There is provided an arrangement (100) which allows for mixing a first fluid with a second fluid at a predetermined volume mixing ratio in a capillary driven fluidic system. The arrangement (100) allows filling an initially empty mixing chamber (110) with the first fluid. The arrangement then allows emptying a predetermined fraction of the first fluid from the mixing chamber (110) such as to form an empty space in the mixing chamber (110). The arrangement then allows filling the empty space of the mixing chamber (110) with the second fluid, thereby allowing a predetermined volume of the first fluid to mix with a predetermined volume of the second fluid over time.

A pipette calibration and volume offset mechanism. The calibration and volume offset mechanism is provided to facilitate user selectable calibration or volume offset operations of a pipette to which the calibration and volume offset mechanism is installed, through axial displacement of a threaded element that effectively moves the home position of the pipette. An offset counter of the calibration and volume offset mechanism is rotationally coupled to the threaded element during a volume offset operation to indicate offset magnitude, but decoupled from threaded element during a calibration or recalibration operation.

The invention provides devices that improve tests for detecting specific cellular, viral, and molecular targets in clinical, industrial, or environmental samples. The invention permits efficient detection of individual microscopic targets at low magnification for highly sensitive testing. The invention does not require washing steps and thus allows sensitive and specific detection while simplifying manual operation and lowering costs and complexity in automated operation. In short, the invention provides devices that can deliver rapid, accurate, and quantitative, easy-to-use, and cost-effective tests.

Disclosed here are kits comprising pre-packed stabilizing solutions for stabilizing combinations of biomarkers demonstrating sufficient accuracy and specificity for identifying kidney injuries. Such kits can be better adapted for sample collection at a subject's dwelling, thus easing the burdensome requirement of continuous monitoring for kidney injury.

The present invention relates to a microfluidic system (10, 20) comprising: a sample reservoir (110, 210); a first sample channel (120, 220) connected to the sample reservoir (110, 210), branching off into a second sample channel (122, 222) ending in a first valve (130, 230), and into a third sample channel (124, 224) which branches off into a fourth sample channel (126, 226) ending in a second valve (132, 232), and into a fifth sample channel (128, 228) ending in a third valve (134, 234); a buffer reservoir (140, 240); a first trigger channel (150, 250) arranged to connect the buffer reservoir (140, 240) to the second valve (132, 232); a second trigger channel (152, 252) connecting the second valve (132, 232) and the first valve (130, 230); and an exit channel (154, 254) connected to the first valve (130, 230).

Microfluidic devices and methods of quantifying fatty acids and/or specialized pro-resolving mediators and/or fatty acid metabolites present in a fluid sample on a microfluidic device are described herein. The methods include extracting fatty acid esters containing fatty acids from the fluid sample, combining the extracted fatty acid esters with a hydrolyzing agent to cleave the fatty acids from the extracted fatty acid esters and form free fatty acids, and quantifying the free fatty acids by performing a bioassay specific to the free fatty acids. Microfluidic devices and methods of quantifying fatty acid metabolites present in a fluid sample on a microfluidic device are also described herein.

A lateral flow assay (LFA) device includes a capillary pad and a sample port that holds the sample fluid before a hole is made in a cavity surface of the sample port. The LFA device includes a breaker with a tip to make a hole in the cavity wall of the sample port causing the sample fluid held inside the compartment to be applied to the capillary pad after the start of a test.

Devices that includes a first portion, the first portion including at least one fluid channel; a fluid actuator; an analysis sensor disposed within the fluid channel; a conductivity sensor disposed within the fluid channel; and an introducer; a second portion, the second portion comprising: at least one well, the well containing at least one material, wherein one of the first or second portion is moveable with respect to the other, wherein the introducer is configured to obtain at least a portion of the material from the at least one well and deliver it to the fluid channel, and wherein the fluid actuator is configured to move at least a portion of the material in the fluid channel.

A microfluidic assembly may include a microfluidic chip operably coupled to a device source pressure port and a device relief pressure port, first and second input reservoirs, an output reservoir, and a reservoir interface. The microfluidic chip may include a microfluidic circuit configured to support a fluid flow that includes a gas flow and a liquid flow within the microfluidic circuit. The reservoir interface may be configured to operably couple the first and second input reservoirs to the microfluidic circuit. The device source pressure port may be configured to receive a source pressure to generate the fluid flow through the microfluidic circuit and cause a mixing of liquids to form an output liquid for delivery to the output reservoir via the fluid flow. The first liquid, the second liquid, and the output liquid need not contact the device source pressure port or the device relief pressure port during the mixing.