The present invention relates to a new system for measuring, recording and monitoring the splanchnic tissue perfusion and the pulmonary physiological dead space in an automated way, both continuously and intermittently, and in real time, which is easy to manage and generates information easy to interpret. Said system comprises at least four measuring devices of medical parameters, connected to a device receiving, converting, storing, integrating, processing, and allowing the management and display of the data recorded in the measurements and the parameters estimated by the same. For this purpose, said device comprises a specific computer program of estimation of parameters related to the measurement of the splanchnic tissue perfusion and the pulmonary physiological dead space, from the data derived from the measuring devices. Likewise, the present invention is related to the use of a device for measuring, recording and monitoring of the splanchnic tissue perfusion and the pulmonary physiological dead space.

A medical tube position confirmation system for confirming the position of a medical tube that is used to supply nutrients to the interior of a body by means of tube feeding while an end portion thereof is inserted into (placed in) the stomach includes a light guide that is configured to guide light entering through an incident end portion so that the light exits through an exit end portion, and is configured to be insertable into the medical tube so that the exit end portion is disposed in the interior of the stomach, and a light source for emitting light including a wavelength passing through a living body, the light source being optically connected to the incident end of the light guide so that the light enters the light guide, and a scattering part optically connected to the light guide on the exit end portion of the light guide so as to scatter light emitted by the light guide.

RGB image signals are inputted. A B/G ratio is calculated from the B and G image signals. A G/R ratio is calculated from the G and R image signals. First, second, and third areas are located in a feature space formed by the B/G and G/R ratios. An equal angular magnification process is performed on an angle in a region R1x including a first reference line passing through the second area. An angle expansion process or an angle compression process is performed on an angle in a region R1y located outside the region R1x. An equal radial-coordinate magnification process is performed on a radial coordinate in a region R2x, which includes a second reference line passing through the second area and intersecting the first reference line. A radial-coordinate expansion process or a radial-coordinate compression process is performed on a radial coordinate in a region R2y located outside the region R2x.

A contact detection instrument 1 is provided with a rod 12, a tip sensor portion 20 that is attached to one end of the rod 12 and is inserted into a living body through a hole, a speaker 14 that, from outside the living body, inputs a sound into a hollow space that is formed in the interior of the rod 12 and the tip sensor portion 20, and a microphone 15 that, outside the living body, outputs an electrical signal that corresponds to the sound inside the hollow space, with the tip sensor portion 20 including an elastic material that covers the hollow space.

A gastrointestinal stimulation apparatus and methods with an electronic controller and a flexible and stretchable electrode array with a central branch and orthogonal bilateral branches that wrap around a section of the gastrointestinal tract and can accommodate repetitive contraction and relaxation movements of the tract. Array branches have a flexible spring structure, stimulation electrodes, recording electrodes, sensors controlled by a controller and adhesion nodes that fix the branches to the tissue. The electrode array can sense the normal peristalsis from upstream tissue and produce a stimulus signal to stimulate the incapable intestine section to generate stimulation-induced contractions. Electrodes on the incapable intestine section can be used for stimulation or recording, the recorded signal from the incapable intestine section can be sent back to the electronics to form a closed loop control system. An impedance measurement using current stimulation can be used to capture low frequency contraction signals.

Systems and methods for gastrointestinal electrical stimulation to treat abnormalities in gastrointestinal motility are provided. In some embodiments, a system for relieving ileus includes an intraluminal catheter comprising: a catheter body having a proximal tip and a distal tip and a duodenal portion proximal to the distal tip of the catheter; and at least one electrode pair disposed along the duodenal portion of the intraluminal catheter, the at least one electrode pair being configured to detect a sensing information indicative of myoelectric activity of a patient and to provide stimulation energy; a sensing system in communication with the at least one electrode pair to receive the sensing information; and an energy delivery system in communication with the at least one electrode pair and the sensing system, the electrical energy delivery system being configured to delivery energy to the patient through the at least one second electrode pair based on the sensing information from the sensing system.

A system for monitoring digestive efficiency within the rumen of one or more ruminant animals comprises rumen boluses shaped and sized to be retained within the rumen dorsal sac and each comprising temperature, pH sensor, and redox sensors, and a wireless transmitter. A processor is arranged to derive from the sensor data one or more parameters indicative of animal digestive efficiency including any combination of one or more of hydrogen scale (rH), partial pressure of hydrogen (pp[H.sub.2]), oxygen fugacity (f(O.sub.2)) and free energy of the system (ΔG). A method and bolus are also claimed.

The invention relates to a device (1) for detecting a pressure in a mammal's stomach, particularly in a rumen of a ruminant, the device (1) comprising at least the following components: a sensing volume (12), a pressure sensor (9) configured and arranged to detect a gas pressure in the sensing volume (12), an elastic membrane (5) forming a deformable wall portion of the sensing volume (12), wherein the elastic membrane (5) is configured and arranged to deform in response to a pressure difference over the elastic membrane (5), wherein the elastic membrane (5) comprises a gas-permeable portion allowing a pressure difference over the elastic membrane (5) to equalize.

The present invention relates to an organ classification system, and the system for classifying the type of an organ may comprise: a search unit for searching an input image for a frame where an image regarding an organ starts, on the basis of a plurality of organ images pre-learned according to types of organs; an obtainment unit for obtaining an image of a found frame from the input image; and a storage unit for storing location information of the found frame in the input image.

An analyzer for diagnosing pulmonary and abdominals including, a pulsed force generator for outputting a mechanical disturbance to generate vibrations and reflected/return waves/vibrations in a patient's torso, and sensors for detecting the vibration/return wave signals. The apparatus compares the detected electrical signals with pre-stored reference wave profiles and based on the compared data generates an output signal indicative of a potential presence or absence of a pulmonary disease and/or condition.