Abstract: A microfluidic device for modeling a tumor-immune microenvironment can include a multiwell plate defining a plurality of microenvironment units fluidically coupled with a plurality of wells. Each microenvironment unit of the plurality of microenvironment units can include one or more compartments. Each microenvironment unit can include a trapping feature positioned within the one or more compartments. The trapping feature can be defined by a portion of at least one of a sidewall or a floor of the one or more compartments. The trapping feature can restrict movement of a tissue sample introduced into the one or more compartments and to allow fluid to flow past the tissue sample. The microfluidic device can include a plurality of micropumps each coupled with a respective well and configured to control movement of a respective fluid sample through each respective well.

Abstract: A method for generating a cell support interface for use in a three dimensional cell culture environment, may include electrospinning a mat having an epithelial support layer configured to create an intimate coupling between the epithelial cell and a porous matrix, including a first layer and a second layer, wherein the first layer is formed using a first solution at a first viscosity level and the second layer is formed using a second solution at a second viscosity level different from the first viscosity level.

Abstract: This disclosure provides systems and methods for seeding cell cultures in a microfluidic device. The systems and methods of this disclosure can enable flow of a cell solution from one side of a scaffold, such as a porous substrate or membrane, to the other side of the scaffold. Flow of the liquid can pass through the scaffold while the cells themselves do not, resulting in the cells driven to the surface of the scaffold for consequent attachment. A microfluidic device can include a microfluidic feature structured to create a seal between a cell seeding tool and an inlet to a microchannel of the microfluidic device. This can enable a pressure-driven flow to push fluid down the channel and through pores of the membrane. In contrast, traditional gravity fed seeding of cells may not create enough pressure to drive fluid through the pores of the scaffold.

Abstract: A method for manufacturing a microfluidic device can include providing a base component to define a first portion of the microfluidic device. A cap component of the microfluidic device can be fabricated with a sealing lip extending a first distance from a first side of the cap component and a support portion extending a second distance, less than the first distance, from the first side of the cap component. The method can include positioning the cap component and the base component within a mold to bring the sealing lip of the cap component in contact with the base component. The base component, the support portion of the cap component, and the sealing lip of the cap component together can define a cavity. The method can include injecting a polymer material into the mold to cause the polymer material to fill the cavity.

Abstract: Devices for treatment of cells are disclosed. The devices include an elongated housing and at least one hollow fiber semi-permeable membrane positioned within the housing having a plurality of pores dimensioned to prevent passage of the cells to be treated. Systems for treatment of cells including the device are disclosed. Methods of treating cells, including transducing cells and activating cells, are also disclosed. The methods include introducing a biosample with cells to be treated into the device, introducing media to suspend and release treated cells into the device, and discharging the treated cells from the device.

Abstract: A microchannel cell culture device is disclosed. The microchannel cell culture device includes a well plate defining an array of tissue modeling environments. A cell culture system including the microchannel cell culture device is also disclosed. The cell culture system includes a plurality of optical sensors, a platform, and a light source. A method of high throughput screening cell biological activity with the microchannel cell culture device is disclosed. A method of measuring oxygen consumption rate of cells in the microchannel cell culture device is disclosed. A method of facilitating drug development with the microchannel cell culture device is also disclosed.

Abstract: The present disclosure describes systems and methods for providing culturing of a number of various tissue types in an air-liquid configuration in a high-throughput format and allowing co-culture of cells as well as application of physiologically relevant flow. A microfluidic cell culturing device is provided that includes a first channel having a first inlet port and a second inlet port, the first channel defined in a first layer. The microfluidic cell culturing device includes a membrane layer having a first surface coupled to the first layer defining the first channel, the membrane layer comprising semipermeable membrane that forms at least a portion of a surface of the first channel. The microfluidic cell culturing device includes a chamber defined in a second layer that exposes a portion the membrane layer to an external environment, wherein the chamber overlaps a portion of the first channel across the membrane layer.

Abstract: A microfluidic device for modeling a tumor-immune microenvironment can include a multiwell plate defining a plurality of microenvironment units fluidically coupled with a plurality of wells. Each microenvironment unit of the plurality of microenvironment units can include one or more compartments. Each microenvironment unit can include a trapping feature positioned within the one or more compartments. The trapping feature can be defined by a portion of at least one of a sidewall or a floor of the one or more compartments. The trapping feature can restrict movement of a tissue sample introduced into the one or more compartments and to allow fluid to flow past the tissue sample. The microfluidic device can include a plurality of micropumps each coupled with a respective well and configured to control movement of a respective fluid sample through each respective well.

Abstract: A method for manufacturing a microfluidic device can include providing a base component to define a first portion of the microfluidic device. A cap component of the microfluidic device can be fabricated with a sealing lip extending a first distance from a first side of the cap component and a support portion extending a second distance, less than the first distance, from the first side of the cap component. The method can include positioning the cap component and the base component within a mold to bring the sealing lip of the cap component in contact with the base component. The base component, the support portion of the cap component, and the sealing lip of the cap component together can define a cavity. The method can include injecting a polymer material into the mold to cause the polymer material to fill the cavity.

Abstract: This disclosure provides systems and methods for seeding cell cultures in a microfluidic device. The systems and methods of this disclosure can enable flow of a cell solution from one side of a scaffold, such as a porous substrate or membrane, to the other side of the scaffold. Flow of the liquid can pass through the scaffold while the cells themselves do not, resulting in the cells driven to the surface of the scaffold for consequent attachment. A microfluidic device can include a microfluidic feature structured to create a seal between a cell seeding tool and an inlet to a microchannel of the microfluidic device. This can enable a pressure-driven flow to push fluid down the channel and through pores of the membrane. In contrast, traditional gravity fed seeding of cells may not create enough pressure to drive fluid through the pores of the scaffold.

Abstract: This disclosure provides systems and methods for integrating an array of electronic sensors capable of performing trans-epithelial electrical resistance (TEER) measurements into a microfluidic device that includes a well plate. In some implementations, the sensors can include electrodes that are submerged into fluidically connected wells of the microfluidic device, which can contain an electrically conductive fluid such as the cell culture media or a buffered salt solution. An array of such electrodes can be integrated into a lid of the system that includes the microfluidic device. These electrodes can be routed using a printed circuit board through a number of multiplex switches that can allow addressing of a desired unit of the device through a microprocessor in communication with a computer.

Abstract: A multiplex-able, regeneratable nucleic-acid linked immunoassay method and system for the detection of a single specific, or multiple, soluble analytes in solution and regeneratable biosensor devices for same are described.

Abstract: A multiplex-able, regeneratable nucleic-acid linked immunoassay method and system for the detection of a single specific, or multiple, soluble analytes in solution and regeneratable biosensor devices for same are described.

Abstract: Described herein are systems, devices, and methods for the delivery of substances to, or the sampling of substances from, a patient using a portable and preferably implantable device. The substances introduced to and/or taken from the patient are preferably fluidic and are driven by a miniature pump, such as a microimpedance pump. A number of design variations are explicitly and implicitly described, such as the use of multiple pumps and multiple reservoirs for containing medicaments. Methods of manufacture of these systems and devices are also described, for instance, using molding, micromachining, or lithographic processes.

Abstract: Systems, devices, and methods are provided for drug-eluting angioplasty balloons. An underlying balloon core member is protected by a core-screen from mechanical and flow shear forces during delivery. Inflation of the balloon opens the screen and pores in the screen permitting drug transfer and absorption. Upon deflation, the screen can be compressed and withdrawn with the balloon.