Abstract: Apparatus and Method for Handling Fluids at Nano-Scale Rates. A linear displacement pump produces non-pulsatile liquid flow rates as low as the nl/mm range. The pump includes a servo motor, a gear reduction, a lead screw, a linear stage, a barrel, and a plunger extending into the barrel and coupled to the stage. A microfluidic interconnect device can be coupled to the barrel. One or more of these pumps can be disposed in a thermally controlled pump assembly that includes a pump housing, a thermally conductive body disposed in the housing and including first and second opposing sides, and a temperature regulating element such as a thermoelectric device disposed in thermal contact with the thermally conductive body on a side thereof opposite to the barrel or barrels of the pumps.

Abstract: According to one embodiment, apparatuses and methods are provided for connecting a light-guiding conduit to a microfluidic channel. First and second substrates with first surfaces can be provided, wherein the first surfaces of the first and second substrates form a microfluidic channel and a connection channel when the first surfaces are positioned together, and wherein the connection channel extends from an edge of the first surface of the first or second substrate to the microfluidic channel. The apparatus and method can also include bonding the first surfaces of the first and second substrates to form the microfluidic channel and the connection channel. A light-guiding conduit can be inserted into the connection channel such that the light-guiding conduit connects to the microfluidic channel and filling an area between the light-guiding conduit and the connection channel for forming a liquid-tight seal between the light-guiding conduit and the connection channel.

Abstract: Microfluidic Systems, Devices and Methods for Reducing Diffusion and Compliance Effects at a Fluid Mixing Region. According to one embodiment, a microfluidic device is provided for combining fluids in a mixing region. The microfluidic device can include a fluid mixing region connected to a first and second microscale channel. The microscale channels can advance fluids to the fluid mixing region. The microscale channels can include constricted flow portions. According to another embodiment, the microscale channels can be connected to waste channels for removing fluid diffused into one of the channels from the other channel. According to yet another embodiment, a microfluidic system is provided for controlling the flow of fluids through the microscale channels for reducing or eliminating diffusion between the channels.

Abstract: Microfluidic Chip Apparatuses, Systems, and Methods having Fluidic and Fiber Optic Interconnections. According to one embodiment, apparatuses and methods are provided for connecting a light-guiding conduit to a microfluidic channel. First and second substrates with first surfaces can be provided, wherein the first surfaces of the first and second substrates form a microfluidic channel and a connection channel when the first surfaces are positioned together, and wherein the connection channel extends from an edge of the first surface of the first or second substrate to the microfluidic channel. The apparatus and method can also include bonding the first surfaces of the first and second substrates to form the microfluidic channel and the connection channel.

Abstract: An actively temperature regulated microfluidic chip assembly includes a first thermally conductive body, a second thermally conductive body attached to the first thermally conductive body, a microfluidic chip encapsulated between the first and second thermally conductive bodies, and a temperature regulating element mounted to the first thermally conductive body for adding heat to or alternately removing heat from the chip. The temperature of the chip and thus the liquid contained and/or flowing therein can be regulated by measuring the temperature of the liquid and operating the temperature regulating element to establish a thermal gradient toward or alternately away from the liquid based on the measured temperature and in comparison with a desired set point temperature.

Abstract: Microfluidic Systems, Devices and Methods for Reducing Noise Generated by Mechanical Instabilities. According to one embodiment, a microfluidic device is provided for reducing noise in a fluid mix. The microfluidic device can include microscale channels for passage of fluids to a mixing junction. The mixing channel can be adapted to combine the fluids into a common fluid flow. The microfluidic device can also include a connector channel including first and second ends. The first end of the connector channel can be connected to the mixing junction. The microfluidic device can also include an expansion channel having connection to the second end of the connector channel. The expansion channel can be adapted for passage of the fluid mix through the expansion channel to reduce concentration gradient noise of the fluid mix by dispersion of the fluid mix as the fluid mix passes through the expansion channel.

Abstract: According to one embodiment, a microfluidic system and method is disclosed for reducing autofluorescence. The microfluidic system can include a light source for generating an excitation light. The microfluidic system can also include a microscope having an objective for focusing the excitation light on a fluid inside a microfluidic channel of a microfluidic chip. Further, the microfluidic system can include a detector for rejecting out-of-focus light emitted from the microfluidic chip.

Abstract: Apparatus and Method for Handling Fluids at Nano-Scale Rates. A linear displacement pump produces non-pulsatile liquid flow rates as low as the nl/mm range. The pump includes a servo motor, a gear reduction, a lead screw, a linear stage, a barrel, and a plunger extending into the barrel and coupled to the stage. A microfluidic interconnect device can be coupled to the barrel. One or more of these pumps can be disposed in a thermally controlled pump assembly that includes a pump housing, a thermally conductive body disposed in the housing and including first and second opposing sides, and a temperature regulating element such as a thermoelectric device disposed in thermal contact with the thermally conductive body on a side thereof opposite to the barrel or barrels of the pumps.

Abstract: The pumps (Pn) are operated to transport individual reagent streams into the chip in a non-pulsatile, laminar flow regime at low flow rates permitting lows grading from 0 to as little as 5 nl/min with a precision of 0.1 nl/min. In the chip (MFC), the reagent streams are merged and the reagents mixed to form a reaction product. The reaction product can be measured at one or more detection points defined in the chip. Concentration gradients are continuously varied by continuously varying the flow rates respectively produced by the pumps according to predetermined flow velocity profiles.