Method for ascertaining and setting a filling volume of a balloon of a catheter, which is placed in the esophagus of a living being, wherein the balloon is filled and/or emptied using a fluid. According to the invention, the balloon is filled and/or emptied step-by-step using at least two volume steps, a pressure difference between a pressure at the end of an expiration (Pmin) and a pressure at the end of an inspiration (Pmax) is determined for at least two volume steps, a relative pressure difference between Pmin and Pmax is determined, a border range is defined on the basis of the relative pressure difference, and an optimum filling volume is ascertained in consideration of the border range.

Methods and systems for non-contact monitoring of a patient to determine a respiratory parameter such as respiration rate. The systems and methods receive a depth signal from the patient to determine patient movement indicative of respiration. The methods include analyzing multiple regions in a region of interest (ROI) to determine whether or not respiration is occurring in the analyzed region, and preparing a mask with the regions determined to have respiration. The mask is used to determine the respiratory parameter of the patient in the masked ROI.

A non-invasive method and system is provided for determining an internal component of respiratory effort of a subject in a respiratory study. Both a thoracic signal (T) and an abdomen signal (A) are obtained, which are indicators of a thoracic component and an abdominal component of the respiratory effort, respectively. A first parameter of a respiratory model is determined from the obtained thoracic signal (T) and the abdomen signal (A). The first parameter is an estimated parameter of the respiratory model that is not directly measured during the study. The internal component of the respiratory effort is determined based at least on the determined first parameter of the respiratory model. The first model parameter is determined based on the thorax signal (T) and the obtained abdomen signal (A) without an invasive measurement.

A hydrogen generator electrically coupled to a cloud monitoring system comprises a hydrogen generating device, a monitoring device, a network device, and a controlling device. The monitoring device monitors the machine condition of the hydrogen generating device and generates a condition signal. The network device selectively transmits a machine information including the condition signal to the cloud monitoring system. The controlling device receives an operating parameter from the cloud monitoring system via the network device and controls the hydrogen generating device according to the operating parameter. The hydrogen generator monitoring system of the present invention collects the relevant data of the user using the hydrogen generator and tracks the health status of the user to perform big data analysis.

A filtering method includes the following steps: receiving an sound signal; decomposing the sound signal into a primary lung sound signal and a reference heart sound signal; adjusting the reference heart sound signal according to a weighted value to generate an adjusted heart sound signal; and subtracting the adjusted heart sound signal from the primary lung sound signal to generate a filtered lung sound signal.

Methods, devices, and systems for contactless cough detection and attribution are presented herein. Audio data may be received using a microphone. A cough may be identified as having occurred based on the received audio data. Radar data may be received indicative of reflected radio waves from a radar sensor. A state analysis process may be performed using the received radar data. The detected cough may be attributed to a particular user based at least in part on the state analysis process performed using the radar data.

Embodiments disclosed herein relate to devices and methods for monitoring one or more physiological parameters of a subject. In an embodiment, a wearable device comprises a substrate configured to be attached to a subject's skin. The substrate comprises a middle portion arranged between two end portions. The wearable device also comprises a physiological sensor. The physiological sensor is configured to sense a physiological signal of the subject when the wearable device is attached to the subject's skin. And, the wearable device comprises one or more electrical components arranged on at least one of the end portions, wherein at least one of the one or more electrical components is coupled to the physiological sensor.

A computer implemented method for providing output data comprising an indication regarding the affliction of a patient with an infectious respiratory disease, the method comprises receiving magnetic resonance imaging data, the magnetic resonance imaging data acquired using a magnetic resonance imaging system, the magnetic resonance imaging data comprising a lung region of the patient; applying a trained function to the magnetic resonance imaging data to generate the output data, the trained function being based on an artificial neural network and the output data comprising the indication regarding the affliction of the patience with the infectious respiratory disease; and proving the output data.

The present technology may be applied to selectively heat one or more diseased areas in the lung while limiting heating to the healthy area and surrounding tissue. This heating provides a therapeutic effect. The selective heating of diseased tissues may be achieved by exposing the lung to an electromagnetic field to cause dielectric or eddy current heating. The present technology is particularly useful for treating emphysema as the diseased areas in emphysema patients have reduced blood flow. The diseased areas will heat up rapidly while the healthy tissue will be cooled by blood flow. This is particularly effective for treating emphysema because of the low mass of the lungs and the high blood flow. In one described embodiment the frequency of the electromagnetic radiation is selected to satisfy certain resonance conditions of the apparatus. In another described embodiment the electromagnetic radiation is applied with a coil whose geometric parameters are chosen so as to produce an electric field maximum in the area to be heated. In another described embodiment the electromagnetic radiation is applied with a pair of electromagnetic energy signal applicators which are positioned around the torso of the patient, one positioned cranially from the treated area and the other positioned caudally from the treated area, and which are shaped to wrap or partially wrap around the circumference of the torso.

Methods and systems for capturing capnography data during high-flow oxygen therapy (HFOT) are disclosed. An example method includes delivering HFOT by delivering breathing gases at an operational flow rate and an operational oxygen concentration level; initiating a temporary flow-reduction function for a set duration, wherein breathing gases are delivered at a temporary flow rate for the set duration, the temporary flow rate being less than the operational flow rate; capturing capnography data for exhaled air during the set duration; and upon expiration of the set duration, resuming HFOT delivery.