A method for evaluating hearing of a user comprising: generating a baseline hearing profile for the user comprising a set of gain values based on a volume setting, each gain value in the set of gain values corresponding to a frequency band in a set of frequency bands; accessing a soundbite comprising a phrase characterized by a frequency spectrum predominantly within one frequency band; playing the soundbite amplified by a first gain in the frequency band; playing the soundbite amplified by a second gain in the frequency band; receiving a preference input representing a preference of the user from amongst the soundbite amplified by the first gain and the soundbite amplified by the second; and modifying a gain value, corresponding to the frequency band, in the baseline hearing profile based on the preference input to generate a refined hearing profile compensating for hearing deficiency of the user.

Systems and methods disclosed herein include a first scanner comprising an inflatable membrane configured to be inflated with a medium to conform an exterior surface of the inflatable membrane to an interior shape of a cavity, the medium attenuating, at a first rate per unit length, light having a first optical wavelength, and attenuating, at a second rate per unit length, light having a second optical wavelength; an emitter configured to illuminate an interior surface of the inflatable membrane; a detector configured to receive light from the interior surface; a processor configured to generate a first electronic representation of the interior shape based on the received light; and a design computer configured to modify the first electronic representation into a three-dimensional shape by correlating pixels of the first electronic representation with corresponding distance information from the first scanner to the inflatable membrane for each pixel.

Systems and methods disclosed herein include a first scanner comprising an inflatable membrane configured to be inflated with a medium to conform an exterior surface of the inflatable membrane to an interior shape of a cavity, the medium attenuating, at a first rate per unit length, light having a first optical wavelength, and attenuating, at a second rate per unit length, light having a second optical wavelength; an emitter configured to illuminate an interior surface of the inflatable membrane; a detector configured to receive light from the interior surface; a processor configured to generate a first electronic representation of the interior shape based on the received light; and a design computer configured to modify the first electronic representation into a three-dimensional shape by correlating pixels of the first electronic representation with corresponding distance information from the first scanner to the inflatable membrane for each pixel.

A system for inspecting a patient's orifice (especially the ear, nose or throat), to components of the system, and to methods of inspecting a patient's orifice. In one embodiment, the orifice inspection system includes: an orifice inspection device for illuminating a patient's orifice; and an image capture device for capturing a photograph of the patient's orifice as illuminated by the orifice inspection device; wherein the orifice inspection device is mountable relative to the image capture device, or wherein the image capture device is mounted on the orifice inspection device.

A system for inspecting a patient's orifice (especially the ear, nose or throat), to components of the system, and to methods of inspecting a patient's orifice. In one embodiment, the orifice inspection system includes: an orifice inspection device for illuminating a patient's orifice; and an image capture device for capturing a photograph of the patient's orifice as illuminated by the orifice inspection device; wherein the orifice inspection device is mountable relative to the image capture device, or wherein the image capture device is mounted on the orifice inspection device.

Disclosed herein are systems and methods for classifying a tympanic membrane by using a classifier. The classifier is a machine learning algorithm. A method for classifying a tympanic membrane includes steps of: receiving, from an interrogation system, one or more datasets relating to the tympanic membrane; determining a set of parameters from the one or more datasets, wherein at least one parameter of the set of parameters is related to a dynamic property or a static position of the tympanic membrane; and outputting a classification of the tympanic membrane based on a classifier model derived from the set of parameters. The classification comprises one or more of a state, a condition, or a mobility metric of the tympanic membrane.

A multi-organ imaging system including a camera lens, a stationary, multi-examination illumination unit (SMEIU), and an attachment holder is provided. An industrial camera unit (ICU) for imaging multiple organs, for example, ear, nose, throat, and skin, is housed in a camera body. The camera lens has a fixed focal length and an iris for optimizing examination and imaging of the organs. The SMEIU is integrated to the camera body and includes illuminators arranged in a geometrical configuration. The attachment holder accommodates an organ examination attachment selected for examining an organ. The illuminators, in optical communication with one or more reflective surfaces in the organ examination attachment, produce shadowless illumination during examination and imaging of each organ, without requiring replacement of the SMEIU for examining each organ. A display unit, accommodated in a display holder detachably attached to the camera body, assists in aiming the camera lens and visualizing each organ.

A multi-organ imaging system including a camera lens, a stationary, multi-examination illumination unit (SMEIU), and an attachment holder is provided. An industrial camera unit (ICU) for imaging multiple organs, for example, ear, nose, throat, and skin, is housed in a camera body. The camera lens has a fixed focal length and an iris for optimizing examination and imaging of the organs. The SMEIU is integrated to the camera body and includes illuminators arranged in a geometrical configuration. The attachment holder accommodates an organ examination attachment selected for examining an organ. The illuminators, in optical communication with one or more reflective surfaces in the organ examination attachment, produce shadowless illumination during examination and imaging of each organ, without requiring replacement of the SMEIU for examining each organ. A display unit, accommodated in a display holder detachably attached to the camera body, assists in aiming the camera lens and visualizing each organ.

A scope (1) for examining or surgically treating ears comprising at least one camera (6), a light source (7), and a stabilizer (2) for supporting the camera (7) in or on the stabilizer (2), the stabilizer (2) being integral with the camera (7) and being configured to stabilize the scope (1) in an ear canal.

A scope (1) for examining or surgically treating ears comprising at least one camera (6), a light source (7), and a stabilizer (2) for supporting the camera (7) in or on the stabilizer (2), the stabilizer (2) being integral with the camera (7) and being configured to stabilize the scope (1) in an ear canal.