A nasogastric tube securement system. The system can include a base layer and a coupling layer. The base layer can be configured to be adhered to a nose, the base layer having a first major surface comprising a skin-contact adhesive and a second major surface opposite the first major surface. The coupling layer can include a first end comprising coupling means configured to be repositionably coupled to the second major surface of the base layer, and a leg. The leg can be connected to and extending from the first end, can be elongated along a longitudinal direction, and can be configured to secure a nasogastric tube.

Provided is a multi-cap for connecting a catheter and the multi-cap includes: a body having an internal hole formed in a longitudinal direction and having an end connected to a catheter; a cover portion disposed on an outer side of the body in the longitudinal direction of the body and spaced from the body such that the catheter is partially inserted between the outer side of the body and the cover portion. Further, a spout is formed at a second end of the body to transmit an injection substance from the outside to the hole and a capping part is connected to a side of the body to selectively close the inlet of the spout.

There is provided a system for monitoring transpulmonary pressure of a mechanically ventilated individual, comprising: a feeding tube, at least one esophageal body, a pressure sensor, and a memory having stored thereon code for: computing an estimate of esophageal wall pressure according to pressure in the esophageal body when inflated and contacting the inner wall of the esophagus, computing the transpulmonary pressure of the mechanically ventilated target individual according to the esophageal wall pressure, periodically inflating and deflating the esophageal body for periodic monitoring of the transpulmonary pressure of the mechanically ventilated target patient while the feeding tube is in use, and computing instructions for adjustment of parameter(s) of a mechanical ventilator that automatically ventilates the target individual according to the computed transpulmonary pressure, wherein the instructions for adjustment of parameter(s) of the mechanical ventilator are computed while the feeding tube is in place without removal of the feeding tube.

A temporary tube placement system includes a tube having a proximal end and a distal end, a camera supported by the tube at the distal end, a plurality of fiber optic filaments through which light from a light source travels from the proximal end to the distal end, a screen for displaying images from the camera, and a power source electrically attached to the camera and the light source. The enteral tube includes a tube having a distal end portion for placement within a patient and a proximal end portion and a lumen increasing in cross section from the proximal end portion toward the distal end portion along at least a portion of the tube.

There is provided system for monitoring spontaneous breathing of a mechanically ventilated target individual, comprising: a feeding tube for insertion into a distal end of an esophagus of the individual, sensor(s) disposed on the feeding tube at a location such that the sensor(s) is located at the distal end of the esophagus of the individual when the feeding tube is in use, wherein the sensor(s) is positioned for sensing values by contact with the tissue of the esophagus including a lower esophageal sphincter (LES) and/or tissue in proximity to the LES, and code for computing an indication of a frequency band of diaphragm movement of the individual according to an analysis of values sensed by the sensor(s), and for adjustment of parameter(s) of a mechanical ventilator for mechanically ventilating the individual, wherein the instructions for adjustment are computed while the feeding tube is in use.

A medical device for the insertion of a tube, with which a tube is introduced from the oral or nasal cavity to the oesophagus of a patient. The device includes tubing and an inlet body, the inlet body is adapted to be arranged between the posterior pharynx and the upper third of the oesophagus of a patient, and the inlet body is joined to the tubing at a point along the vertical dimension thereof; the tubing and the inlet body also being in connection through a through hole which communicates them internally.

Devices and methods can be used to treat long gap esophageal atresia, while obviating much of the delay and complexities associated with current procedures. The devices and methods involve actively stretching the esophagus portions with traction to promote growth of the esophagus portions. Moreover, the devices and methods provided allow for a compression anastomosis to occur between the esophageal ends. This eliminates the need for a second operation to suture the esophageal ends together.

Disclosed is an active inserted gastric tube with an intra-body communication function, including a tube body, a pulse module, an intra-body communication module and a control module. The pulse module is arranged at a front end of the tube body, and is configured to generate a pulse signal. the intra-body communication module is configured to receive the pulse signal generated by the pulse module and transmit the pulse signal to the control module. The control module is configured to analyze the received pulse signal. In this way, the pulse signal is generated by the pulse module, and the gastric tube is inserted into the esophagus through the tube body. The pulse signal is transmitted through a human body to realize an intra-body communication. The control module analyzes the pulse signal transmitted through the human body, so as to identify whether the tube body is inserted into the esophagus or trachea.

There is provided feeding tubes including an electromagnetic sensor including a sensor body comprising a core positioned at a distal end of the sensor lumen, and a wire extending along the length of the feeding tube, wherein an RF induced heating of the feeding tube in an MRI environment is below 5 degrees.

There is provided system for monitoring spontaneous breathing of a mechanically ventilated target individual, including: a feeding tube for insertion into a distal end of an esophagus of the individual, sensor(s) disposed on the feeding tube at a location such that the sensor(s) is located at the distal end of the esophagus of the individual when the feeding tube is in use, wherein the sensor(s) is positioned for sensing values by contact with the tissue of the esophagus including a lower esophageal sphincter (LES) and/or tissue in proximity to the LES, and code for computing an indication of a frequency band of diaphragm movement of the individual according to an analysis of values sensed by the sensor(s), and for adjustment of parameter(s) of a mechanical ventilator for mechanically ventilating the individual, wherein the instructions for adjustment are computed while the feeding tube is in use.