Abstract: A device for cryotherapy treatment of gastrointestinal lesions includes a cooling member that may be attached to a first tube for pressurizing cryogenic fluid through the tube and into the cooling member through nozzles located at the distal end of the first tube. A second tube may be attached to the cooling member for evacuating the cryogenic fluid from within the cooling member, following the fluid's expansion once it exits the first tube. The cryotherapy device may be attached to an endoscope such that the first tube may be passed through the endoscope's working channel, while the second tube may be passed along the endoscope's circumference. The cryotherapy device may further comprise securing means attached to the first tube, for securing the first tube to the endoscope's working channel, thus preventing free rotation of the cryotherapy device within the endoscope, relative to the rotation of the endoscope.

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: 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 device, system and method for cytology acquisition which may be performed with a swallowable in vivo device, specifically with a swallowable endoscopy capsule. The swallowable capsule may comprise a rotatable drum, a brush attached onto the drum for brushing against a tissue and acquiring cytology, and a porthole through which the brush may be in contact with the tissue.

Abstract: A system for positioning of a naso/orogastric feeding tube. The system comprises an interface adapted to receive a combined impedance measure comprising a plurality of impedance readings from a plurality of impedance sensors disposed in a plurality of segments along a lateral surface of a naso/orogastric feeding tube; wherein one of the plurality of segments is located to be at least 1 centimeters above another of the plurality of segments when the naso/orogastric feeding tube is in a feeding position, a code store for storing a code, a processor coupled to the interface and the program store for implementing the stored code, the code comprising code to calculate an estimation of a position of the naso/orogastric feeding tube according to the combined impedance measure, and code to generate instructions for a caregiver to relocate the naso/orogastric feeding tube according to the estimation.

Abstract: There is provided a computer-implemented method for calculating a gastric emptying rate from a stomach lumen into a small intestine of a patient, comprising: using at least one processor for executing the following during an enteral tube feeding of a stomach of the patient by a feeding mechanism: analyzing outputs of at least one stomach sensor located within the stomach for detecting a stop feeding condition; pausing the enteral tube feeding in response to a detection of the stop feeding condition; after a predefined period of time, restarting the enteral tube feeding until the stop condition is redetected by an analysis of said outputs; calculating a gastric emptying rate based on an amount of feeding content delivered during a period between the restarting and the redetection; and instructing the feeding mechanism to adapt a feeding rate of the enteral tube feeding according to the gastric emptying rate.

Abstract: According to some embodiments of the present invention there are provided a method for calculating a volume of an individual falling drop of liquid by analyzing electromagnetic radiation (EMR) reception, the method comprising projecting electromagnetic radiation (EMR) from an EMR source, measuring the EMR using at least one EMR sensor when the EMR is partially interfered with by a drop falling between the EMR source and the EMR sensor, calculating a plurality of widths parallel to a vertical axis of the drop, each one of the plurality of widths is calculated according to a reception of a time correlated measured portion of the EMR, and calculating a volume of the drop by combining the plurality of widths and a velocity of the drop when the drop is falling between the EMR source and the EMR sensor.

Abstract: A system and method for determining location and orientation of an in-vivo device, with respect to an external system in which the device is located include a frame with external magnets attached thereon. An in-vivo device is inserted into the patient's body, which is placed within the system, and the external magnets apply magnetic forces on the in-vivo device. A radio beacon transmitter is attached to the frame for transmitting a radio pulse. The in-vivo device includes an ultrasonic transmitter for transmitting an ultrasonic signal, which is triggered by the radio pulse. At least three transponders are placed on the patient's body, each transponder sending a first acoustic signal triggered by the radio pulse, and each sending a second acoustic signal triggered by the device's ultrasonic signal.

Abstract: In-vivo medical devices, systems and methods of operating such devices include a permanent magnetic assembly interacting with external magnetic fields for magnetically maneuvering said device to a desired location along a patient's GI tract, and anchoring said devices to the desired location for a period of time. The in-vivo medical device includes illumination sources, an optical system, and an image sensor for imaging the GI tract and thus assisting in locating the desired location. Some in-vivo medical devices include a concave window, which enables better imaging of small areas along the tissue. Furthermore, in-vivo devices with a concave window enable carrying operating tools without damaging the tissue of the GI tract, since prior to operation, the tools protrude from the concave window but remain behind the ends of the edges of the concave window.

Abstract: Systems and methods for scanning an organ or other extended volumes of body tissue using one or more Optical Coherence Tomography (OCT) probes are presented. Some embodiments provide equipment for managing a plurality of OCT penetrations into a tissue or organ, and provide some or all of the following: detection and/or control of OCT probe positions and orientations (and optionally, that of other imaging modalities) detecting changes in body tissue positions, registering and mapping OCT scan results and optionally input from other imaging modalities, integrating OCT scan information and/or information from other modalities and/or recorded historical information, optionally some or all of the above with reference to a common coordinate system. Some embodiments comprise a display for displaying some or all of this information. In some embodiments, inferences based on observed portions of the organ relative to non-observed portions of an organ are displayed.

Abstract: A system and a method for delivering fluid to and sensing analyte levels in the body of the patient are disclosed. The system includes a dispensing apparatus configured to infuse fluid into the body of the patient and a sensing apparatus configured to be in communication with the dispensing apparatus and further configured to detect a level of analyte concentration in the body of the patient.

Abstract: Systems and methods for imaging within depth layers of a tissue include illuminating light rays at different changing wavelengths (frequencies), collimating illuminated light rays using a collimator, and splitting light rays using a beam splitter, such that some of the light rays are directed towards a reference mirror and some of the rays are directed towards the tissue. The systems and methods further include reflecting light rays from the reference mirror towards the imager, filtering out non-collimated light rays reflected off the tissue by using a telecentric optical system, and reflecting collimated light rays reflected off the tissue towards the imager, thus creating an image of an interference pattern based on collimated light rays reflected off the tissue and off the reference mirror. The method may further include creating full 2D images from the interference pattern for each depth layer of the tissue using Fast Fourier transform.

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: An in vivo capsule has a cauterization element that may be deployed by physician while in vivo for cauterizing a lesion, such as bleeding. Energy is transferred from outside of the patient's body to the capsule and specifically to the ablating element, such as via a resonance circuit. Accordingly, it is the object of the present invention to provide a method and apparatus for precisely cauterizing or ablating tissue in-vivo. Embodiments of the invention may provide an in-vivo device having a cauterization or ablation element incorporated therein and a system and method for controlled navigation of the in-vivo cauterization device through a body lumen.

Abstract: Fluid delivery devices and methods for delivering fluid to the body of the patient are disclosed which include a housing having an upper wall and a lower wall defining an opening, a well-arrangement mechanism configured to be disposed inside the housing and between the upper wall and the lower wall and including a tubular member having a bore, wherein the bore is configured to be disposed within the opening, a penetrating cartridge for delivery of therapeutic fluid to the body of the patient, wherein the penetrating cartridge is configured to engage the bore following its insertion through the upper opening and the lower opening, and a tilting tool configured to rotate the bore prior to insertion of the penetrating cartridge, wherein therapeutic fluid is configured to be delivered through the tubular member into the penetrating cartridge into the body of the patient when the penetrating cartridge engages the bore.

Abstract: One or more therapeutic fluids, such as for example insulin can be delivered to a body. In addition or alternatively, the concentrations of one or more analytes can be measured in vivo. A feedback process can be used to regulate levels of the one or more analytes based on the measurements via delivery of the one or more therapeutic fluids. Related systems, apparatus, methods, and/or articles are also described.

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: A feeding tube device for postpyloric feeding that comprises a bendable feeding tube having a proximal end, a central portion and, and a distal end and a delivery lumen therealong for conducting a digestible substance therethrough, an imaging unit having an image sensor mounted on a tip of the distal end to image an imaging space thereinfront, and a tilting mechanism for tilting the distal end in relation to the central portion. The distal end has at least one lateral tilt and feeding opening therealong for delivering the digestible substance therethrough, the at least one lateral tilt and feeding opening are laid out so that when the tilting mechanism tilts the distal end the at least one lateral tilt and feeding opening narrows.

Abstract: In-vivo devices, systems and methods for the detection of blood within in-vivo bodily fluids. The methods include irradiating in-vivo fluids passing through a gap in a housing of an in-vivo device introduced to the GI tract of a subject with a plurality of illumination sources positioned on a first side of a gap; detecting with at least one light detector positioned on the opposite side of the gap and facing the illumination sources, light irradiated by the illumination sources; transmitting a plurality of values representing the light detected over time; converting these values to blood concentration values over time, and comparing the blood concentration values to a predetermined threshold value. Based on the comparison, the method includes determining the type of bleeding profile, such that if a plurality of blood concentration values measured consecutively is above the threshold value, the bleeding profile indicates bleeding.

Abstract: A system, method and device for immobilizing an imager in-vivo and/or focusing images on the imager reflected from an in-vivo site to be monitored with for example a moveable or otherwise adjustable focusing mechanism. The imaging sensor may for example be positioned on an acute angle to an in-vivo surface to which the device is immobilized so that the device may for example image an in-vivo area that is opposed to such device. Sensors in addition to or other than an imaging sensor may be used.