There is provided a system for managing reflux during an enteral feeding, comprising: (i) a non-transitory memory having stored thereon a code for execution by at least one hardware processor of a computing device, the code comprising: code for receiving electrical signals outputted by at least one reflux event sensor disposed within a digestive system of a patient; code for determining a gastric reflux event based on an analysis of the electrical signals; code for outputting instructions to pause enteral feeding of the patient by a feeding controller that regulates enteral feeding of the patient using an enteral feeding tube positioned within the digestive system of the patient; and (ii) an evacuation controller that directs back-flow of digestive contents from the digestive system of the patient to an external evacuation reservoir through an evacuation tube.

According to one aspect, an implantable medical device may include an anchor assembly configured to anchor the medical device to a body lumen. The implantable medical device may also include a capsule. The capsule may include a pH sensor. The pH sensor may be configured to measure a pH of contents within the body lumen. The capsule may also include a power source, a controller, and an impedance sensor. The impedance sensor may be configured to measure an impedance within the body lumen.

A feeding tube position confirmation device 102, operable to confirm the position of a predetermined portion of a medical feeding tube in a predetermined portion of a human or animal body, the position confirmation device comprising an optical waveguide 106 dimensioned to be insertable into the lumen of the feeding tube, the optical waveguide having a sensing distal end 108 comprising a distal end material and a sensing material mixed with the distal end material, the sensing material operable to provide a change in optical properties at the distal end 110 of the optical waveguide dependent on the environment to which the sensing distal end 108 of the waveguide is exposed. The sensing material may comprise a reflective material. Methods of manufacture and use of such devices are also described.

Methods, systems and apparatus for monitoring equivalent inner diameter of arteriole-like blood vessels and related cardiovascular parameters, where by measuring a time difference between signals from larger blood vessels, like arteries (excluding arterioles), and smaller blood vessels, similar to arterioles by their physiologic properties, also taking concurrent heart rate value into account.

In case the signal from larger blood vessels is measured geometrically relatively far from such a signal from smaller, arteriole-like blood vessels, said measured time difference may be evaluated by several ways in order to separate a PWTT component of time differences, obtained from said measured signals, from transient time component, including information about changes of diameter in arteriole-like vessels.

It also may be effective defining more correctly the role of blood viscosity in monitored vascular condition of patient.

A medical apparatus for a patient includes an external system configured to transmit one or more transmission signals, each transmission signal having at least power or data. An implantable system is configured to receive the one or more transmission signals from the external system, and the external system includes a first external device with at least one external antenna configured to transmit a first transmission signal to the implantable system. The first transmission signal includes at least power or data, and an external transmitter is configured to drive the at least one external antenna. An external power supply is configured to provide power to at least the external transmitter, and an external controller is configured to control the external transmitter. A first implantable device includes at least one implantable antenna configured to receive the first transmission signal from the first external device. An implantable receiver is configured to receive the first transmission signal from the at least one implantable antenna. At least one implantable functional element is configured to interface with the patient. An implantable controller is configured to control the at least one implantable functional element. The medical apparatus is configured to neuromodulate tissue and/or record patient information.

Disclosed is a monitoring device including a first measurement device disposed inside an organ of a target, the first measurement device being configured to measure a first biosignal of the target and to transmit the first biosignal, a second measurement device disposed inside a skin tissue of the target, and the second measurement device being configured to measure a second biosignal of the target, to receive the first biosignal, and to transmit bioinformation comprising the first biosignal and the second biosignal, a drone configured to move to an area in which the target is positioned, to receive the bioinformation from the second measurement device, and to transmit the bioinformation, and an analyzer configured to monitor and analyze a condition of the target based on the bioinformation received from the drone.

Devices and methods for treating obesity are provided. More particularly, intragastric devices and methods of tracking and locating the same are provided.

A multimodality imaging system including ultrasound, optical coherence tomography (OCT), photoacoustic (PA) imaging, florescence imaging and endoscopic catheter for imaging inside the gastrointestinal tract with real-time automatic image co-registration capability, including: an ultrasound subsystem for imaging; an optical coherence tomography (OCT) subsystem for imaging, a PA microscopy or tomography subsystem for imaging and a florescence imaging subsystem for imaging. An invasive interventional imaging device is included with an instrumentality to take a tissue biopsy from a location visible on the ultrasound subsystem for imaging, on the optical coherence tomography (OCT) subsystem for imaging, photoacoustic (PA) subsystem for imaging and florescence subsystem for imaging. The instrumentality takes a tissue biopsy from a visible location simultaneously with the visualization of the tissue about to be biopsied so that the tissue biopsy location is visualized before, during and after the biopsy.

Methods for monitoring equivalent inner diameter of arterioles by measuring blood pressure wave transient time from small arteries to arterioles and calculating, from the transient time and concurrently measured heart rate values, an equivalent inner diameter of arterioles.

The invention relates to a device for permanently detecting the gastric pressure, the gastric temperature, the gastric motility and the movement of a livestock animal, in particular a ruminant, comprising a, for example, bolus-shaped body (14), said body (14) comprising the following components: a pressure sensor (9), a telemetric device (9) for transmitting measuring values, and a gas-tight interior space (12), wherein a wall of the gas-tight interior space (12) comprises in some regions an elastic material which is deformable by the gastric pressure of a livestock animal, and wherein the pressure sensor (9) is designed to detect the pressure in the gas-tight interior space (12). According to the invention, said device is designed such that it permanently remains in the stomach of the livestock animal when it is applied to the livestock animal.