Implantable electronic hearing aid

Abstract

An electronic hearing aid device for enabling persons having loss of hearing due to a nonfunctioning malfunctioning inner ear (Cochlea), but have having a responsive auditory (acoustic, or eighth cranial) nerve, to hear by way of an electronic device including a microphone for receiving audio signals connected to an amplifier for converting the audio signal into an analog voltage signal. The analog voltage signal is filtered by a series of filter networks which separate the analog voltage signal into a plurality of frequency component signals each having a predetermined frequency range within the audio spectrum. The component analog voltage signals are then converted into digital pulse signals having the same frequency as the component voltage signal, which are fed to the auditory nerve by way of implanted platinium platinum (or other) wires, wherein the digital pulse signals more accurately simulate the natural sound signals transmitted to the brain for interpretation.

Description

ORIGIN OF THE INVENTION

The invention described herein was made by an employee of the United States Government and may be manufactured and used by or for the Government for governmental purposes without the payment of any royalties thereon or therefor.

representation of a non-functioning malfunctioning inner ear, but who still have a responsive auditory nerve system. The proposed device of the present invention will enable these persons to hear by the transmitting of electrical impulses directly to the auditory nerve system through electrode wires electrodes implanted in the auditory nerve such system. The non-functioning malfunctioning cochlea will can be bypassed altogether. The exact method and most appropriate access to the acoustic nerve must should be experimentally researched and established by the medical profession and those accustomed to the art (otologists). It is essential for optimum performance that electrical insulation be maintained between one implanted electrode and another within the acoustic nerve system. In this manner, only those groups of nerves intended for stimulation by a limited band of frequencies will be activated.

It is considered a major fault of prior attempts at electrode implantation to insert an electrode or electrodes into the cochlear fluid through the oval or round window. The cochlear fluid is not an insulating liquid, and insulation is therefore not maintained between channels.

In addition, prior hearing aid devices have applied analog voltages have been applied to the electrodes. The cochlea (inner ear) does not have the capability to convert analog voltages to digital pulses for stimulation of acoustic nerve endings. A surgical process for implanting such electrodes in the cochlea is discussed more fully in an article entitled "The Electric Ear" appearing in the April 1974 issue of Newsweek magazine.

It is to be understood, of course, that other techniques may be utilized for transmitting the electrical impulses generated by the electronic device of the present invention, and that the electronic device of the present invention contemplates application to other types of hearing problems.

Referring now in more detail to the drawings, FIG. 1 illustrates a schematic diagram of an electrical circuit embodying the electronic device of the present invention for receiving external audio sound waves and converting the sound waves into digital pulsed electrical stimuli which are transmitted over through the implanted electrodes. A receiver means 10 is provided by a miniature electronic microphone for receiving the external audio signals or sound waves and converting the audio signal into an analog audio voltage signal. The output 10a of the microphone receiver 10 is connected to the input 12a of a conventional amplifier circuit 12 for amplifying the analog voltage signal. A plurality of frequency filter networks 14a through 14j each has an input connected to an output 12b of the amplifier means 12 for receiving the amplified voltage signals therefrom. Each of the frequency filter networks 14a through 14j provides a band-pass filter for passing only a component voltage signal having a frequency of the range to which each respective network is limited.

In the preferred illustrative embodiment, each frequency filter network provides a band-pass filter in increments or "blocks" of 500 hertz (HZ) over the audio spectrum between 0 and 5,000 hertz. Thus, filter network 14a is designed to pass a signal in the frequency range of from 0 to 500 hertz, filter 14b from 500 to 1,000 hertz, filter 14c from 1,000 to 1,500 hertz, network filter 14d from 1,500 to 2,000 hertz, filter 14e from 2,000 to 2,500 hertz, filter 14f from 2,500 to 3,000 hertz, filter 14g from 3,000 to 3,500 hertz, filter 14h from 3,500 to 4,000 hertz, filter 14i from 4,000 to 4,500 hertz, and filter 14j from 4,500 to 5,000 hertz. The number of frequency networks used and hence frequency blocks provided for depends on what correlation is to be achieved with natural electrical stimuli of the auditory nerve systems and the number of portions thereof that are to be stimulated.

The composite analog voltage signal coming from amplifier 12 will be passed through the various filter networks 14a through 14j and will be broken down into component signals of 500 hertz "blocks" each, which will be contained within the normal audio spectrum between 0 and 5,000 hertz. The filter networks 14a through 14j may be any conventional band-pass filter such as a crystal or tuned circuit. One suitable type of network circuit is manufactured by the Krohn-Hite Corporation of Avon, Mass., series 3340, specifically model 3343R. This filter represents one of the best in laboratory equipment and exceeds the requirements for the purposes of this invention except in special applications.

Other suitable filter networks may be had within the integrated circuitry art to provide miniature frequency filter networks of the required complexity and capability within the size of a "body" type aid.

One such filter for each of the 10 channels in this instance could be constructed with the use of a resistance-capacitance twin-T band pass band-pass filter section operating into a high gain tuned audio amplifier, producing a so-called "active filter".

All 10 channels of this type "active filter", along with the microphone and primary audio amplifier, could be packaged within a "body" type hearing aid case, and even within the volume of behind-the-ear and eyeglass aid aids.

The output of each frequency filter network 14a through 14j is connected to a corresponding analog-digital analog-pulse converter circuit 16a through 16j. Each of the analog-digital analog-pulse circuits receives the analog frequency component signal coming from the associated frequency filter network and converts the frequency component signal into a digital pulse component signal having a series of digital pulses of the same frequency as the analog frequency component signal. The analog-digital analog-pulse converter circuit shown generally at 16a through 16j may be any conventional analog to digital pulse converter circuit which will may rectify the analog voltage signal, providing a series of digital pulses occurring at the same frequency as the original analog signal.

One suitable converter circuit is comprised of a simpled simple diode rectifier D1, or and a transistor gating circuit (or trigger, or switch), whereby a transistor T1 is biased at or slightly below cutoff normally.

When an analog signal from the appropriate filter network (channel) is applied, it will be rectified by the transistor (or diode) switching circuit. Only the positive going portion of the audio sine wave will cause the transistor to conduct. The turn-on threshold of the transistor can therefore be adjusted to allow control of input analog voltage levels, and thus control of background noise.

Voltage level control and time duration limits may also be included in the transistor output (Collector) (collector) circuitry, thus maintaining strict control of voltage levels and pulse widths applied to the acoustic nerve system.

Each of the analog-digital analog-pulse converter circuits 16a through 16j is connected to a pin connector member 18 having a plurality of pin connections 20a through 20j connected to the corresponding analog-digital analog-pulse converter circuits 16a through 16j for receiving the digital pulsed component signal therefrom. The pin connector member 18 is preferably in the form of a female connector 18a which may be implanted in the area of the mastoid bone of the outer ear such as shown in FIG. 1, and a male connector member 18b wherein the pins 20a through 20j are carried by the male connector for insertion into a plurality of matching insert channels 22a through 22j carried within the female connector 18a. In this manner, the electronic circuit elements of the present invention may be removably attached and replaced as a hearing aid device.

It should be noted that another method of female connector implantation could might be accomplished by placing it in the ear canal. Implantation in the ear canal may be more cosmetically acceptable than location in the mastoid area.

Connected to the insert channels 22a through 22j of the female coupling 18a are a plurality of corresponding electrode members 24a through 24j which have their remote end ends surgically implanted adjacent portions of the auditory nerve system B of the inner ear along the basilar membrane C at points a through j. The electrodes transmit each component digital pulse pulsed signal at the same portion of the auditory nerve normally accustomed to transmitting like signals in the normal hearing process for interpretation in the hearing center of the brain. Thus, each individual block of digital impulse stimuli will be applied directly to the auditory nerve system by way of the imbedded electrodes 24a through 24j which are preferably in the form of platinum wires.

The It is proposed that the pulsed stimuli of the electronic device constructed in accordance with the present invention proposes that the digital stimuli will more naturally and accurately simulate the functioning of the electrical nature of the cochlea D output to the auditory nerve system. Of course, the microphone 10, the amplifier 12, the frequency filter networks 14a through 14j, and the analog-to-digital analog-to-pulse converter circuits 16a through 16j, and a suitable power source will be appropriately packaged external to the patient in a package housing A.

It is important to note that the greater the number of individual channels (wires), and thus the greater the synthesis of the input audio signal, then the better the fidelity, or true reproduction of the input signal (s), or tone (s).

The ten individual channels presented in this invention may exceed the current practical state-of-the-art in electrode implantation within the acoustic nerve. The number ten is therefore illustrative, and not intended to be a limitation to the concept.

Likewise, neither is utilization of the audio spectrum between 0-5,000 hertz.

The most beneficial frequency range required by various patients will vary in each case and must should be determined by an audiologist.

Thus, it can be seen that an advantageous construction for a hearing aid device can be had in accordance with the present invention for aiding a person having a hearing disability of the inner ear. By breaking down a composite audio signal into component "blocks" of a predetermined frequency range and digitizing converting each block component of the audio signal into a series of pulses for direct application to the auditory nerve system by way of imbedded platinum wires electrodes, a more natural and accurate simulation of the true functioning of the inner ear can be accomplished.

While a preferred embodiment of the invention has been described, using specific terms, such description is for illustrative purposes only, and it is to be understood that changes and variations may be made without departing from the spirit or scope of the following claims.

Claims

1. An electronic hearing aid device for use in aiding a person having a non-functioning malfunctioning inner ear mechanism comprising:

receiver means for receiving an external audio signal and converting said signal into an analog voltage signal;

amplifier means connected to said receiver means for receiving said analog voltage signal and amplifying said voltage signal;

a plurality of frequency filter networks each having an input connected to an output of said amplifier means for receiving said amplified voltage signal and filtering said analog signal into a number of separate frequency component signals corresponding to a predetermined frequency range of each respective filter network;

analog-digital analog-pulse converter circuit means connected to the output of each filter network for receiving each said frequency component signal and converting said signal into a digital pulsed component signal; and

a plurality of elongated electrode members each having one end connected to an output of one of said converter circuit means with the remote end thereof adapted for being implanted adjacent a portion of the auditory nerve system of the inner ear for transmitting said digital pulsed component signals for interpretation in the hearing portion of the brain.

2. The device as set forth in claim 1 wherein said analog-digital convertor analog-pulse converter circuit means converts said frequency component signal into a series of digital pulses occurring at the same frequency as said frequency component signal.

3. The device as set forth in claim 1 wherein said electrodes are platinum wires.

4. The device as set forth in claim 1 further comprising pin collector means having a plurality of pins for connection of said output of said converter circuit means and said one end of said electrodes.

5. The device as set forth in claim 4 wherein said connector means includes a female connector for being implanted adjacent the mastoid bone portion of the outer ear having a plurality of pin channels connected to said electrodes and a male connector having corresponding pin connections connected to said converter circuit outputs for insertion into said pin channels of said female connector.

6. An electronic hearing aid device for aiding a person having a non-functioning malfunctioning inner ear comprising:

receiver means for receiving an audio signal and converting said signal into an analog voltage signal;

amplifier means connected to the receiver means for receiving said analog voltage signal and amplifying said signal;

a plurality of frequency filter networks having an input connected to the output of said amplifier means for receiving said amplified analog voltage signal and separating said analog signal into frequency component signals having frequencies corresponding to a predetermined frequency range of each respective filter network;

an analog-digital analog-pulse converter network connected to the output of each of said filter networks for receiving said analog frequency component signal therefrom and converting said frequency component signal into a digital pulsed component signal having a series of digital pulses of the same frequency as the analog frequency component signal and being of related amplitudes;

a pin connector member having a pin connection connected to an output of each analog-digital analog-pulse filter network for receiving said digital pulse signals; and

a plurality of electrode members for being implanted adjacent portions of the nerve of the inner ear with the remote end of said electrodes being connected to each of said pin connections so that each component digital pulse signal will be applied at the same portion of the nerve normally accustomed to transmitting like signals in the normal hearing process for interpretation as sound.

7. An electronic hearing aid for use in aiding a person having a malfunctioning hearing mechanism to hear comprising:

receiver or microphone means for receiving an external audio signal and converting said signal into an analog voltage signal;

amplifier means connected to said receiver means for receiving said analog voltage signal and amplifying it;

a plurality of filters, each having inputs thereof connected to the output of said amplifier means, for receiving said amplified voltage signal and filtering said signal into a plurality of separate component signals corresponding to separate frequency ranges;

analog-pulse converter circuit means connected to the output of each filter network for receiving each said frequency component signal and converting said signal into a pulsed component signal; and

a plurality of electrodes, each being connected to an output of said converter circuit means and having at least a portion thereof adapted for implantation adjacent a portion of the auditory nerve system, so that the electrodes transmit pulsed frequency component signals to the auditory nerve system for interpretation in the hearing portion of the brain.

8. A device according to claim 7 wherein the analog-pulse converter circuit is one which produces a unipolar pulsed component signal.