A system and method are disclosed for the remote detection of otitis media in children at home or in other locations for use in a telemedicine environment. The system runs on a smartphone application and is easy for a child's caregiver to use. The system also includes a pop-open soundwave guide that directs an audio signal from a smartphone's speaker to the patient's eardrum and back to the smartphone's microphone.

Disclosed herein are systems and methods to detect a wide range of eardrum abnormalities by using high-resolution otoscope images and report the condition of the eardrum as “normal” or “abnormal.”

Disclosed herein are systems and methods to detect a wide range of eardrum abnormalities by using high-resolution otoscope images and report the condition of the eardrum as “normal” or “abnormal.”

Provided are a method and an apparatus for measuring an endolymphatic hydrops ratio of inner ear organs using an artificial neural network. The method of measuring an endolymphatic hydrops ratio includes obtaining a plurality of frame images obtained by capturing inner ear organs, obtaining a plurality of pieces of mask data corresponding to each of the plurality of frame images by inputting the plurality of frame images into a neural network, clustering the plurality of pieces of mask data according to the inner ear organs and obtaining representative images according to the inner ear organs according to certain conditions, and overlapping a target image synthesized by using the plurality of frame images and the representative images according to the inner ear organs so as to measure an endolymphatic hydrops ratio.

Provided are a method and an apparatus for measuring an endolymphatic hydrops ratio of inner ear organs using an artificial neural network. The method of measuring an endolymphatic hydrops ratio includes obtaining a plurality of frame images obtained by capturing inner ear organs, obtaining a plurality of pieces of mask data corresponding to each of the plurality of frame images by inputting the plurality of frame images into a neural network, clustering the plurality of pieces of mask data according to the inner ear organs and obtaining representative images according to the inner ear organs according to certain conditions, and overlapping a target image synthesized by using the plurality of frame images and the representative images according to the inner ear organs so as to measure an endolymphatic hydrops ratio.

A speculum body is configured to attach to the otoscope. An array of radially situated microchannels is within the speculum body and extends to apertures in a distal end of the speculum body. A power electrode array is within the speculum body positioned with respect to the microchannels to excite plasma generation within the microchannels. An optically transparent central portion is in the body to permit viewing of an eardrum by a practitioner. A method of treatment of the middle ear and/or middle ear cavity incudes actuating plasma jets to extend into the ear canal from a speculum attached to the otoscope and continuing the plasma jet treatment for a period of time sufficient to inactivate or kill a bacterial biofilm in the middle ear and/or the middle ear cavity.

A speculum body is configured to attach to the otoscope. An array of radially situated microchannels is within the speculum body and extends to apertures in a distal end of the speculum body. A power electrode array is within the speculum body positioned with respect to the microchannels to excite plasma generation within the microchannels. An optically transparent central portion is in the body to permit viewing of an eardrum by a practitioner. A method of treatment of the middle ear and/or middle ear cavity incudes actuating plasma jets to extend into the ear canal from a speculum attached to the otoscope and continuing the plasma jet treatment for a period of time sufficient to inactivate or kill a bacterial biofilm in the middle ear and/or the middle ear cavity.

The present disclosure is directed to arthroscopic visualization systems and methods. The visualization system can include a camera with a fluid inflow path, wherein a proximal end of the camera is configured to fluidly connect a fluid reservoir to the fluid inflow path. The system can also include a cannula with a lumen, wherein the lumen is configured to be fluidly connected to the fluid inflow path at a distal end of the camera. In addition, the system can also include a scope, wherein the scope is configured to be connected to the distal end of the camera and a portion of the scope is configured to be inserted into the lumen of the cannula.

A package is defined by an enclosure sized for retaining a medical diagnostic instrument and/or instrument supplies. A teaching aid, which simulates at least one medical target of interest, is directly integrated into the package for use with a medical diagnostic instrument. In at least one version, a sales demonstration aid is integrated with the packaging to highlight an enhanced field of view of the medical diagnostic instrument and provide a comparative field of view with other similar instruments.

An ear ailment diagnostic device 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.