Intermittent warming of a biologic sample including a nucleic acid includes receiving at a first end of a channel of a microfluidic device, a biologic sample including a nucleic acid, and warming a subset of a plurality of heating elements disposed adjacent to the channel. The method includes warming the heating elements to a particular temperature of a particular warming and cooling protocol. The method includes moving the biologic sample from the first end of the channel to a second end of the channel opposite the first end at a particular flow rate associated with the warming and cooling protocol, and intermittently warming the biologic sample using the subset of heating elements while the biologic sample moves from the first end of the channel to the second end of the channel.

A laboratory water generation and distribution system capable of distributing laboratory water at different temperatures is disclosed. A laboratory water generation section is configured to receive potable water and treat the potable water to generate laboratory water. A laboratory water distribution section comprises a laboratory water storage tank and a main distribution loop fluidly communicating with the laboratory water storage tank to receive the laboratory water therefrom. The laboratory water distribution section further comprises a sub distribution loop operatively connected to the main distribution loop via a valve to receive the laboratory water therefrom. The sub distribution loop returns to the main distribution loop and dispenses the laboratory water to the main distribution loop.

A microfluidics device has one or more bubble diversion regions. Problems associated with the generation of air bubbles are avoided in a microfluidics device such as a cartridge, for use with a point of care (POC) diagnostics device, the cartridge being able to carry out downstream processing such as polymerase chain reaction (PCR) and/or nucleic acid capture. The bubble diversion region has a lower flow resistance than the flow resistance of an area of interest.

The present invention discloses a microstructured discrimination device for separating hydrophobic-hydrophilic fluidic composites comprising particulate and/or fluids in a fluid flow. The discrimination is the result of surface energy gradients obtained by physically varying a textured surface and/or by varying surface chemical properties, both of which are spatially graded. Such surfaces discriminate and spatially separate particulate and/or fluids without external energy input. The device of the present invention comprises a platform having bifurcating microchannels arranged radially. The lumenal surfaces of the microchannels may have a surface energy gradient created by varying the periodicity of hierarchically arranged microstructures along a dimension. The surface energy gradient is varied in two regions. In one pre-bifurcation region the surface energy gradient generates a fluid flow. In the other post-bifurcation region, there is a difference in surface energy proximal to the bifurcation such that different flow fractions are divided into separate channels in response to different surface energy gradients in each of the post-bifurcation channels. Accordingly, fluids of different hydrophobicity and/or particulate of different hydrophobicity are driven into separate channels by a global minimization of the fluid system energy.

A microfluidic device for analyzing permeability of substances through a membrane. Flow channels pass respective fluid flows with the substances through the housing between respective connectors. An access cavity extends from outside into the housing through the first flow channel and into the second flow channel for accessing an inside of the housing. The membrane can be placed over a cavity opening forming a fluid interconnection between overlapping areas of the flow channels A clamping ring in the first flow channel holds the sample membrane in place over the cavity opening while the membrane is exposed to the respective fluid flows through the flow channels on either sides of the membrane.

The present invention relates to a spiral microfluidic device and module for CTC separation from blood, a manufacturing method. When a blood sample and a body fluid sample are respectively injected into the inlet of the device by the method described below, viable CTCs can be isolated and used for the development of specific cancer cell lines. The device has two inlets with a radius of 10 mm or less, a two-loop helical microchannel having a uniform height of a radial inner portion and a radial outer portion, and a rectangular cross-section in which the width of the upper portion is equal to the width of the base, and the two-loop helical microchannel is branched from the CTC and two outlets through which blood cells are separately discharged. The present invention can provide a spiral microfluidic device and module for CTC isolation, a manufacturing method, which can lead to the development of a reported specific cell line by making it possible to isolate viable CTCs by a spiral microfluidic device for CTC isolation derive an effect.

The invention concerns a method, an assembly and a system for determining a characteristic property of a molecular interaction. The method includes providing a liquid sample including a particle capable of being in a state of equilibrium and in a state of non-equilibrium. The particle includes a marker in at least one of its state of equilibrium and state of non-equilibrium. The method further includes bringing the particle in a state of non-equilibrium by subjecting the sample to a condition jump comprising a jump in temperature and/or pressure; reading out the marker as a function of time during at least a portion of a relaxation time for said particle, and determining said characteristic property of said molecular interaction.

A microfluidic diagnostic chip may comprise a microfluidic channel, a functionalizable enzymatic sensor in the microfluidic channel, the functionalizable enzymatic sensor comprising a binding surface to bind with a biomarker in a fluid, and a microfluidic pump to pass the fluid over the binding surface. A microfluidic device may comprise a number of pumps to pump a fluid though the number of microfluidic channels and a number of microfluidic channels comprising at least one sensor to detect a change in a chemical characteristic of the fluid in response to presence of the fluid on the sensor

A fluidic device includes: a circulation flow path; and a capture part arranged on the circulation flow path and configured to capture a sample substance in a solution and/or a detection part arranged on the circulation flow path and configured to detect a sample substance in a solution. A method of capturing a sample substance that is bound to a carrier particle, using a fluidic device which includes a circulation flow path and a capture part arranged on the circulation flow path and configured to capture the carrier particle and in which the circulation flow path has two or more circulation flow path valves, includes: an introduction step of, in a state where the circulation flow path valve is closed, introducing a solution that includes a sample substance to at least one of partitions partitioned by the circulation flow path valve and introducing a solution that includes a carrier particle which is bound to the sample substance to at least another of the partitions; a mix step of opening all of the circulation flow path valves and circulating and mixing a solution in the circulation flow path; and a capture step of capturing the carrier particle by the capture part.

Disclosed is a microfluidic biosensing system including a processor, in which a Raman barcode database corresponding to at least one Raman spectrum signal is stored, a plurality of Raman barcode beads mixed with a target fluid and coupled to at least one target bioparticle in the target fluid, a microfluidic channel disposed to make the target fluid mixed with the Raman barcode beads flow therethrough, a light source disposed on the microfluidic channel, and a spectral detection device connected to the processor and disposed to correspond to the light source. The spectral detection device receives the Raman spectrum signal generated when the target bioparticle coupled with the Raman barcode bead is irradiated, and transfers the received Raman spectrum signal to the processor. The processor determines a type of the bioparticle(s) and calculates the number of bioparticle(s) by matching the Raman spectrum signal(s) to the Raman barcode database.