The present invention relates to a method for cancer cell separation, and more specifically, relates to a method for cancer cell separation using micro-vibration.

The present invention describes a fluidic device for measuring at least one of corpuscle mass density and weight. The fluidic device comprises a sedimentation chamber fluidly connected to an inlet channel configured to be immersed in a liquid. The fluidic device further comprises a pumping system connected to the sedimentation chamber. The pumping system is adapted to control the flow of liquid in the sedimentation chamber. A processor of the fluidic device is configured to obtain corpuscle data related to a corpuscle in at least one region of the sedimentation chamber; and calculate at least one of corpuscle mass density and weight based on the data received.

In some examples, a system including a fluid stream monitoring system. The monitoring system includes an illumination device configured to illuminate at least some of particles suspended in a fluid stream; and an imaging device configured to image the illuminated particles at a first image plane that intersects a longitudinal axis of the fluid stream, wherein the illumination device and the imaging device are registered to the fluid stream delivery device in the first image plane, where the first image plane is substantially orthogonal to the longitudinal axis. The system includes processing circuitry configured to determine one or more physical characteristics of the fluid particles.

A microfluidic device system includes a channel having an entrance and an exit, a height at the entrance being greater than a height at the exit. The height of the channel may decrease continuously from the height at the entrance to the height at the exit. Cells or particles or beads traveling through the channel become trapped based on their size and/or deformability. A visual sensor captures images of the trapped cells or particles or beads, and image software analyzes the captured images to provide size and/or deformability and/or fluorescence information. A method of fabricating such a microfluidic device includes introducing a glass wafer to an etching solution at a specific rate such that a first end of the glass wafer is etched longer than other portions of the glass wafer.

Provided herein are systems and method for measuring cell stiffness. In particular, provided herein are microelectrode configuration and systems for measuring platelet deformation and stiffness.

Provided herein are systems and method for measuring cell stiffness. In particular, provided herein are microelectrode configuration and systems for measuring platelet deformation and stiffness.

Embodiments of a system and method for deforming a can include a substrate including an inlet module and an outlet module; a fluidic pathway coupled to the inlet module and the outlet module, and including a sample branch operable to transmit the sample fluid; one or more sheath fluid branches flanking the sample branch and operable to transmit sheath having a sheath fluid viscosity higher than a sample fluid viscosity of the sample fluid; a delivery region initiating at a junction between the sample branch and the one or more sheath fluid branches, and operable to transmit a co-flow comprising the sample fluid and the sheath fluid; and a deformation region located downstream of the delivery region and operable to deform the one or more particles of the sample fluid based upon a reduced velocity of the sheath fluid with respect to the sample fluid in the co-flow.

This invention provides new methods and apparatus for rapidly analyzing a single bioparticle or a plurality of bioparticles to assess their condition. The invention is enabled by an optical microcavity comprising reflective structures to confine light and bioparticles in the same space. Under resonance conditions, an electromagnetic standing wave is established in the microcavity to interact with the bioparticle. Means are provided to bring a bioparticle into the microcavity and to detect changes in the resonance condition with and without the bioparticle in the microcavity. Information about the bioparticle is obtained using the benefits of light interactions as fast, non-contacting, and non-destructive.

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.

An optical particulate detection system for an aircraft is provided. The optical particulate detection system includes an optical particulate detector and a controller. The optical particulate detector includes at least two optical sources and at least one optical sensor distributed in series with respect to a flow path of a component surface of the aircraft. The controller is configured to interface with the optical particulate detector, monitor the at least one optical sensor, and characterize one or more particles of foreign object debris based on a pulse width and two or more scattering ratios determined with respect to light emitted from the at least two optical sources.