JP7465570B2 - Bone conduction hearing aids - Google Patents

Description

The present invention relates to a hearing aid that utilizes bone conduction.

There are various types of hearing loss, including conductive hearing loss caused by abnormalities in the outer or middle ear, sensorineural hearing loss caused by abnormalities in the inner ear, cochlea or brain, mixed hearing loss, which is a combination of conductive and sensorineural hearing loss, and high-frequency hearing loss caused by aging or genetic factors, in which the person can hear low-frequency sounds but not high-frequency sounds.

Therefore, various hearing aids for the hearing impaired are commercially available. For example, for conductive hearing loss, where the eardrum is blocked from transmitting sound to the auditory nerve, bone conduction hearing aids that transmit sound via the skull are effective. Bone conduction hearing aids are used by various types of hearing impaired people, including those with hearing loss due to malformations of the auricle or outer ear, where normal hearing aids cannot be worn. Bone conduction hearing aids do not introduce sound from the ear canal as with normal hearing aids, but instead introduce sound from a bone conduction speaker (bone conduction terminal) that is pressed against the skin behind the auricle, and the sound is transmitted through the bone to the sensory cells of the inner ear. Conventional bone conduction hearing aids required headband-type or eyeglass-type devices to be pressed against the skin.

For example, the headband-type bone conduction hearing aid mentioned above has the drawback that the pressure point can shift with head movement, making the hearing unstable. Also, headband-type and eyeglass-type bone conduction hearing aids always apply a constant amount of pressure to the temples, causing the same discomfort as wearing eyeglasses with strong springs. Even adults find it quite painful to wear them for long periods of time, and young children in particular often dislike wearing them.

In order to solve the above-mentioned problems, a hearing aid has been proposed, as shown in Patent Document 1, which includes a bone conduction speaker body having a magnetized or non-magnetized magnetic body that is embedded in the skull without being exposed to the skin, a voice coil arranged in a magnetic path created by the magnet, and the bone conduction speaker body is configured to be fixed to the magnetic body by the magnetic force of the magnet, and a sound collection device including a microphone and an amplifier unit connected to the bone conduction speaker.

JP 2007-184722 A

However, the hearing aid described in Patent Document 1 embeds a magnetized or non-magnetized magnetic body in the skull, which is a part of the body, and therefore the hearing-impaired person is always psychologically anxious and cannot be said to be favorable for mental health. In other words, because a foreign body is embedded in the vicinity of the brain of the hearing-impaired person, the hearing-impaired person's anxiety that the brain may be damaged cannot be alleviated. In addition, there is a possibility that a surgical failure or mistake when embedding the magnetic body in the skull may cause physical adverse effects such as local infection around the skull of the hearing-impaired person.

The present invention has been made in consideration of these circumstances, and provides a bone conduction hearing aid that utilizes a vibrating part (e.g., a metal piece, implant, etc.) placed in the user's mouth.

The bone conduction hearing aid according to the present invention comprises:
A bone conduction hearing aid that uses bone vibrations,
A sound collecting part that is located outside the oral cavity and collects sound;
an amplification adjustment unit that amplifies and adjusts the sound collected by the sound collection unit as a signal ;
a transmitting unit that transmits the sound amplified by the amplification adjustment unit as a wireless signal;
a vibration unit that is placed in the oral cavity, receives the wireless signal from the transmission unit, and transmits the audio signal by vibrating the bone through the tooth root, the artificial tooth root, and the gums ;
It has the following characteristics.

With this configuration, the hearing-impaired person can feel safe and secure without having to implant a foreign object into a part of his/her body (such as the skull) from the outside, and the psychological hurdle of wearing the hearing aid is lowered, allowing the person to live a life that is favorable in terms of mental health. It is also possible to provide a hearing aid that does not cause local infections on the skin.

The bone conduction hearing aid according to the present invention comprises:
The vibrating part is packed into a cavity formed in the tooth.
With this configuration, the vibration of the bones in the oral cavity can be reliably transmitted to the bones, providing a hearing aid that is easy for the hearing-impaired to hear.

The bone conduction hearing aid according to the present invention comprises:
The vibration part is a part of the implant placed in the oral cavity.
This configuration ensures that vibrations are transmitted reliably from the vibration unit built into the implant to the bone that receives the signal, providing a hearing aid that the hearing-impaired person will not miss. In addition, the sound from audio devices such as smartphones, mobile phones, televisions, and computers can be heard directly through the hearing aid.

The bone conduction hearing aid according to the present invention comprises:
The vibration unit is installed inside a denture placed in the oral cavity.
With this configuration, vibrations can be reliably transmitted from the vibration unit built into the denture to the bone that receives the signal, providing a hearing aid that the hearing-impaired person will not miss. Also, the sound from audio devices such as smartphones, mobile phones, televisions, and computers can be heard directly through the hearing aid.

The bone conduction hearing aid according to the present invention has a plurality of vibration units arranged in the oral cavity.
With this configuration, even if one vibration unit breaks down or has other problems, the other vibration units can compensate for it, resulting in a highly reliable hearing aid. For example, by arranging the vibration units on the left and right, the direction of the sound source can be determined.

The amplification adjustment section of the bone conduction hearing aid according to the present invention can freely change the frequency of the signal.
With this configuration, it is possible to change the frequency of the sound and focus on sounds that are easy for the hearing-impaired person 400 (user) to hear.

According to the present invention, a vibration part (for example, a metal piece, a part of an implant, the position of a denture, the denture itself, etc.) placed in the user's oral cavity is utilized.
Therefore, according to the present invention, there is no need to implant a vibrating unit near the brain, and no need to wear glasses, earphones, or other equipment.
Furthermore, according to the present invention, it is possible to provide a bone conduction hearing aid that allows a hearing-impaired person to maintain mental stability when wearing the hearing aid and prevents localized skin infections, etc.

1 is an image diagram for explaining a bone conduction hearing aid according to a first embodiment of the present invention; 1 is a schematic diagram showing a case in which an implant is used as one component of a bone conduction hearing aid according to a first embodiment of the present invention. 1 is a schematic diagram showing a state in which a vibration unit is installed inside an implant of a bone conduction hearing aid according to a first embodiment of the present invention. FIG. 1 is a diagram showing that a metal piece filled in a cavity formed in the teeth of a user who uses a bone conduction hearing aid according to embodiment 1 of the present invention is a vibration part. 1 is an explanatory diagram showing the configuration of a bone conduction hearing aid according to a first embodiment of the present invention;

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
<First embodiment>
Fig. 1 is an image diagram for explaining a bone conduction hearing aid (hereinafter, referred to as hearing aid 100) according to a first embodiment of the present invention. Fig. 2 is a schematic diagram of a case where an implant 200 is used as one configuration of the hearing aid 100. The hearing aid 100 is a bone conduction hearing aid that uses bone conduction. The hearing aid 100 has a vibration unit 40 that is placed in the oral cavity of a user (a person with hearing loss) 400. Fig. 1 shows a schematic diagram of a user 400 using the hearing aid 100.

First, a general implant will be described. An implant is a general term for medical devices and materials that are embedded in the body. More specifically, cardiac pacemakers, artificial joints, silicone materials embedded in the body for cosmetic surgery, etc. are all implants. Incidentally, implant is spelled "Implant" in English, and in Japanese it means "to plant," "to blow in," "to insert," or "to transplant." The word implant is also used outside of dentistry, and cardiac pacemakers and silicone used in cosmetic surgery are also types of implants. Generally speaking, in the dental field, an artificial tooth root embedded in the jawbone is called an implant, or more correctly, a "dental implant." Since dental dentistry deals with implants more often than other departments, it is often recognized that "implant = dental implant." In the first embodiment, when simply referring to an implant, it is meant to mean a dental implant.

Next, a configuration example of the hearing aid 100 using the implant 200 will be described.
The implant 200 is composed of an implant body (fixture) 3 embedded in the gums 4, and an abutment 2 fixed by a screw between the crown 1 and the implant body 3. The implant body 3 is embedded in the maxillary bone 5 or the mandibular bone 5. Metallic titanium or titanium alloys are mainly used for the implant body 3. Metallic titanium or titanium alloys are used as the implant body 3 because they have the property of bonding with the bone 5 when embedded in the bone.

As described above, the implant body 3 is mainly made of metal titanium or titanium alloy. The abutment 2 connects the implant body 3 and the crown 1. The abutment 2, like the implant body 3, is mainly made of metal titanium or titanium alloy. Therefore, in the first embodiment, the abutment 2 is used as a vibration section, which is one component of the hearing aid 100. The implant 200 is placed in the oral cavity of the user 400, and by using the abutment 2 connecting the crown 1 and the implant body 3 as a vibration section, it becomes unnecessary to separately install a vibration section that constitutes part of the hearing aid 100.

However, the vibration unit only needs to be installed in the oral cavity, and the vibration unit only needs to be arranged at a position where the vibration can be transmitted to the maxillary bone 5 or the mandibular bone 5. For example, as shown in FIG. 3, the vibration unit 40 may be a metal piece embedded inside the abutment 2 inserted into the implant body 3, or as shown in FIG. 4, the vibration unit 40 may be a metal piece filled in the cavity 6 formed in the tooth 1A of the user 400. In either case, the vibration unit 40 may be formed of titanium or a titanium alloy. The vibration unit 40 does not need to be made of metal, and may be made of glass, resin, minerals, or the like through future development. The vibration unit 40 may also be installed inside a denture (so-called false teeth), or the denture itself may be the vibration unit 40. The vibration unit 40 may also be installed in the implant body 3 instead of the abutment 2.

FIG. 3 is a schematic diagram showing a state in which the vibration section 40 is installed inside the implant 200 of the hearing aid 100 according to the first embodiment of the present invention.
3, a vibration unit 40 is installed inside the implant body 3. The vibration unit 40 picks up sounds emitted around the hearing-impaired person 400 or by the hearing-impaired person 400 himself, and transmits the vibrations of the sounds to the bone 5. For example, the vibrations transmitted to the bone 5 reach the "cochlea" or "inner ear sensory cells" inside the body, enabling the hearing-impaired person 400 to hear sounds.

4 is a diagram showing that a metal piece filled inside a cavity 6 formed in a tooth 1A of a user 400 who uses a hearing aid 100 according to the first embodiment of the present invention is used as a vibration unit 40. As shown in FIG. 4, if the vibration unit 40 is directly filled inside the cavity 6 of the tooth 1A in the core that is inserted into the tooth root , it is possible to directly apply vibration to the bone 5.

Fig. 5 is a functional block diagram showing the electrical configuration of hearing aid 100 according to embodiment 1 of the present invention. As shown in Fig. 5, hearing aid 100 has a sound collection unit 10, an amplification adjustment unit 20, a battery 13, a transmission unit 30, and a vibration unit 40 placed in the oral cavity. Sound collection unit 10, amplification adjustment unit 20, and transmission unit 30 are placed outside the oral cavity of a user 400.

The sound collection unit 10 sends sounds around the hearing-impaired person 400 or sounds generated by the hearing-impaired person himself to the amplification adjustment unit 12 (amplifier). Here, the amplification adjustment unit 12 does not simply amplify the sound, but amplifies it while taking into consideration factors such as the strength, pitch, and directionality of the incoming sound. In addition, when amplifying the input sound, it is configured to provide a more comfortable hearing by cutting unnecessary noise and emphasizing speech sounds as necessary. In addition, the amplification adjustment unit 12 modulates the sound that the hearing-impaired person 400 (user) wants to hear into a sound that the hearing-impaired person 400 can hear by changing the frequency of the sound, making it easier for the hearing-impaired person 400 to hear.

The sounds that are difficult to hear differ depending on the hearing-impaired person 400. Therefore, in the hearing aid 100, the configuration of the amplification adjustment unit 40 is made such that the frequency band of the audible sounds can be changed according to the operation of the hearing-impaired person 400. With such a configuration, the frequency band can be adjusted to the frequency band of conversation for the hearing-impaired person 400 who has difficulty hearing conversation, and the frequency band can be adjusted to the frequency band of external noise when the hearing-impaired person 400 has difficulty hearing external noise. In addition, the hearing aid 100 may be configured to be capable of issuing a danger signal in response to dangerous sounds (e.g., sounds emitted by cars, railroad crossing sounds, and traffic signal sounds). This can protect the safety of the hearing-impaired person 400 from traffic accidents and the like. Furthermore, the amplification adjustment unit 20 and the transmission unit 30 may be configured to be capable of issuing a signal to communicate the presence of the hearing aid 100 to the surrounding environment (e.g., near a road, near a railroad crossing, near a traffic signal). This can provide a system that can encourage the surrounding environment (e.g., cars) to drive safely.

Furthermore, the battery 13 is provided to electrically operate each component of the hearing aid 100 (the amplification adjustment section 20, the vibration section 40, etc.).

The vibration unit 40 vibrates with a signal (wireless signal) transmitted from the transmission unit 30, and vibrates the upper or lower jaw bone 5 of the hearing-impaired person 400. The vibration unit 40 has a receiving unit and an oscillating unit. The receiving unit receives the signal transmitted from the transmission unit 30. The oscillating unit vibrates based on the received signal, and the vibration unit 40 vibrates. The vibration unit 40 also has a battery. The battery may be a wireless charging type that can be charged without contact. Furthermore, the vibration unit 40 may be covered with a heat insulating material to protect it from the temperature and humidity in the oral cavity. The heat insulating material may be, for example, a heat-resistant material such as ceramic or resin. In this way, the surrounding sounds can be provided to the hearing-impaired person 400 with a sound quality and volume that is comfortable for the hearing-impaired person 400.

For example, by arranging multiple vibration parts 40 on the left and right, the direction of the sound source can be determined, so that the direction of the sound source, such as the sound of a car, the sound of a railroad crossing, the sound of a traffic light, or the direction of the person you are talking to, can be easily determined, thereby further reducing the mental burden on the user.
Even if there is only one vibration section 40, it is possible to adjust the left and right hearing separately by modulating the frequency band of the sound with the amplification adjustment section 20.

As described above, the hearing aid 100 of embodiment 1 utilizes the vibration of the bone 5, and has a sound collection unit 10 that collects sound, an amplification adjustment unit 20 that amplifies the sound collected by the sound collection unit 10, a transmission unit 30 that transmits the sound amplified by the amplification adjustment unit 20 as a signal, and a vibration unit 40 that is placed in the oral cavity and vibrates the bone 5 with the signal from the transmission unit 30.

According to this configuration, by disposing the vibration unit 40 in the oral cavity, a foreign object is not embedded in a part of the body (skull, etc.) of the hearing-impaired person from the outside, so the hearing-impaired person feels safe and secure, the psychological hurdle of wearing the hearing aid 100 is lowered, and the hearing-impaired person can live a life that is favorable in terms of mental health. In addition, a hearing aid that does not cause local infections on the skin can be provided.

The vibrating part 40 of the hearing aid 100 is a metal piece that is stuffed into a cavity 6 formed in the tooth 1A.
With this configuration, a highly versatile hearing aid can be obtained that can be used not only within the implant 200 but also within the cavity 6 of the tooth 1A.

The vibration unit 40 of the hearing aid 100 is an implant 200 that is placed in the oral cavity.
With this configuration, vibrations are reliably transmitted from the vibration unit 40 built into the implant 200 to the bone 5 that receives the vibrations, providing a hearing aid that the hearing-impaired person 400 will not miss. In addition, sounds from audio devices such as smartphones, mobile phones, televisions, and personal computers can be heard directly through the hearing aid 100.

The hearing aid 100 has a plurality of vibration units 40 arranged in the oral cavity.
With this configuration, even if one vibration section 40 fails or experiences other problems, the other vibration sections 40 can compensate, thereby making it possible to obtain a highly reliable hearing aid 100.

The vibration section 40 of the hearing aid 100 can freely change the frequency of the signal.
With this configuration, it is possible to focus on the sound that the hearing-impaired person 400 (user) wants to hear by changing the frequency of the sound. In addition, by changing the frequency, it is also possible to cancel noise that causes anxiety to the user (hearing-impaired person or normal person).

The sound collection unit 10, the amplification adjustment unit 20, and the transmission unit 30 of the hearing aid 100 are disposed outside the oral cavity.
With this configuration, maintenance and inspection of the hearing aid 100, and charging or replacing the battery 13, etc. can be easily performed, and a hearing aid 100 with excellent product reliability, durability, and convenience can be provided to the user (hearing-impaired person) 400.
Although the hearing aid 100 has been described as being used by a person with hearing loss, the hearing aid 100 can also be used by a person with normal hearing to encourage other normal hearing people to drive safely, for example, while driving a car. The vibration unit 40 may also be embedded in a mouthpiece. The hearing aid 100 can also be used as a bone conduction earphone.

1: Crown 1A: Tooth 2: Abutment 3: Implant body 4: Gums 5: Bone 6: Inside cavity 10: Sound collecting unit 13: Battery 20: Amplification adjustment unit 30: Transmission unit 40: Vibration unit 100: Bone conduction hearing aid (hearing aid)
200: Implant 400: User (Hearing impaired)

Claims (3)

A bone conduction hearing aid that uses bone vibrations,
A sound collecting part that is located outside the oral cavity and collects sound;
an amplification adjustment unit that amplifies and adjusts the sound collected by the sound collection unit as a signal;
a transmitting unit that transmits the sound amplified by the amplification adjustment unit as a wireless signal;
a vibration unit that is placed in the oral cavity, receives the wireless signal from the transmission unit, and transmits the sound vibration by vibrating the bone through the tooth root or the artificial tooth root ;
having
A bone conduction hearing aid , wherein the vibration section is embedded inside a core that is inserted into the tooth root, or inside an abutment that is inserted into an implant body . The bone conduction hearing aid according to claim 1 , wherein a plurality of the vibration units are arranged in the oral cavity. 3. The bone conduction hearing aid according to claim 1, wherein the amplification adjustment section is capable of freely changing the frequency of the signal.