Abstract: Embodiments of the invention are directed to methods and systems associated with a disposable dispenser (100, 200) of therapeutic fluid. Preferred embodiments having a small size of less than about 75 mm in length, less than 50 mm in width and less than about 10 mm in thickness and may be releasably attached to the body (B). In one embodiments, the dispenser draws fluid from a flexible volume-conformable reservoir (4) and operates a dosing and metering pump (6, 61, 62, 63) incorporating a motor to deliver fluid through a fluid delivery tool (8, 81, 82). Disposed on the housing bottom (2B) is a peel-of-tape (22) that when removed, electrically connects a power supply (18) to power the operative components (3) of the dispenser into operation, exposes an adhesive (28) and a window (21) opened in the housing (2), and allows the fluid delivery tool (8) to extend for insertion into the skin (S).

Abstract: The present invention provides a system and method for obtaining in vivo images. The system contains an imaging system and a transmitter for transmitting signals from a camera to a receiving system located outside a patient.

Abstract: A 3D camera for determining distances to regions in a scene wherein gating or modulating apparatus for the 3D camera is incorporated on a photosurface of the camera on which light detectors of the camera are also situated. Each pixel in the photosurface may include its own pixel circuit for gating the pixel on or off or for modulating the sensitivity of the pixel to incident light. The circuit may comprise at least one amplifier inside the pixel, at least one feedback capacitor separate from the light sensitive element and connected between the input and output of each of the at least one amplifier, and at least one controllable connection through which current flows from the light sensitive element into the input of the at least one amplifier. The 3D camera may further include a light source and a controller.

Abstract: A device and system for in-vivo sensing having a relatively heavy part and a relatively light part such that the heavy and light part may be temporarily attached in-vivo. Detachment of the heavy part may be provided at a predetermined location along a body lumen. The light part upon detachment of the heavy part may for example float within a body lumen.

Abstract: The present invention provides a system and method for obtaining in vivo images. The system contains an imaging system and a transmitter for transmitting signals from a camera to a receiving system located outside a patient.

Abstract: A system and method may display an image stream, where an original image stream may be divided into two or more subset images streams, each subset image stream being displayed simultaneously or substantially simultaneously. The images may be displayed fused. The images may be collected from an ingestible capsule traversing the GI tract.

Abstract: Embodiments of the invention are directed to methods and systems associated with a disposable dispenser (100, 200) of therapeutic fluid. Preferred embodiments having a small size of less than about 75 mm in length, less than 50 mm in width and less than about 10 mm in thickness and may be releasably attached to the body (B). In one embodiments, the dispenser draws fluid from a flexible volume-conformable reservoir (4) and operates a dosing and metering pump (6, 61, 62, 63) incorporating a motor to deliver fluid through a fluid delivery tool (8, 81, 82). Disposed on the housing bottom (2B) is a peel-off tape (22) that when removed, electrically connects a power supply (18) to power the operative components (3) of the dispenser into operation, exposes an adhesive (28) and a window (21) in the housing (2), and allows the fluid delivery tool (8) to extend for insertion into the skin (S).

Abstract: A device and a method for implementing a photo-spectrometer unit (20), or PSU (20), for use with a spectrometry system (100) having optical means (12), and electronic means (13) is disclosed. The PSU is formed in a two-step manufacturing process to form a chip having a monolithic structure. The chip has a first surface and second surface. During the first manufacturing process step, optical means are integrally formed on the first surface (301), and during the second manufacturing process step, electronic means are formed on the second surface (302). The chip is transparent to electromagnetic radiations, and the PSU has at least one optical deflecting element (32) for guiding received radiations through the chip, for establishing direct optical path coupling between an optical element formed on the first surface and an electronic element formed on the second surface.

Abstract: A system and method may display an image stream, where an original image stream may be divided into two or more subset images streams, each subset image stream being displayed simultaneously or substantially simultaneously. The images may be displayed fused. The images may be collected from an ingestible capsule traversing the GI tract.

Abstract: An in-vivo device may include an optical system, and a method for viewing in-vivo sites. A dome or cover may cover an end of the device, protecting optical elements such as illumination devices or imagers, which may be behind the dome. The dome may be forward projecting. The field of view of the imager may be for example forward looking. Illumination element(s) and a receiving unit or imager may be disposed behind a single optical window, which for example may enable obtaining of images free of backscatter and stray light.

Abstract: Systems and methods for detecting an occlusion in a fluid delivery device are disclosed. The system includes a fluid delivery tube, an occlusion detection sensor configured to be coupled to the fluid delivery tube and further configured to detect occlusion within the fluid delivery tube. The fluid delivery tube includes an occlusion detection portion. The occlusion detection sensor is further configured to detect alteration of a shape of the occlusion detection portion when at least one condition occurs within the fluid delivery tube.

Abstract: Embodiments of the invention are directed to systems, methods and devices for sustained medical infusion with controlled rate injection of a fluid into a body. Such a system may include a first separate reusable unit, a second separate depletable unit a third separate disposable unit having a cannula, and may include a fourth separate remote control unit. Emission of appropriate instructions from the fourth unit, when the first unit, the second unit, and the third unit are coupled together in associative operation and disposed on the skin, power is supplied to an engine for generating motion to a fluid transfer system, and when the cannula is inserted in the body, fluid is transferred from the reservoir to the body, via the tube and the cannula.

Abstract: A system and method are described for the purpose of performing non invasive examination of the colon. The proposed method is based on an ingestible capsule incorporating ultrasonic transducer elements, control circuit and an external wireless power supply and data recorder. The recorded ultrasonic data is later processed and a virtual image of the lumen is generated for diagnostic purpose. The proposed method will not require prep and thus will be more patient friendly.

Abstract: An in vivo sensing device including an immobilizer that may immobilize the device in an in vivo location. The immobilizer may be activated by for example a processor or in response to an in vivo condition or in response to a signal from an outside operator.

Abstract: A device, system and method for in-vivo analysis. An autonomous in-vivo device may include a magnet to detain at least a portion of a sample collected from a body lumen; a sensor to sense a property of the detained sample portion; and a transmitter to transmit data of the sensed property.

Abstract: Embodiments of the invention are directed to systems, methods and devices for sustained medical infusion with controlled rate injection of a fluid into a body. Such a system may include a first separate reusable unit, a second separate depletable unit a third separate disposable unit having a cannula, and may include a fourth separate remote control unit. Emission of appropriate instructions from the fourth unit, when the first unit, the second unit, and the third unit are coupled together in associative operation and disposed on the skin, power is supplied to an engine for generating motion to a fluid transfer system, and when the cannula is inserted in the body, fluid is transferred from the reservoir to the body, via the tube and the cannula.

Abstract: Provided are a system and method for in vivo and in situ detection of body lumen conditions. The system comprises at least one interaction chamber for containing an endo-luminal sample, the interaction chamber comprising at least one indicator; at least one light source for illuminating the interaction chamber; and at least one optical detector for detecting in vivo optical changes occurring in the interaction chamber. The reaction between the indicator and sample may result in an optical change, which is detected and possibly imaged by the optical detector.

Abstract: The present invention provides a system and method for obtaining in vivo images. The system contains an imaging system and a transmitter for transmitting signals from a camera to a receiving system located outside a patient.

Abstract: A system for transfer of a signal, such as an energizing signal, to a transmitting in vivo sensing device. The in vivo device includes at least one signal transmitter and at least one signal receiving unit. The system includes an external phased array antenna. The phased array antenna receives a signal from the sensing device and then transmits a signal to the device phased in the reverse order to that of receipt the signal from the sensing device.

Abstract: A system for continuous monitoring of body analytes and controlling delivery of fluids to a body of a user. The system includes a sensing apparatus configured to detect concentration level of analyte in the body of the user using optical means and a dispensing apparatus configured to infuse fluid into the body of the user based on the detected concentration level of analyte.