Abstract: Methods and devices that include the use of venting elements for enhancing bonded substrate yields and regulating temperature. Venting elements are generally fabricated proximal to functionalized regions in substrate surfaces to prevent bond voids that form during bonding processes from affecting the functionalized regions. Venting elements generally include venting channels or networks of channels and/or venting cavities.

Abstract: A microfluidic system and method for employing it to control fluid temperatures of fluids residing within microchannels of a microfluidic device. The microfluidic device is provided with a top layer and a bottom layer and microchannels configured therebetween. Temperature of the fluid within the microchannels is controlled in various ways including the use of electrical resistive heating elements and by providing zones located in contact with the top and bottom layers of the microfluidic device for circulating heat transfer of fluid therein.

Abstract: Methods and devices for inducing high bulk hydrodynamic resistance and/or for inducing low electrical resistance in microscale systems including bulk viscosity enhancers, surfactants, and electrolytes. High bulk hydrodynamic resistance is optionally utilized to regulate the effects of spontaneous injection and/or dispersion. Induced high hydrodynamic resistance in conjunction with induced low electrical resistance are optionally utilized to provide and regulate electrical fields within microfluidic devices. Integrated systems incorporating the methods of the invention are also provided.

Abstract: Microfluidic devices, systems and methods that are operated and/or configured to enhance the passage of electrical current from power supplies to the fluids within the system. The devices, methods and systems utilize alternate electrode and system configurations to permit transfer of current at lower voltages, minimize water hydrolysis at the electrode/fluid interface and/or permit accurate in situ measurement of the parameters of processes carried out in those devices and systems.

Abstract: Methods and devices for inducing high bulk hydrodynamic resistance and/or for inducing low electrical resistance in microscale systems including bulk viscosity enhancers, surfactants, and electrolytes. High bulk hydrodynamic resistance is optionally utilized to regulate the effects of spontaneous injection and/or dispersion. Induced high hydrodynamic resistance in conjunction with induced low electrical resistance are optionally utilized to provide and regulate electrical fields within microfluidic devices. Integrated systems incorporating the methods of the invention are also provided.

Abstract: Methods and devices that include the use of venting elements for enhancing bonded substrate yields and regulating temperature. Venting elements are generally fabricated proximal to functionalized regions in substrate surfaces to prevent bond voids that form during bonding processes from affecting the functionalized regions. Venting elements generally include venting channels or networks of channels and/or venting cavities.