RU2729723C1 - Bionic ear prosthesis - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: group of inventions refers to medicine, namely to a bionic ear prosthesis and a method for ear prosthesis with such a prosthesis. Bionic ear prosthesis comprises a microphone, means of converting electrical signals into acoustic, connecting wires for transmitting electrical and converted acoustic signals and a power supply unit with an energy source. Additionally, the prosthesis comprises an auricular simulator, a body, screw implants to be placed in the temporal bone, a magnetic-vibration bone conduction transducer made for installation on a sound-conducting screw implant, and a flexible microchip with analogue-to-digital and digital-to-analogue converters, a digital signal processor, a radio communication module and a programmable memory device. Body has a mushroom head with an outer surface for the auricle imitator installation, an internal surface in the form of a temporal bone and a foot with external surface areas as per the tragic inner surface and an external acoustic canal. Flexible microchip is placed at the distal end of the body leg and connected by connecting wires in the form of flexible tape conductors with a magnetic-vibration transducer of bone conductivity and with a power supply unit including at least one resistor and at least one capacitor placed between the microphone and the power source. Simulated absent concha of dental silicone is performed by 3D-printing of a mirror image of a digital image of a computer tomography of the opposite auricle. Body is made with a mushroom head having an external surface for the auricle imitator installation, an internal surface in the form of a temporal bone and a foot with external surface areas as per the tragic inner surface and an external acoustic meatus. Casing is inserted into canal of external acoustic meatus. Simulator of auricle is placed on the outer surface of the body head and on the temporal bone with subsequent fixation of the imitator and head of the body with screw implants made for installation in the temporal bone. Magnetic-vibration transducer is installed on a sound-conducting screw implant of bone conductivity.EFFECT: provides for correction of hearing loss in hard of hearing of patients with atresia or microtia by means of acoustic apparatus operating on the principle of bone conduction and arranged in auricular prosthesis.5 cl, 1 dwg

Description

The invention relates to medicine, in particular to otolaryngology and dentistry, and can be used to improve the auditory capabilities of a person and replace the missing auricle. From the prior art, a Baha bone conduction apparatus is known, consisting of a processor that detects, cleans and amplifies sound waves and converts them into vibrations, then the amplified vibrations are transmitted to a connecting element - a support from which they are transmitted to an osseointegrated implant. From a titanium implant, sound vibrations are transmitted to the cochlea by the bone conduction mechanism (http://eu-max.ru/products/baha/).

Known ear prosthesis, made of medical dental silicone, made by casting according to the prototype, made by 3D-printing, mirrored digital image of a computer tomogram of the opposite auricle of the patient. Auricle prosthesis consists of two elements of the auricle and a base at the point of contact with the tissues of the prosthetic bed, interconnected by fixing elements made of hard dental polymer, having a round flat base, a neck and a hemispherical head. The edges of the hemispherical head are made with tipped. The section of transition from the head to the neck has a bump with a rounding radius. The base of these elements is monolithically fixed in the part of the prosthesis - the shell. In the part - the base in the projection of the element heads, there are holes in the section 2 times less than the diameter of the heads of the fixing elements. The technical results of the invention are the precise individual production of the prosthesis of the reproduced ear of the patient, as well as the possibility of quick and repeated replacement of the part of the prosthesis adjacent to the tissues of the prosthetic bed (RF Patent No. 2630354 dated 09/07/2017).

Known hearing aid, inserted into the ear canal of the patient's ear, has modules, each having a large degree of freedom of rotation and not placed in a single housing. The hearing aid contains a receiving module for supplying acoustic signals to an enclosed space adjacent to the eardrum, a main module, which houses all components for improving hearing, except for the receiver, and a connecting block for transmitting amplified electrical signals from the main module to the receiving module. The connecting block is inserted into the cartilaginous area of the external auditory canal and pivotally connected with the ability to rotate with the receiving module and with the main module for the possibility of independent movement of the receiving module both during the installation of the hearing aid in the ear canal and when removing it from it (RF Patent No. 2191485 from 20.01.2002).

The task to the solution, which is directed by the present group of inventions, is to provide hearing improvement in hearing impaired patients with atresia or microtia by means of a bionic ear prosthesis.

The technical result of the group of inventions is the correction of hearing loss with a hearing aid operating on the principle of bone conduction located in the auricle prosthesis.

The technical result is achieved in that the bionic ear prosthesis containing a microphone, means for converting electrical signals into acoustic signals, connecting wires for transmitting electrical signals and converted acoustic signals and a power supply unit with an energy source, differs from the closest analogue in that it additionally contains an ear simulator shells, body, screw implants for installation in the temporal bone, magnetic-vibration bone conduction transducer made for installation on a sound-conducting screw implant, and a flexible microchip with analog-to-digital and digital-to-analog converters, digital signal processor, radio communication module and programmable memory device, while the body has a mushroom head with an outer surface for installing a simulator of the auricle, an inner surface in the shape of the temporal bone and a leg with sections of the outer surface in the shape of the inner surfaces of the tragus, and an external auditory canal about the passageway, and a flexible microchip is located at the distal end of the body leg and is connected by connecting wires in the form of flexible ribbon conductors with a magnetic vibration bone conduction transducer and a power supply unit including at least one resistor and at least one capacitor placed between the microphone and the power source ...

In particular cases of its execution or use, a bionic ear prosthesis may contain screw implants made with spherical heads, an energy source made in the form of a battery or in the form of a battery, and a power source made for wireless charging. The method of ear prosthetics with a bionic prosthesis, as described above, includes making a simulator of an absent auricle from dental silicone, which is cast according to a 3D-printed mirror image of a computed tomogram of the opposite auricle and making a housing with a mushroom head having an outer surface for installation simulator of the auricle, the inner surface in the shape of the temporal bone and the leg with sections of the outer surface in the shape of the inner surfaces of the tragus, and the canal of the external auditory canal, installation of the body into the canal of the external auditory canal, placement of the simulator of the auricle on the outer surface of the head of the body and on the temporal bone with subsequent fixation of the simulator and the head of the body, screw implants made for installation in the temporal bone, and installation of a magnetic-vibration transducer on a sound-conducting screw bone conduction implant.

Dividing the prosthesis into two collapsible parts allows you to disconnect the internal part of the prosthesis, which is fixed in the internal auditory canal and contains devices that amplify sound with a battery for charging it, while the other part of the bionic prosthesis, the auricle, remains fixed, ensuring the aesthetics of the face and its social invulnerability. The outer and inner parts of the bionic ear prosthesis are made individually according to the digital volumetric image of the second existing ear and the patient's auditory canal obtained by MSCT. The most suitable basis for building such a system is a hybrid chip, for example, the EZARIO 7150 SL HYBRID from ON Semiconductor, which includes a digital signal processor and additional components necessary for building various types of hearing aids.

Chip 7150 SL includes a digital signal processor, analog-to-digital and digital-to-analog converters, programmable memory and radio module. These components are electronic parts for different types of hearing aids, and they are all housed in one housing. For this reason, the microcircuit is called hybrid.

The choice was made on this microcircuit on the basis that it contains all the necessary functional components to build a device within the scope of the task, has a minimum size, the manufacturer provides tools for developing and debugging the hearing aid software and software for its maintenance.

In addition to the 7150 SL microcircuit, the hearing aid (prosthesis) contains a microphone, a sound emitter, a power source, one or two compact capacitors and resistors provided by the 7150 chip switching circuit. These components are external to the microcircuit and, along with it, are located in the prosthesis volume.

A microphone was used as a sound emitter, for example, MP23AB01DHTR (3.35 × 2.5 × 0.98 mm) and a miniature magnetic vibration transducer for bone conduction devices, for example, Sonion 37AAX007 / A (7.87 × 4.09 × 5.6 mm), power supply - zinc air cell type PR70 (5.9 × 3.6 mm) according to IEC classification.

The power supply of the prosthesis has a contact wireless charging capability. And the magnetic vibration transducer, fixed in the prosthesis, performs an additional function of the fastening element of the prosthesis.

The essence of the group of inventions is illustrated by a drawing depicting a section of a bionic ear prosthesis installed in the ear canal and attached to the temporal bone.

The bionic ear prosthesis contains a simulator of the auricle 1, body 2, screw implants 3 and 4 for installation in the temporal bone, a magnetic-vibration bone conduction transducer 5 made for installation on the upper screw implant 4, and a microchip 6 with analog-digital and digital analog converters, digital signal processor, radio module and programmable memory.

The body 2 has a mushroom head with an outer surface 7 for installing a simulator of the auricle 1, an inner surface 8 in the shape of a temporal bone and a leg with sections of the outer surface in the shape of the inner surfaces of the tragus, and a canal of the external auditory canal. Flexible microchip 6 is located at the distal end of the body leg 2 and is connected by connecting wires in the form of flexible ribbon conductors 9 with a bone conduction magnetic vibration transducer 5 and with a power supply unit including at least one resistor and at least one capacitor 10, placed between the microphone 11 and energy source 12.

In particular cases of its execution or use, a bionic ear prosthesis may contain screw implants 3 and 4, made with spherical heads and an energy source 12 in the form of a battery or in the form of a battery. The power source 12 can be configured for wireless charging. In the method of ear prosthetics with a bionic prosthesis, the basic principle of converting the sound wave recorded by the microphone 11 into a vibration signal by the processor and transmitting it along the temporal bone to the inner ear by means of a magnetic-vibration transducer 5 fixed to the upper sound-conducting implant 4 is laid down.

In the process of prosthetics, a simulator of an absent auricle 1 is initially made of dental silicone, which is molded according to a 3D-printed mirror image of a computer tomogram of the opposite auricle. Then, a body 2 is made with a mushroom head having an outer surface 7 for mounting a simulator of an auricle 1, an inner surface 8 in the shape of a temporal bone and a leg with sections of the outer surface in the shape of the inner surfaces of the tragus, and a canal of the external auditory canal. The body 2 is installed in the canal of the external auditory canal. Place the simulator of the auricle 1 on the outer surface 7 of the head of the body and on the temporal bone. The simulator of the auricle 1 and the head of the body 2 are fixed with screw implants 3 and 4, made for installation in the temporal bone. A magnetic vibration transducer 5 is installed on the upper sound-conducting screw implant 4 of bone conduction.

Hearing improvement using a bionic prosthesis is carried out as follows. The sound wave is captured by the simulator 1 of the auricle and is localized according to the funnel principle in the external auditory canal of the prosthesis, where the microphone 11 is fixed.

Microphone 11 captures the sound wave and through a flexible ribbon conductor 9 transmits it to a flexible microchip 6 including a digital signal processor, analog-to-digital and digital-to-analog converters, programmable memory and radio communication module. By means of the microchip 6, the sound signal is converted into a vibration signal and through a flexible tape conductor 9 is transmitted to the magnetic-vibration transducer 5, fixed on the sound-conducting implant 4. The vibration signal is transmitted by the transducer 5 through the sound-conducting implant 4 installed in the temporal bone to the inner ear.

The uninterrupted operation of the microphone 11 and the transducer system 5 is provided by the resistor 13, the capacitor 10 and the power source 12, which can be made for wireless charging.

Claims (5)

1. A bionic ear prosthesis containing a microphone, means for converting electrical signals into acoustic signals, connecting wires for transmitting electrical signals and converted acoustic signals, and a power supply unit with an energy source, characterized in that it additionally contains an auricle simulator, a housing, screw implants for installation into the temporal bone, a magnetic-vibration bone conduction transducer designed for installation on a sound-conducting screw implant, and a flexible microchip with analog-to-digital and digital-to-analog converters, digital signal processor, radio communication module and programmable memory, while the case has a mushroom head with an outer surface for installing a simulator of the auricle, an inner surface in the shape of a temporal bone and a leg with sections of the outer surface in the shape of the inner surfaces of the tragus and the canal of the external auditory canal, and a flexible microchip is located at the distal end of the leg housing and connected by connecting wires in the form of flexible tape conductors with a magnetic-vibration bone conduction transducer and a power supply unit including at least one resistor and at least one capacitor located between the microphone and the power source. 2. The prosthesis of claim. 1, characterized in that the screw implants are made with spherical heads. 3. The prosthesis according to claim 1, characterized in that the energy source is made in the form of a battery or in the form of a battery. 4. The prosthesis of claim. 1, characterized in that the power source is made for wireless charging. 5. A method of ear prosthetics with a bionic prosthesis according to claim 1, comprising making a simulator of an absent auricle made of dental silicone, which is molded according to a 3D-printed mirror image of a computed tomogram of the opposite auricle and manufacturing a body with a mushroom head having an external surface for installing the simulator of the auricle, the inner surface in the shape of the temporal bone and the leg with sections of the outer surface in the shape of the inner surfaces of the tragus and the canal of the external auditory canal, installation of the body into the canal of the external auditory canal, placement of the simulator of the auricle on the outer surface of the head of the body and on the temporal bone with subsequent fixation of the simulator and the head of the body, screw implants made for installation in the temporal bone, and installation of a magnetic vibration transducer on a sound-conducting screw bone conduction implant.

Images