Abstract: A substantially leak-free, sealable microvalve that can be repeatedly opened and sealed is presented. The resealable microvalve includes a block with a through via and a sealing plate. The gap between the block and the sealing plate is sealed by a sealing material. The sealing material can be melted when heat is applied and can be solidified when heat is absent. To close the resealable microvalve, heat is applied by flowing a current through a resistive heater and an actuator brings the block and the sealing plate into a contacting position. By removing the heat, the sealing material is solidified and creates a sealed state. To open the resealable microvalve, heat is applied to the sealing material. When the sealing material melts, the actuator moves the block and the sealing plate into a spaced apart position.

Abstract: A microvalve device is provided that includes a through via located in an island structure supported on a thermally-insulating membrane supported by a frame. The through via is surrounded by a meltable sealing material. A heater element is positioned on the island structure for sealing the material over the through via by heating the sealing material.

Abstract: A method of forming 3D engineered tissues by providing a 2D scaffold material comprising a plurality of fold locations and a plurality of cell assembly sites, assembling cells into the cell assembly sites and folding the 2D scaffold material along the fold locations to form a 3D scaffold structure. Tissues formed by the method.

Abstract: A substantially leak-free, sealable microvalve that can be repeatedly opened and sealed is presented. The resealable microvalve includes a block with a through via and a sealing plate. The gap between the block and the sealing plate is sealed by a sealing material. The sealing material can be melted when heat is applied and can be solidified when heat is absent. To close the resealable microvalve, heat is applied by flowing a current through a resistive heater and an actuator brings the block and the sealing plate into a contacting position. By removing the heat, the sealing material is solidified and creates a sealed state. To open the resealable microvalve, heat is applied to the sealing material. When the sealing material melts, the actuator moves the block and the sealing plate into a spaced apart position.

Abstract: The present disclosure introduces new multi-functional vibrating devices, methods of using the devices, and methods of manufacturing the devices. A multi-functional vibrating device can include one or more actuators, each paired with an amplifier capable of converting small lateral vibration into large vertical vibration. The present disclosure also involves interactive information acquisition technologies and assistive technologies, particularly devices, methods, and systems for tactile information transfer and acquisition. Some embodiments incorporate multi-functional vibrational devices, methods, and systems to achieve unique structural and operational characteristics—such as high-resolution, robustness, versatility, compactness, and/or rapid refresh rates—for communicating information. Some embodiments can convert information from a format that is less convenient and/or accessible in some cases (e.g., visual or audio) to an intuitive and/or private format (e.g., tactile patterns and motions).

Abstract: Energy harvester. The harvester includes a radially extending beam having a proximal end mounted a selected distance from an axis of rotation of an object and includes a mass at its distal end. The mass, beam characteristics, and the selected distance are chosen so that the beam resonant frequency during rotation of the object substantially matches the driven rotational frequency of the object.

Abstract: A microvalve device is provided that includes a through via located in an island structure supported on a thermally-insulating membrane supported by a frame. The through via is surrounded by a meltable sealing material. A heater element is positioned on the island structure for sealing the material over the through via by heating the sealing material.

Abstract: An energy storage device includes at least one nanotube. An energy storage mechanism converts energy external to the device into the appropriate levels of strain on the at least one nanotube to produce stored energy, and an energy recovery mechanism converts the energy released by relaxing the at least one nanotube back to energy external to the device.

Abstract: An energy storage device includes at least one nanotube. An energy storage mechanism converts energy external to the device into the appropriate levels of strain on the at least one nanotube to produce stored energy, and an energy recovery mechanism converts the energy released by relaxing the at least one nanotube back to energy external to the device.