Abstract: A magnetic-hydrodynamic force fluid logic controller is provide that includes a solid or flexible or flexible substrate, a fluid chamber disposed above the substrate, where the chamber includes a fluid under test that includes an active magnet, where the active magnet is disposed to control a magnetic north pole of the droplet and a magnetic south pole of the droplet, a two-dimensional distribution of magnetic elements a surface the solid or flexible substrate, where the magnetic elements comprise a magnetization in a magnetic north pole and magnetization in a magnetic south pole, where the magnetic elements are activated by an external magnetic field of the active magnet, where the droplets have a droplet magnetization, where the droplet magnetization is configured for droplet self-interaction by the magnetic elements and the active magnet, where the self-interaction comprises splitting, merging, propagation, logic, storage, memory and all possible combinations of logical circuit operations.

Abstract: A magnetohydrodynamic force fluid logic controller is provided including a solid substrate, a fluid chamber disposed above the substrate, containing a fluid under test. It also includes an active magnet such that the active magnet is disposed to control north and south poles on the fluid under test or on the carrier fluid and a two-dimensional distribution of magnetized domains disposed on a surface of the solid substrate. The magnetized domains have poles activated by the above the active magnet, where the different parts of the above the fluid under test self-interact and split, merge or propagate along different directions on the above the substrate subject to their placement on the magnetized domains, whereby the active magnet regulates the self-interaction. The results of the self-interactions are equivalent to physical binary logic operations where “1” is the presence and “0” is the absence of a fluidic volume at a given location.

Abstract: Fluid-based no-moving part logic devices are constructed from complex sequences of micro- and nanofluidic channels, on-demand bubble/droplet modulators and generators for programming the devices, and micro- and nanofluidic droplet/bubble memory elements for storage and retrieval of biological or chemical elements. The input sequence of bubbles/droplets encodes information, with the output being another sequence of bubbles/droplets or on-chip chemical synthesis. For performing a set of reactions/tasks or process control, the modulators can be used to program the device by producing a precisely timed sequence of bubbles/droplets, resulting in a cascade of logic operations within the micro- or nanofluidic channel sequence, utilizing the generated droplets/bubbles as a control. The devices are based on the principle of minimum energy interfaces formed between the two fluid phases enclosed inside precise channel geometries.

Abstract: Fluid-based no-moving part logic devices are constructed from complex sequences of micro- and nanofluidic channels, on-demand bubble/droplet modulators and generators for programming the devices, and micro- and nanofluidic droplet/bubble memory elements for storage and retrieval of biological or chemical elements. The input sequence of bubbles/droplets encodes information, with the output being another sequence of bubbles/droplets or on-chip chemical synthesis. For performing a set of reactions/tasks or process control, the modulators can be used to program the device by producing a precisely timed sequence of bubbles/droplets, resulting in a cascade of logic operations within the micro- or nanofluidic channel sequence, utilizing the generated droplets/bubbles as a control. The devices are based on the principle of minimum energy interfaces formed between the two fluid phases enclosed inside precise channel geometries.

Abstract: Optical lenses and methods for manufacturing optical lenses are disclosed herein. Lenses having a reduced aperture size are also disclosed herein along with methods for making the same. The optical lenses disclosed herein can be made having improved optical properties. The lenses can be used in optical microscopes, including optical microscopes with a shorter optical path relative to conventional optical microscopes.

Abstract: A magnetic trap droplet controller is provided that includes a solid substrate, a controller operated by an appropriately programmed computer, a two-dimensional distribution of magnetized domains disposed on a surface of the solid substrate, a fluid chamber disposed above the two-dimensional distribution of magnetized domains, and an active magnet, where the active magnet is disposed to provide a dynamic magnetic field in-plane with the solid substrate, where the dynamic magnetic field controls north and south poles of the two-dimensional distribution of magnetized domains according to the controller, where a fluid under test that is disposed in a carrier fluid that is disposed in the fluid chamber propagates according to the controlled north and south poles of the two-dimensional distribution of the magnetized domains.

Abstract: Devices and methods for insect surveillance are disclosed. In particular, the invention relates to devices for collecting samples of salivary fluid from insects and multiplexed high-throughput methods of screening insect samples for specific insect species, genetically modified strains, and insect-borne pathogens. An attractant is used to induce insects to deposit salivary droplets in a 2-dimensional microfluidic array having media-filled pockets sized to collect saliva from a single insect. The array for sample collection can be integrated with a microfluidic device for high-throughput processing of insect samples. The microfluidic device can be designed to perform multiplexed PCR or immunoassays, for example, for insect genotyping or pathogen detection.

Abstract: Techniques are provided for a completely programmable fluidic manipulation without requiring any external control elements or electricity. A chip includes multiple microfluidic channels separated from an outside of the chip by an outer flexible substrate. An apparatus includes a plurality of actuators rotatably connected to a support structure with a recess for receiving the chip. Each actuator includes a plurality of teeth protruding outward, and is positioned so that at least in some angle of rotation a tooth of the actuator extends sufficiently into the recess to compress a microfluidic channel in a chip disposed in the recess. An optional punch card guide is included for guiding a card to contact the actuators. A system or kit includes a punch card on which is formed a plurality of punch features, each configured to engage a tooth of an actuator. Different microfluidic protocols are executed by simply changing the punch card.

Abstract: A method, system and apparatus for imaging an oral cavity of a subject include a bracket comprising a mouthpiece and a camera mount. The mouthpiece has upper and lower bite guides disposed on a posterior side and separated by an opening through the mouthpiece. The bite guides are spaced apart so a subject biting on the guides opens the oral cavity to inspection through the opening. The mount is disposed on an anterior side of the mouthpiece; and has a flange to engage and slide along the opening and an optical path for light to pass through the mount and mouthpiece. A clip on an anterior side of the mount is configured to removeably hold a camera to record light passing through the optical path from the posterior side of the mount. In one embodiment, the camera is a programmable cell phone with digital camera.

Abstract: Fluid-based no-moving part logic devices are constructed from complex sequences of micro- and nanofluidic channels, on-demand bubble/droplet modulators and generators for programming the devices, and micro- and nanofluidic droplet/bubble memory elements for storage and retrieval of biological or chemical elements. The input sequence of bubbles/droplets encodes information, with the output being another sequence of bubbles/droplets or on-chip chemical synthesis. For performing a set of reactions/tasks or process control, the modulators can be used to program the device by producing a precisely timed sequence of bubbles/droplets, resulting in a cascade of logic operations within the micro- or nanofluidic channel sequence, utilizing the generated droplets/bubbles as a control. The devices are based on the principle of minimum energy interfaces formed between the two fluid phases enclosed inside precise channel geometries.

Abstract: An optical device, such as a microscope, is disclosed that can be assembled from flat materials. The optical device can be assembled via a series of folds of a flat material. The optical microscope can include a stage for supporting a sample, an optic stage, and a light source. The optic stage can include one or more lenses. The optical microscope can be capable of obtaining simultaneous images from different forms of microscopy. The optical microscope may have bright field and filter field viewing capabilities wherein a user shifts from bright field to filter field by lateral movement of the stage containing a lens and a light source that cooperate to provide either the bright field or the filter field.

Abstract: Fluid-based no-moving part logic devices are constructed from complex sequences of micro- and nanofluidic channels, on-demand bubble/droplet modulators and generators for programming the devices, and micro- and nanofluidic droplet/bubble memory elements for storage and retrieval of biological or chemical elements. The input sequence of bubbles/droplets encodes information, with the output being another sequence of bubbles/droplets or on-chip chemical synthesis. For performing a set of reactions/tasks or process control, the modulators can be used to program the device by producing a precisely timed sequence of bubbles/droplets, resulting in a cascade of logic operations within the micro- or nanofluidic channel sequence, utilizing the generated droplets/bubbles as a control. The devices are based on the principle of minimum energy interfaces formed between the two fluid phases enclosed inside precise channel geometries.

Abstract: A method for implementing a logic operation employs an all fluid-based no-moving part micro-mechanical logic family of microfluidic bubble logic devices that are constructed from complex sequences of microfluidic channels, microfluidic bubble modulators for programming the devices, and microfluidic droplet/bubble memory elements for chemical storage and retrieval. The input is a sequence of bubbles/droplets encoding information, with the output being another sequence of bubbles/droplets. For performing a set of reactions/tasks, the modulators program the device by producing a precisely timed sequence of bubbles/droplets, resulting in a cascade of logic operations within the microfluidic channel sequence, utilizing the generated bubbles as a control. The devices are based on the principle of minimum energy interfaces formed between the two fluid phases enclosed inside precise channel geometries.

Abstract: A method, system and apparatus for imaging an oral cavity of a subject include a bracket comprising a mouthpiece and a camera mount. The mouthpiece has upper and lower bite guides disposed on a posterior side and separated by an opening through the mouthpiece. The bite guides are spaced apart so a subject biting on the guides opens the oral cavity to inspection through the opening. The mount is disposed on an anterior side of the mouthpiece; and has a flange to engage and slide along the opening and an optical path for light to pass through the mount and mouthpiece. A clip on an anterior side of the mount is configured to removeably hold a camera to record light passing through the optical path from the posterior side of the mount. In one embodiment, the camera is a programmable cell phone with digital camera.

Abstract: Fluid-based no-moving part logic devices are constructed from complex sequences of micro- and nanofluidic channels, on-demand bubble/droplet modulators and generators for programming the devices, and micro- and nanofluidic droplet/bubble memory elements for storage and retrieval of biological or chemical elements. The input sequence of bubbles/droplets encodes information, with the output being another sequence of bubbles/droplets or on-chip chemical synthesis. For performing a set of reactions/tasks or process control, the modulators can be used to program the device by producing a precisely timed sequence of bubbles/droplets, resulting in a cascade of logic operations within the micro- or nanofluidic channel sequence, utilizing the generated droplets/bubbles as a control. The devices are based on the principle of minimum energy interfaces formed between the two fluid phases enclosed inside precise channel geometries.

Abstract: This invention provides devices and apparatuses comprising the same and methods of use thereof for efficient pumping and/or mixing of relatively small volumes of fluid, wherein the fluid contains a sample within an inner fluid phase dispersed in an outer phase. Such devices utilize nonlinear electrokinetics as a primary mechanism for driving fluid flow and/or mixing the fluid. Methods of cellular analysis, drug delivery and others, utilizing the devices are described.

Abstract: Fluid-based no-moving part logic devices are constructed from complex sequences of micro- and nanofluidic channels, on-demand bubble/droplet modulators and generators for programming the devices, and micro- and nanofluidic droplet/bubble memory elements for storage and retrieval of biological or chemical elements. The input sequence of bubbles/droplets encodes information, with the output being another sequence of bubbles/droplets or on-chip chemical synthesis. For performing a set of reactions/tasks or process control, the modulators can be used to program the device by producing a precisely timed sequence of bubbles/droplets, resulting in a cascade of logic operations within the micro- or nanofluidic channel sequence, utilizing the generated droplets/bubbles as a control. The devices are based on the principle of minimum energy interfaces formed between the two fluid phases enclosed inside precise channel geometries.

Abstract: In exemplary implementations of this invention, hydrothermal synthesis of zinc oxide nanowires is morphologically controlled. Metal complex ions are used to suppress growth in a face-selective manner, by electrostatic crystal growth inhibition. This permits the aspect ratio (height/diameter) of the nanowires to be dynamically tuned over a wide range, from needle-like nanowires that are efficient field emitters to flattened nanowires with a platelet-like shape. The nanowire synthesis is all inorganic and occurs at low temperatures (e.g., <=60° C.). The growth inhibition may be predictively modeled, using speciation plots and treating non-zinc complex ions as ligands. Microfluidic channels may be used for the synthesis, with different solutions flowing down different channels, permitting nanowires with different properties to be synthesized in parallel.

Abstract: A method for implementing a logic operation employs an all fluid-based no-moving part micro-mechanical logic family of microfluidic bubble logic devices that are constructed from complex sequences of microfluidic channels, microfluidic bubble modulators for programming the devices, and microfluidic droplet/bubble memory elements for chemical storage and retrieval. The input is a sequence of bubbles/droplets encoding information, with the output being another sequence of bubbles/droplets. For performing a set of reactions/tasks, the modulators program the device by producing a precisely timed sequence of bubbles/droplets, resulting in a cascade of logic operations within the microfluidic channel sequence, utilizing the generated bubbles as a control. The devices are based on the principle of minimum energy interfaces formed between the two fluid phases enclosed inside precise channel geometries.

Abstract: A method for implementing a logic operation employs an all fluid-based no-moving part micro-mechanical logic family of microfluidic bubble logic devices that are constructed from complex sequences of microfluidic channels, microfluidic bubble modulators for programming the devices, and microfluidic droplet/bubble memory elements for chemical storage and retrieval. The input is a sequence of bubbles/droplets encoding information, with the output being another sequence of bubbles/droplets. For performing a set of reactions/tasks, the modulators program the device by producing a precisely timed sequence of bubbles/droplets, resulting in a cascade of logic operations within the microfluidic channel sequence, utilizing the generated bubbles as a control. The devices are based on the principle of minimum energy interfaces formed between the two fluid phases enclosed inside precise channel geometries.