A system for assessing extubation includes a respiratory assistance device, an artificial intelligence platform, and a hospital information system. The respiratory assistance device is adapted to communicate with a trachea of a patient. The artificial intelligence platform includes a prediction module. A method for assessing extubation includes the following steps. Measured values of respiratory parameters of the patient are recorded by the respiratory assistance device. The recorded times and the measured values of the respiratory parameters corresponding to each of the recording times are transmitted to the artificial intelligence platform. The prediction module analyzes the measured values of respiratory parameters within a predetermined time period according to a prediction model to generate a prediction result. The prediction result is transmitted to the hospital information system and is recorded into a medical record of the patient. With such design, a reference for extubation assessment that is more accurate is provided.

Provided are concepts for generating an indicator of chronic obstructive pulmonary disease (COPD) in a subject. In particular, an elasticated bag suitable for inflation is utilised, such that a change in a measurable characteristic of the elasticated during exhalation of the subject is detected. The change in the measurable characteristic may be analyzed so as to generate an indicator of COPD. Thus, this indicator may be used by a skilled professional in deciding whether to further investigate the possible presence of COPD.

A portable system is provided for measuring a ketone, such as an acetone, in the breath or other bodily fluid of a user. The system includes a portable measurement device that analyzes fluid samples and generates corresponding ketone measurements. The portable measurement device communicates with an application which runs on a smartphone or other mobile device of the user. The application tracks, and generates graphs of, the ketone measurements, and may include various features for facilitating the analysis of the measurements.

A face mask includes a mask body formed of a flexible material and configured to cover the mouth and nose of the user such that a cavity is formed between the face of the user and the face mask, the mask body having an interior surface facing the mouth and nose of the user and an exterior surface opposite the interior surface; a first sensor unit for measuring a moisture level and an oxygen level of the air entering the cavity; a second sensor unit for measuring a moisture level and an oxygen level of the air being expelled from the cavity; and at least one wireless transceiver configured to transmit data from the first sensor unit and the second sensor unit to a remote device.

The present invention is related to the field of bio/chemical sensing, assays and applications. Particularly, the present invention is related to collecting a small amount of a vapor condensate sample (e.g. the exhaled breath condensate (EBC) from a subject of a volume as small as 10 fL (femto-Liter) in a single drop), preventing or significantly reducing an evaporation of the collected vapor condensate sample, analyzing the sample, analyzing the sample by mobile-phone, and performing such collection and analysis by a person without any professionals.

A spirometry system operable to measure airflow through an air passage defined by a mouthpiece including one or more contact sensors configured to generate at least one mouth contact signal indicative of user mouth contact with the proximal portion of the mouthpiece. The spirometry system can further include an airflow sensor configured to generate an airflow signal corresponding to airflow within the air passage, and processor circuitry communicatively coupled to the one or more contact sensors and to the airflow sensor. The processor circuitry can be configured to determine an indication of an amount of user mouth contact for use with a measurement of airflow by the processor circuitry.

A system and method for monitoring resuscitation and respiratory mechanics of a patient is provided. A pressure sensor detects air pressure within an air-flow path of a resuscitator and generates a first detection signal in response thereto. A flow-rate sensor detects the flow-rate within the air-flow path and generates a second detection signal In response thereto. A processor receives and processes the first and second detection signals using an algorithm to identify a ventilation rate, a lung pressure, and an air volume corresponding to the respiratory air. A report is generated of real-time feedback about respiration of the patient that includes the ventilation rate, lung pressure, and air volume.

An apparatus and method for collecting a breath sample are provided. The apparatus has a breath input interface configured to receive exhaled breath, a first conduit system connected to the breath input interface, at least one breath sample storage device connected to the breath input interface via a breath intake conduit of the first conduit system extending between the breath input interface and the breath collection system, the at least one breath sample storage device being configured to capture at least some of the breath, and at least one metering device for measuring at least one characteristic, the at least one metering device being positioned along an exhaust conduit of the first conduit system that branches from the breath intake conduit.

A respiratory tidal volume monitor and feedback device (RTVMFD) comprising a frame, a flow channel tube attached to the frame, a mass flow sensor disposed on the flow channel tube to detect air flow through the flow channel tube, a microcontroller unit attached to the frame and electrically connected to the mass flow sensor via a bus, the microcontroller unit having a system processor, a system memory, and a system clock, a visual display attached to a top of the frame, the visual display being electrically connected to the bus. According to a further embodiment, the RTVMFD further comprises an audio output attached to the frame and electrically connected to the bus.

The present invention is related to the field of bio/chemical sensing, assays and applications. Particularly, the present invention is related to collecting a small amount of a vapor condensate sample (e.g. the exhaled breath condensate (EBC) from a subject of a volume as small as 10 fL (femto-Liter) in a single drop), preventing or significantly reducing an evaporation of the collected vapor condensate sample, analyzing the sample, analyzing the sample by mobile-phone, and performing such collection and analysis by a person without any professionals.