Non-invasive methods of detecting hidden hearing loss (cochlear synaptopathy) based on detection of an abnormal ratio of Summating Potential (SP)/Action Potential (AP) (SP/AP) Ratios.

A recognition apparatus 100 for ear acoustic recognition include a feature normalizer 101 which reads input ear acoustic data and removes the earphone's resonance effect from the input ear acoustic data to produce a normalized data at the output, a feature extractor 102 which extracts acoustic features from the normalized data, a classifier 103 which reads the acoustic features as input and classifies them into their corresponding class.

A set of one or more processing circuits obtains eye movement-related eardrum oscillation (EMREO)-related measurements from one or more EMREO sensors of a hearing instrument. The EMREO sensors are located in an ear canal of a user of the hearing instrument and are configured to detect environmental signals of EMREOs of an eardrum of the user of the hearing instrument. The one or more processing circuits may perform an action based on the EMREO-related measurements.

The invention relates to a method for determining compliance of a cavity in minimally invasive surgery and to devices for carrying out said method.

An ear ailment diagnostic device and method in accordance with the present disclosure generally comprises a pair of earpieces, which both further comprise a light source, a magnification lens, an air conduction channel and a miniature camera. The earpieces may optionally comprise a thermometer and/or tympanometer. Each earpiece is coupled to an air conduction tube, an insufflator and an electrical wiring/data tube which is coupled to a computer. The insufflator may be manually, electronically, or battery powered. In the preferred embodiment the computer comprises a smart phone with data processing capability and wireless communication capability. Any data sent from the device can then be interpreted and diagnosed in a remote location so that an accurate treatment is prescribed.

A sensor system includes an actuator, an accelerometer coupled with the actuator, a rigid member, a transducer, and one or more processors. The actuator generates motion. The accelerometer outputs an acceleration signal responsive to at least the motion of the actuator. The rigid member extends from a first end coupled with the accelerometer to a second end. The transducer is coupled with the second end of the rigid member. The transducer can be configured to couple with a load, and can output a force signal responsive to at least a portion of the motion of the actuator transmitted to the transducer via the rigid member. The one or more processors determine a mechanical impedance of the load based at least on the acceleration signal and the force signal.

A sensor system includes an actuator, an accelerometer coupled with the actuator, a rigid member, a transducer, and one or more processors. The actuator generates motion. The accelerometer outputs an acceleration signal responsive to at least the motion of the actuator. The rigid member extends from a first end coupled with the accelerometer to a second end. The transducer is coupled with the second end of the rigid member. The transducer can be configured to couple with a load, and can output a force signal responsive to at least a portion of the motion of the actuator transmitted to the transducer via the rigid member. The one or more processors determine a mechanical impedance of the load based at least on the acceleration signal and the force signal.

A system having a scope with a longitudinal length extending between a proximal end and a distal end includes a plurality of markers spaced along the longitudinal length. The system also includes a disassociation and positioning device that is configured to enhance unsedated transnasal endoscopic procedures by at least partially occluding the vision of a patient while enabling body cavity access, and optionally record and sense body functions such as temperature, heart rate and oxygenation of the blood stream. The system further includes a sensor integrated into the distraction device, wherein the sensor is configured to detect the markers on the longitudinal length of the scope.

An otoscope includes at least one speaker and two microphones. The speaker is configured to generate a stimulus pressure wave and direct a planarized pressure wave toward an ear canal of a patient when the otoscope is at least partially inserted into the ear canal of the patient. The microphones are configured to record the forward stimulus pressure wave as it travels toward the TM and the reverse response pressure wave of the patient as it travels toward the otoscope. The quantitative relationship between the stimulus and the response is the diagnostic measure. The microphones are configured to record the pressure wave, the otoscope is configured to analyze the pressure wave, and the otoscope is configured to display results to a medical professional or user. The speaker and microphones are positioned outside the ear canal of the patient when the otoscope is at least partially inserted into the ear canal.

A set of one or more processing circuits obtains eye movement-related eardrum oscillation (EMREO)-related measurements from one or more EMREO sensors of a hearing instrument. The EMREO sensors are located in an ear canal of a user of the hearing instrument and are configured to detect environmental signals of EMREOs of an eardrum of the user of the hearing instrument. The one or more processing circuits may perform an action based on the EMREO-related measurements.