (110) that are connected by a channel. According to a preferred embodiment, the chambers and the channel are filled with different fluids such that a non-zero surface tension is created at the associated fluidic interfaces. Moreover, the magnetic source (150) is arranged to provide at least two separate magnetic gradient regions (GR) and to allow for the attraction of magnetic particles (MP) present in one of the chambers into these different regions, wherein furthermore the magnetic attraction forces (F) generated by at least one of the gradient regions (GR) is strong enough to allow for pushing or pulling magnetic particles through said fluidic interfaces. In a preferred embodiment, the magnetic source may be realized by a permanent magnet (150) of hexahedral shape. The invention further relates to a method for achieving dispersion and a method for achieving accumulation of an ensemble of magnetic particles in said microfluidic system.

The present invention is directed to sample test cards having an increased sample well capacity for analyzing biological or other test samples. In one embodiment, the sample test cards of the present invention comprise one or more fluid over-flow reservoirs, wherein the over-flow reservoirs are operatively connected to a distribution channel by a fluid over-flow channel. In another embodiment, the sample test cards may comprise a plurality of flow reservoirs operable to trap air thereby reducing and/or preventing well-to-well contamination. The test card of this invention may comprise from 80 to 140 individual sample wells, for example, in a test card sample test cards of the present invention have a generally rectangular shape sample test card having dimensions of from about 90 to about 95 mm in width, from about 55 to about 60 mm in height and from about 4 to about 5 mm in thickness.

A cell sorting apparatus includes a flow channel through which fluid including cells flows, an electric-field application section capable of applying an electric field having a gradient in a direction different from the flowing direction of the fluid at a first position on the flow channel in accordance with a cell sorting signal requesting an operation to sort the cells, and a flow splitting section configured to split the cells changing their flowing directions due to a dielectrophoretic force caused by application of the electric field at a second position on the downstream side of the first position on the flow channel.

A system that includes a cartridge housing and a hollow transfer module, according to an embodiment is described herein. The cartridge housing further includes at least one sample inlet, a plurality of storage chambers, a plurality of reaction chambers, and a fluidic network. The fluidic network is designed to connect the at least one sample inlet, a portion of the plurality of storage chambers and the portion of the plurality of reaction chambers to a first plurality of ports located on an inner surface of the cartridge housing. The hollow transfer module includes a second plurality of ports along an outer surface of the transfer module that lead to a central chamber within the transfer module. The transfer module is designed to move laterally within the cartridge housing. The lateral movement of the transfer module aligns at least a portion of the first plurality of ports with at least a portion of the second plurality of ports.

Disclosed are high-throughput vessel supply systems and methods of supplying sample vessels, such as samples stored in test tubes. A system for supplying a plurality of individual vessels that each contains a sample is disclosed.

The present invention is directed to the use of microfluidics in the preparation of cells and compositions for therapeutic uses.

This disclosure relates to a system for sorting sperm cells in a microfluidic chip. In particular, various features are incorporated into the system for aligning and orienting sperm in flow channels, as well as, for determining sperm orientation and measuring relative DNA content for analysis and/or sorting.