Disclosed herein are spirometers that can be used for assessment of pulmonary lung function. The disclosed systems, computer readable mediums and methods can be directed towards use in a variety of settings by health care professionals, clinical trial specialists, and individual users.

Diagnostic test devices improve communication to a user thereof through provision of audible output. The test device can include a test member, such as lateral flow assay test strip. The test device further includes an electronic communication circuit that can comprise an audio output element as well as a microcontroller. Other elements in the electronic communication circuit includes one or more sensor elements, a display element, and one or more switching elements.—Methods provide indicia for operation of a test device that comprise steps for assembly of a diagnostic test device that provides for audio output.

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.

Embodiments of the present invention are directed a system using a microphone and a mobile computer device comprising a transducer through which a user is to exhale or inhale; the transducer is configured and operable to convert the spirometric flow rate into an audible signal having an audio frequency responsive to the spirometric flow rate, wherein the transducer comprises a rotor including a plurality of rotor blades configured to rotate the rotor responsive to a spirometric flow; wherein the microphone is external to the transducer and is adapted to detect the audible signal having the audio frequency and to convert the audible signal to a corresponding electrical signal having the audio frequency.

An audible augmented reality (AR) computing system may receive audio data such as audible information, from a sensing system in an operating room (OR), ambient noise in the OR. The audio AR computing system may generate AR content. For example, the audio AR computing system may generate AR content based on the audible data. The AR content may be or may include audible information associated with the audio data. The audio AR computing system may receive an adjustment indication. The adjustment indication may be or may include one or more of adjustment information for the AR content. For example, the adjustment indication may be or may include one or more of a surgical task indication, a task importance indication, an audio insertion indication, an audio translation indication, an audio source location indication. The audio AR computing system may adjust the AR content based on the received adjustment indication.

A system includes a computer including a processor and a memory storing instructions executable by the processor to detect a position of a head of an occupant within a passenger compartment of a vehicle. The instructions include instructions to conduct a hearing test based on the position of the head of the occupant. The instructions include instructions to output sound at least at one of a specified frequency or amplitude, the specified frequency or amplitude selected based on results of the hearing test.

A training and simulation assembly for the learning of deliberate control of a specified body part by a test subject contains an electrode cap, which has a number of electrodes, and an evaluation unit, which is configured to measure voltages present at the electrodes and to provide measurement results as EEG measurement data. The evaluation unit analyzes the EEG measurement data for the presence of a mental act and to determine a correspondence value, which indicates the correspondence of the EEG measurement data with reference values defined by the mental act. A control unit and a simulation unit are provided. The simulation unit stimulates the body of the test subject at a specified point of the body and/or to trigger a motion. The control unit controls the stimulation unit and the ability to apply an indicating stimulus to the body part by the stimulation unit.

A physiological acoustic monitoring system receives physiological data from an acoustic sensor, down-samples the data to generate raw audio of breathing sounds and compresses the raw audio. The acoustic monitoring system has an acoustic sensor signal responsive to tracheal sounds in a person. An A/D converter is responsive to the sensor signal so as to generate breathing sound data. A decimation filter and mixer down-samples the breathing sound data to raw audio data. A coder/compressor generates compressed audio data from the raw audio data. A decoder/decompressor decodes and decompresses the compressed audio data into decompressed audio data. The decompressed audio data is utilized to generate respiration-related parameters in real-time. The compressed audio data is stored and retrieved so as to generate respiration-related parameters in non-real-time. The real-time and non-real-time parameters are compared to verify matching results across multiple monitors.

Systems, methods and computer-readable media are disclosed for providing therapeutic auditory stimulation. Consistent with disclosed embodiments, a system for providing therapeutic auditory stimulation may comprise a diagnostic unit that computes an EEG spectral density of a patient and a heart rate spectral density of a patient and provides values for one or more EEG frequency bands and one or more heart rate frequency bands. The system may also comprise a therapy unit that generates, based on the provided values, one or more stimulation waveforms corresponding to one or more of the EEG frequency bands and provides the stimulation waveforms for therapeutic auditory stimulation. The stimulation waveforms may comprise audible carrier frequencies modulated by signals with frequencies that vary exponentially with time. The EEG frequency bands may comprise the delta, theta, alpha, beta 1, beta 2, and gamma EEG frequency hands.

The invention refers to an apparatus that determines the abnormal electrical potential points which appear in the ventricular myocardium, particularly the left ventricle, which are capable of generating arrhythmias with a serious impact. The apparatus may assist the physician in objectively identifying, in real time, of the points which require ablating. The apparatus to determine the points of abnormal electrical potential from the ventricular myocardium contains an amplification and analogue filtering module, an analogue to digital signal converter, a hardware device which contains a microchip for digital processing, by means of a software, of signals received from an EKG and a catheter, with a display for the visualization of the signals received from the EKG and the catheter, as well as the abnormal electrical potentials found in the ventricular myocardium, identified via the software. The software analyzes the received signal from the catheter, referring to the amplitude, duration and synchronization with the QRS complex of the signal received from the EKG, as well as the degree of spectral fragmentation.