In brain analysis, anatomical standardization is performed when analyzing a region of interest (ROI). There are individual differences in the shape and size of the brain and by converting the brain into a standard brain, these differences can be compared with each other and subjected to statistical analysis. When generating a standard brain analysis, a large number of pieces of image data are classified into a plurality of groups based on their anatomical features. An intermediate template that is an intermediate conversion image and a conversion map is calculated for each group, and the calculation of the intermediate template and the generation of the intermediate conversion image are repeated while gradually reducing the number of classifications, so that a final standard image is generated. Using the standard image and the intermediate template calculated during the generation of the standard image, spatial standardization of the measured image is performed.

A system for diagnosing and quantifying an organ prolapse includes a first manometry catheter configured for insertion within a first organ of the pelvic floor. The first manometry catheter includes an inflatable balloon configured to support a series of first sensors disposed along a length thereof and operably coupled to an image display for displaying a first image thereon relating to the first organ. One or more additional manometry catheters are configured for insertion within one or more respective additional organs. The additional manometry catheters include inflatable balloons configured to support corresponding additional sensors along a length thereof. The additional sensors are operably coupled to the image display for displaying one or more additional images thereon relating to the one or more additional organs. The first image and the one or more additional images being simultaneously displayed on the image display for diagnostic and quantification purposes.

A device for positioning a needle tip to a desired location by signaling pressure change is provided. The device includes a barrel, a piston, a biasing element, and a plunger. The barrel defines a reservoir, and it includes a distal end connectable to a puncturing apparatus. The plunger is slidably engaged with the piston, and both are movable within the reservoir. The biasing element connects the plunger and the piston, and its change in length corresponds to the relative position of the plunger and piston. In operation, the piston is at a first position relative to the plunger when the biasing element is at a first length. The piston later moves to a second relative position in response to the biasing element's change of the length resulting from a pressure change inside the reservoir when the puncturing apparatus reaches a location of a mass. The position's change of the piston is visually detectable.

Provided are methods of making a long-term implantable electronic device, and related implantable devices, including by providing a substrate having a first encapsulation layer that covers at least a portion of the substrate, the first encapsulation layer having a receiving surface; providing one or more electronic devices on the first encapsulation layer receiving surface; and removing at least a portion of the substrate from the first encapsulation layer; thereby making the long-term implantable electronic device. Further desirable properties, including device lifetime increases during use in environments that are challenging for sensitive electronic device components, are achieved through the use of additional layers such as longevity-extending layers and/or ion-barrier layers in combination with an encapsulation layer.

The present invention describes a system that uses ultrasonic waves to transfer energy and data, enabling for the control and recharging of a cardiac assist device. Data and energy transfer are accomplished using pulsed ultrasonic waves. The use of ultrasonic waves allows for wireless transcutaneous energy transfer to power the cardiac assist device pump in absence of a driveline, reducing complications associated with driveline infections and improving patient quality of life.

Described is a catheter for being retained inside the body for extended periods, and a catheter mating device that can connect to the catheter to move the catheter inside of the body or remove it from the body. The catheter mating device has a stem with an apparatus at its distal end. The apparatus is moveable between a first position and a second position. When in its first position, the distal end is configured to fit in the proximal end of the catheter. When in its second position, the distal end engages the proximal end of the catheter and connects the catheter mating device to the catheter.

An injector (1) for implanting a sensor implant (2) in the human or animal eye, in particular for the suprachoroidal implantation of a pressure sensor for the wireless measurement of the intraocular pressure, is improved in terms of rapid, complication-free, low-trauma and low-wear suprachoroidal implantation in that, to accommodate the sensor implant, the injector (1) has a substantially tubular injection chamber (8), the inner wall surfaces (9, 10) of which have a non-rotationally symmetrical cross section, preferably an oval or rectangular cross section, in that, at a free end, the injection chamber (8) is provided with an injection opening (13), through which, during implantation, the sensor implant (2) can slide out and slide into a sclera incision in the eye, wherein the inner wall surfaces (9, 10) of the injection chamber (8) enclose the likewise non-rotationally symmetrical cross section of the sensor implant (8) and prevent a rotation of the sensor implant (2) about an axis of rotation extending in the direction of the injection (11).

Disclosed is an IoT enabled, portable, multiple stimuli reinforced non-nutritive Sucking Training System, Method and Device that implements a function that measures suction pressure of a non-nutritive sucking event produced by a pre-mature infant; then converts the measured pressure value using transducer to digital form; then transmits the pressure value in digital form using IoT (Internet-of-Things) controller to a server and/or to an app and/or a software installed on a smartphone device. The app and/or software installed on the smartphone device which receives the pressure measurement uses an algorithm to produce a stimulus such as music and/or haptic feedback for the pre-mature infant, to train the premature infant to suck optimally; thereby improving self-feeding capability of the premature infant.

A mucosal impedance measuring apparatus detects and measures a condition of mucosa. The mucosal impedance measuring apparatus includes a catheter comprising a tube, impedance sensing electrodes on an exterior surface of the catheter, a balloon mounted on the tube in which the balloon is capable of inflation and deflation, and an impedance measuring system. The impedance measuring system is adapted to measure a pressure-regulated impedance measurement of the mucosa that is indicative of the condition of the mucosa when the balloon is inflated and the impedance sensing electrodes direct an electric current through mucosa while the balloon is pressed against the mucosa.

Disclosed is an implant and method of making an implant. The implant having a housing that defines a cavity. The housing includes a sensor comprising a base attached to a diaphragm wherein said base may be positioned within said cavity. The sensor may be a capacitive pressure sensor. The diaphragm may be connected to the housing to hermetically seal said housing. The sensor may include electrical contacts positioned on the diaphragm. The attachment between the base and the diaphragm may define a capacitive gap and at least one discontinuity configured to enhance at least one performance parameter of said implant.