Abstract: A method is provided for pumping fluid through a channel of a microfluidic device. The channel has an input port and an output port. The channel is filled with fluid and a pressure gradient is generated between the fluid at the input port and the fluid at the output port. As a result, fluid flows through the channel towards the output port.

Abstract: A method is provided for collecting a concentration of particles from a sample fluid containing the particles. The method includes the steps of providing a microfluidic device. The microfluidic device includes an input channel, an output channel and a collection region. The input channel has an input end and an output end. The output channel has an input end and an output end. The collection region interconnects the output end of the input channel and the input end of the output channel. The sample fluid flows through the input channel and the output channel at a first velocity and through the collection region at a second velocity less than the first velocity such that the particles collect in therein.

Abstract: A device and method are provided for facilitating extraction of a fraction from a biological sample. The biological sample includes non-desired material and a fraction-bound solid phase substrate. The device includes an input zone for receiving the biological sample therein and a phase-gate zone for receiving an isolation buffer therein. An output zone receives a reagent therein. A force is movable between a first position adjacent the input zone and a second position adjacent the output zone. The force urges the fraction-bound solid phase substrate from the input zone, through the phase-gate zone and into the output zone.

Abstract: A device and method are provided for facilitating extraction of a fraction from a biological sample. The biological sample includes non-desired material and a fraction-bound solid phase substrate. The device includes an input zone for receiving the biological sample therein and a phase-gate zone for receiving an isolation buffer therein. An output zone receives a reagent therein. A force is movable between a first position adjacent the input zone and a second position adjacent the output zone. The force urges the fraction-bound solid phase substrate from the input zone, through the phase-gate zone and into the output zone.

Abstract: The present invention provides liquid crystal-based devices and methods for bioagent detection. In certain aspects, the present invention is directed to devices and methods utilizing liquid crystals and membranes containing polymerized targets that can report the presence of bioagents including, but not limited to, enzymes, antibodies, and toxins.

Abstract: A bladder arrangement is provided for a microneedle-based drug delivery device. The bladder arrangement includes a flexible membrane having an inner surface, an outer surface and an outer periphery. A bladder member, having a rigidity greater than the flexible membrane, includes an inner surface, an outer surface and an outer periphery. The inner surface of the flexible membrane and the inner surface of the bladder member define a chamber for receiving a drug therein. At least one microneedle is operatively connected to the bladder member. The at least one microneedle has an input and an output receivable within the individual. A valve operatively connects the input of the at least one microneedle and the chamber.

Abstract: A variable-focus lens assembly is provided. The lens assembly includes a microfluidic device that defines a chamber for receiving a fluid therein. A slip having an aperture therethrough is disposed in the chamber. A first fluid is disposed on the first side of the slip and a second fluid is disposed on the second side of the slip. A lens is formed from the interface of the first and second fluids. The outer periphery is pinned to the slip about the aperture. A turning structure fabricated from a hydrogel material engages the slip and tunes the focal length of the lens in response to a predetermined stimulus.

Abstract: The present invention provides liquid crystal-based devices and methods for bioagent detection. In certain aspects, the present invention is directed to devices and methods utilizing liquid crystals and membranes containing polymerized targets that can report the presence of bioagents including, but not limited to, enzymes, antibodies, and toxins.

Abstract: An active microneedle array and method are provided for penetrating an outer layer of the epidermis. The active microneedle array includes a base having first and second sides. The first side of the base is engageable with the epidermis. A microneedle projects from the first side of the base. The microneedle is moveable between a first initial configuration and a second deformed configuration in response to engagement with the epidermis so as to form a passageway therein.

Abstract: A method is provided for pumping fluid through a channel of a microfluidic device. The channel has an input port and an output port. The channel is filled with fluid and a pressure gradient is generated between the fluid at the input port and the fluid at the output port. As a result, fluid flows through the channel towards the output port.

Abstract: A microfluidic device is provided for delivering a drug to an individual. The microfluidic device includes a body that defines a reservoir for receiving the drug therein. A valve interconnects the reservoir to an output needle that is insertable into the skin of an individual. A pressure source urges the drug from the reservoir toward the needle. The valve is movable between a closed position preventing the flow of the drug from the reservoir to the output needle and an open position allowing for the flow of the drug from the reservoir to the output needle in response to a predetermined condition in the physiological fluids of the individual.

Abstract: A device and method for conducting peristaltic pumping of a fluid in a body is provided. The body includes a channel having an input and an output and being partially defined by a flexible layer. A plurality of contacts are spaced along the layer and the channel is filled with the fluid. The plurality of spaced contacts is magnetically coupled to a magnetic field in sequence so as to translate peristaltic motion to the layer thereby pumping the fluid through the channel.

Abstract: Microfluidic systems and methods. A microfluidic device for in vitro fertilization comprises a substrate and a plurality of microchannels disposed in the substrate, including an inlet of at least two of the plurality of microchannels arranged on the substrate to align with a fluid-handling device. Another microfluidic system for assaying a plurality of cells comprises a substrate and a plurality of microfluidic channels comprising a source channel, a sink channel, and a cell chamber. An insert for a microfluidic system comprises a substrate configured to be inserted into a dish and a plurality of microscale wells disposed in the substrate. A microfluidic channel comprises a substrate and at least one microchannel having an open inlet, an open outlet, a channel, and an opening in the substrate disposed over a portion of the channel.

Abstract: A microfluidic device is provided for delivering a drug to an individual. The microfluidic device includes a body that defines a reservoir for receiving the drug therein. A valve interconnects the reservoir to an output needle that is insertable into the skin of an individual. A pressure source urges the drug from the reservoir toward the needle. The valve is movable between a closed position preventing the flow of the drug from the reservoir to the output needle and an open position allowing for the flow of the drug from the reservoir to the output needle in response to a predetermined condition in the physiological fluids of the individual.

Abstract: A biological work station for culturing and monitoring cells includes a laminar flow bench and an incubator disposed on the bench. The bench includes a work surface adjacent the incubator that allows experiments and other manipulations to be performed within the confines of the laminar flow bench. An imaging system, such as a stereoscope, may be mounted to the bench so that images may be captured of a culture without removal of the culture from the incubator.

Abstract: A detection device is provided for detecting the presence of an agent in a fluid. The device includes a body defining first and second chambers. It is intended for the first chamber accommodating the flow of fluid therein. A first valve is disposed in the body between in the first and second chambers. The first valve opens in response to the presence of the agent in the fluid. A first detection structure is disposed in the second chamber in order to generate a predetermined signal in response to exposure to the fluid.

Abstract: A platform and method for mimicking the environment within a cell is provided. The platform includes a microfluidic device defining a chamber. At least one hydrogel post is positioned within the chamber of the microfluidic device. Each hydrogel post defines a corresponding pore for receiving a first molecule therein. Second molecules are introduced into the pores of the hydrogel posts and the interactions between the first and second molecules are observed.

Abstract: A drug delivery platform is provided for delivering a controlled infusion of a drug to an individual. The drug delivery platform includes a reservoir for receiving the drug therein and a hydrogel engageable with the reservoir. The hydrogel is movable between a first configuration and a second configuration wherein the hydrogel exerts a pressure on the reservoir to urge the drug therefrom in response to a predetermined stimulus. A flow guide distributes the predetermined stimulus over the hydrogel in response to activation by an individual.

Abstract: A method is provided of generating a gradient within gel matrix received in a channel of a microfluidic device. A source reservoir in communication with the input of the channel is filled with a first fluid. A sink reservoir in communication with the output of the channel is filled with a second fluid. A soluble factor is deposited in the source reservoir such that the soluble factor diffuses into the channel and forms the gradient. The soluble factor in source reservoir is replenished to maintain the gradient in a generally pseudo-steady state and the second fluid in the sink reservoir is replaced.

Abstract: A drug delivery platform is provided for delivering a controlled infusion of a drug to an individual. The drug delivery platform includes a reservoir for receiving the drug therein and a pressure source engageable with the reservoir. The pressure source is movable between a first configuration and a second configuration wherein the pressure source exerts a pressure on the reservoir to urge the drug therefrom. An output conduit is provided for transmitting the drug into the individual. An actuation mechanism is operatively connected to the pressure source and the output conduit. The actuation mechanism is movable between a non-actuated position and an actuated position wherein pressure source moves from the first configuration to the second configuration and wherein the input of the output conduit communicates with the drug and the output end of the output conduit is receivable in the individual.