Embodiments of the present disclosure provide for devices, methods for separating particles, and the like.

Embodiments of the present disclosure provide for devices, methods for separating particles, and the like.

A magnetic base for a sample plate of a sample processing system is provided comprising a first plate comprising a first top surface; a bottom surface; and a sample plate mounting cavity wall mounted to the first top surface, wherein the first plate and the sample plate mounting cavity wall define a sample plate mounting cavity configured to accommodate a sample plate of a sample processing system. The magnetic base further comprises a second plate extending parallel to the first plate, the second plate comprising a second top surface; and a magnet mounting cavity wall extending between the bottom surface of the first plate and the second top surface of the second plate, wherein the first plate, the second plate, and the magnet mounting cavity wall define a magnet mounting cavity configured to accommodate a free floating magnet.

A magnetic base for a sample plate of a sample processing system is provided comprising a first plate comprising a first top surface; a bottom surface; and a sample plate mounting cavity wall mounted to the first top surface, wherein the first plate and the sample plate mounting cavity wall define a sample plate mounting cavity configured to accommodate a sample plate of a sample processing system. The magnetic base further comprises a second plate extending parallel to the first plate, the second plate comprising a second top surface; and a magnet mounting cavity wall extending between the bottom surface of the first plate and the second top surface of the second plate, wherein the first plate, the second plate, and the magnet mounting cavity wall define a magnet mounting cavity configured to accommodate a free floating magnet.

A process. The process includes forming a slurry comprising electrode active material particles of one or more lithium-ion electrochemical cells, magnetizing the electrode active material particles, and separating the magnetized electrode active material particles from the slurry.

A process. The process includes forming a slurry comprising electrode active material particles of one or more lithium-ion electrochemical cells, magnetizing the electrode active material particles, and separating the magnetized electrode active material particles from the slurry.

Devices, methods, and systems are provided for extracting particles from a ferrofluid and for rapid affinity measurements. Such systems may comprise a fluidic channel or chamber configured to include a ferrofluid having a plurality of target particles and background particles. The systems may include a capture region configured to capture at least a portion of the plurality of target particles. In addition, the systems include a first magnetic field generator and a second magnetic field generator. The first magnetic field generator may be arranged proximate to the fluidic channel, the first magnetic field generator being configured to generate a first magnetic field configured to direct the plurality of target particles towards the capture region. The second magnetic field generator can be arranged to be proximate to the capture region, and is further configured to generate an affinity thresholding magnetic field configured to remove background particles from the capture region.

Devices, methods, and systems are provided for extracting particles from a ferrofluid and for rapid affinity measurements. Such systems may comprise a fluidic channel or chamber configured to include a ferrofluid having a plurality of target particles and background particles. The systems may include a capture region configured to capture at least a portion of the plurality of target particles. In addition, the systems include a first magnetic field generator and a second magnetic field generator. The first magnetic field generator may be arranged proximate to the fluidic channel, the first magnetic field generator being configured to generate a first magnetic field configured to direct the plurality of target particles towards the capture region. The second magnetic field generator can be arranged to be proximate to the capture region, and is further configured to generate an affinity thresholding magnetic field configured to remove background particles from the capture region.

A system for determining drug effectiveness on a plurality of cells is described. The system includes flowing a ferrofluid mixed with a plurality of biological cells through an inlet portion of a cartridge, the cartridge comprising a plurality of microfluidic channels, the inlet is in communication with a portion of each of the plurality of channels, applying a magnetic field proximate at least one of the inlet portion and the plurality of micro-channels, wherein the magnetic field is configured to apply an indirect force on the mix, separating biologic cells according to at least a first type as the mix flows in a first direction; and directing at least the first type of cells toward a first sensor functionalized with receptors via at least one of the micro-channels, the sensor arranged proximate to a second portion of at least one of the micro-channels downstream from the first inlet portion.

A system for determining drug effectiveness on a plurality of cells is described. The system includes flowing a ferrofluid mixed with a plurality of biological cells through an inlet portion of a cartridge, the cartridge comprising a plurality of microfluidic channels, the inlet is in communication with a portion of each of the plurality of channels, applying a magnetic field proximate at least one of the inlet portion and the plurality of micro-channels, wherein the magnetic field is configured to apply an indirect force on the mix, separating biologic cells according to at least a first type as the mix flows in a first direction; and directing at least the first type of cells toward a first sensor functionalized with receptors via at least one of the micro-channels, the sensor arranged proximate to a second portion of at least one of the micro-channels downstream from the first inlet portion.