Systems and methods for monitoring nutritional uptake of an individual are disclosed. The method can include monitoring microflora intestinal gas concentration levels associated with a patient and adjusting the volume of nutrient provided by the patient with an artificial feeding device based at least in part on the microflora intestinal gas levels associated with the patient. A microflora intestinal gas sensor can be used to monitor the microflora intestinal gas associated with the patient. The microflora intestinal gas sensor can monitor the microflora intestinal gas in a patient's exhaled breath or in the patient's digestive tract. The microflora intestinal gas sensor be included as part of an enteral feeding system at the distal end or outside end of an enteral feeding tube. Systems and methods for monitoring nutritional uptake of an infant based on microflora intestinal gas levels associated with the infant are also disclosed.

A medical device position notification system including a medical device and at least one sensor associated with the medical device, a processor, and a display device. The medical device is configured to be inserted into an orifice of the patient. The sensor measures information related to the position of the medical device in the patient's body, and communicates the information with the processor in real-time. The display device is coupled to the processor and is configured to display a tracing path of the position of the medical device in real-time. The display device is further configured to display a notification of the position of the medical device within the patient's body, such as a notification alert that the medical device has deviated from a predetermined path.

The use of a device to measure patient sensory response through the application of an incrementally increased electrical current to the oropharynx.

Systems and methods for monitoring nutritional uptake of an individual are disclosed. The method can include monitoring microflora intestinal gas concentration levels associated with a patient and adjusting the volume of nutrient provided by the patient with an artificial feeding device based at least in part on the microflora intestinal gas levels associated with the patient. A microflora intestinal gas sensor can be used to monitor the microflora intestinal gas associated with the patient. The microflora intestinal gas sensor can monitor the microflora intestinal gas in a patient's exhaled breath or in the patient's digestive tract. The microflora intestinal gas sensor be included as part of an enteral feeding system at the distal end or outside end of an enteral feeding tube. Systems and methods for monitoring nutritional uptake of an infant based on microflora intestinal gas levels associated with the infant are also disclosed.

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.

A patient monitoring, feeding, and mechanical breathing system, the system including an endotracheal probe including a first longitudinal member connected to a first camera and a semi-rigid longitudinal member inserted in an ET tube such that the first camera is aligned with a tip of the ET tube; an OG probe including a second longitudinal member configured to be inserted in an oral gastro (OG) tube, the second longitudinal member including a side camera, configured to be placed facing a window of the OG tube, wherein the side camera includes a tapered side; an enhanced OG probe, including a second camera and a motion sensor placed at the tip of the enhanced OG tube; a device communicatively coupled to the endotracheal, OG and enhanced OG probes, and having a screen configured to display images from any of the first camera, the side camera, and the second camera.

Certain embodiments are directed to methods, apparatuses, and systems for providing accurate, non-intrusive measurement of breastfeeding. The embodiments described herein are used during the normal breastfeeding routine and measure the volume of breast milk transferred in real time. The device is lightweight, disposable, and does not interfere with the milking mechanisms used by infants. The device provides a more accurate monitoring of infant nutrition and peace of mind for mothers.

An apparatus for identifying the location of a nasogastric tube that includes a pump that selectively fluidly couples to a nasogastric tube, a pressure sensor that identifies the pressure of an inner chamber of the nasogastric tube, and a controller configured to selectively power the pump and read the pressure sensor to identify an impedance of at least one opening of the nasogastric tube.

Camera devices and methods of use are provided wherein the camera device is attached to a medical device that is placed within a patient's body and the camera device includes a light source, a camera, a housing with adapters, and a cable, wherein the camera captures image data that is used with the cable to assist an operator in the control, placement and use of the medical device and the camera device is capable of being used with several different sized medical devices by being provided with several different sized adapters.

Disclosed is an NGT system, the system comprises a nasogastric tube having a diameter and length configured to pass through an esophagus such that the lumen of the NGT maintains fluid communication with a portion of the digestive tract, and a digestive tract sensor operatively associated with the NGT, the digestive tract sensor configured to sense from inside the body and transmit signals in response to one or both of conditions relating to nourishment states of the digestive tract, and positioning of the NGT.