The invention relates to a device and method for in situ temperature-induced antigen retrieval of samples wherein all steps are performed under a pressure higher than the atmospheric pressure on a sample immobilized on a sample support which can be further subjected to staining and imaging on the same sample support, optionally by cycle multiplexing that enables imaging of various molecular targets through multi-molecular read-outs on the same sample in a rapid, highly sensitive and reliable manner.

The present invention provides systems, devices, and methods for point-of-care and/or distributed testing services. The methods and devices of the invention are directed toward automatic detection of analytes in a bodily fluid. The components of the device can be modified to allow for more flexible and robust use with the disclosed methods for a variety of medical, laboratory, and other applications. The systems, devices, and methods of the present invention can allow for effective use of samples by improved sample preparation and analysis.

A method for manipulating a microdroplet of a reaction medium in an immiscible carrier medium with a target molecule bound to a solid support for the purposes of effecting a chemical transformation is provided. It is characterised by the steps of (a) bringing the microdroplet into contact with the solid support under conditions where the microdroplet and solid support are caused to combine, (b) allowing the reaction medium to react with the target molecule and (c) thereafter exerting a force to induce the reaction medium to become detached from the solid support and reform a microdroplet in the carrier fluid. In one embodiment the solid support is a particle, bead or the like.

A fluidic assembly comprising a fluid analysis apparatus (30), the fluid analysis apparatus (30) comprising: a fluid measurement device (34); a fluidic device including a flow cell (36) arranged in a measurement region of the fluid measurement device (34), the flow cell (36) constructed of at least one first fluoropolymer material, the flow cell (36) including a channel, the channel containing a sample segment (52) that is carried in a fluorinated fluid carrier (54), wherein the sample segment (52) and fluorinated fluid carrier (54) are immiscible.

A micro-fluidic chip comprises a chip base, a lens, and a securing portion. The chip base has a flow cell and a micro-fluidic channel defined therein. The micro-fluidic channel is fluidly connected to the flow cell to deliver fluid to and from the flow cell, respectively via a fluid input port and a fluid output port. The lens has an apex and a base. The apex is positioned within the flow cell. The securing portion is affixed to the chip base such that the lens is sandwiched between the chip base and the securing portion. The securing portion has a circular cavity defined therein in a surface adjacent the chip base, for receiving the base of the lens. The securing portion further has separate light input and output channels to allow light in and out, respectively, of the circular cavity and the lens.

A apparatus for detecting cells or particles in a fluid container includes a dispenser configured to dispense at least one cell or at least one particle into a defined sub-volume of a fluid with which the fluid container is at least partially filled, and a detection apparatus configured to, in a time-coordinated manner with dispensing the at least one cell or the at least one particle by the dispenser, perform a detection in the defined sub-volume and/or in one or several sub-volumes underneath the defined sub-volume in order to sense the at least one cell or the at least one particle when entering the fluid or immediately after entering the fluid.

A biochip device includes a waveguide, chromophore elements, a diffusing structure, and a sloping surface. The chromophore elements are disposed on a portion of the waveguide and are configured to emit fluorescence in response to excitation by guided light waves transmitted by the waveguide. The diffusing structure is configured to generate guided light waves in the waveguide when illuminated. The sloping surface is sloped relative to a plane of the waveguide and is configured to direct excitation light into the waveguide, and the sloping surface and the waveguide are configured to deflect the excitation light to the diffusing structure to generate guided light waves within the waveguide. The sloping surface may be a face of a prism attached to or integrated with the waveguide, or the sloping surface may be a chamfer formed at an edge of the waveguide.

The present invention discloses a Polymerase Chain Reaction (PCR) apparatus for real-time detecting of one or more fluorescent signals. According to the apparatus, the PCR is performed by controlling heating and cooling intervals of a reagent container receiving space. With the aid of an added specific probe and fluorescent material, as well as a light source and a spectrometer, a generated fluorescent signal is detected. Meanwhile, the apparatus is also pre-loaded with an algorithm configured to analyze and quantify the fluorescent signal in a real-time manner.

Disclosed are cartridge components, cartridges, systems, and methods for isolating analytes from biological samples. In various aspects, the cartridge components, cartridges, systems, and methods may allow for a rapid procedure that requires a minimal amount of material from complex fluids.

An example micro-fluidic device includes a micro-fluidic channel having an inner surface and a plurality of pillars positioned along the inner surface. The device further includes a plurality of power supplies connected to the pillars. Another example micro-fluidic device includes a micro-fluidic channel having an inner surface and a plurality of pillars positioned along the inner surface. The device further includes a power supply. The pillars are grouped into at least two groups of pillars, each group of pillars including at least two pillars, and all pillars of at least one group of pillars are connected to the power supply. In another example, a sensing system for detecting bioparticles includes a micro-fluidic device, wherein a surface of each pillar comprises functionalized plasmonic nanoparticles or functionalized SERS nanoparticles, a radiation source for radiating the micro-fluidic device, and a detector for detecting SERS signals or surface plasmon resonance.