UA63226A - Method for monitoring normal parameters of acoustic-and-mechanical system of middle ear and computerized ear-spectrometer for its realization - Google Patents

Abstract

The method for monitoring the normal parameters of the acoustic-and-mechanical system of the middle ear has been proposed. The acoustic reflection coefficient relating to the reflection of the acoustic pulse from the tympanic membrane as a function of the frequency is measured. The coefficient is then transformed into the non-dimensional parameter û the standard factor equaling to unity when the hearing is normal. The ear spectrometer for monitoring the normal parameters of the middle ear comprises the acoustic probe with the ear-phone and the microphone, the generator of the probing signal, measuring circuit, the sound-guide, the permanent memory, the random access memory, the display, the printer, the key-board, and the mouse.

Description

Description of the invention

The proposed invention belongs to methods and means for controlling the functional state of system 2 of the human middle ear and can be used for express control of the norm of the acousto-mechanical system of the ear to differentiate its disorders from the sensorineural system, as well as in test trials in functional diagnostics, with - conducting mass preventive examinations, examinations of infants and children.

Among the objective (without the participation of the subject) methods of hearing examinations are currently used: acoustic impendasometry in its modern version of single- or multi-frequency tympanometry; registration of 70 auditory evoked potentials (SVP); otoacoustic emission registration (UAE); Unconditional reflex audiometry of infants. For the last method, it is only important to establish the fact that the children have deviations in hearing from the norm |Lysovsky V.A., Eliseev V.A. Hearing aids and apparatus. - M.: Radio and communication, 1991 - 192 p.

A prerequisite for the first 3 methods is the sealing of the external auditory canal and the introduction into it of a continuous sound signal with a frequency of 226 Hz in single-frequency and 226, .660, 1000 Hz - in multi-frequency 12 tympanometers, or a sound stimulus of a certain intensity, duration and spectral composition during registration

GCC or UAE. Values measured in most cases are averaged over time |Lysovsky V.A., Eliseev

V.A. Hearing aids and apparatus! - M.: Radio and communication, 1991 - 192 p.

The method of monitoring the norm of the middle ear system, which is used in a multi-frequency acoustic ear impedance meter, is the closest in technical essence to the claimed one, which is based on the acoustic impact on the middle ear of the patient by a continuous signal with a frequency of 226 Hz or 226 Hz, 660, 1000 Hz, and continuous measurement of the dependence of the equivalent volume of the middle ear, with the patient's hermetically closed external auditory canal, from the pressure difference in the external auditory canal and atmospheric pressure created by the pneumatic system of the impedance meter. Approximate classifications of tympanograms are used to identify deviations in the middle ear; the classifications according to Jerger and Liden |/Lysenko received the most recognition

Ohm. Modern methods and means of research of human hearing. -K.: KVITS, 2002.-176 p.|. "

This method has a significant drawback, which is that the large intersubject discrepancy of the equivalent volume of the middle ear can cover deviations from the average values that are characteristic of the norm and various types of pathologies, which does not allow to reliably diagnose the pathology only on the basis of the tympanogram. There is no objective quantitative parameter of the state of the middle ear system. In addition, a continuous signal is used for obtaining tympanograms, and the measured value is averaged over time. This does not allow obtaining a change in the equivalent volume of the middle ear both in the process of fast (for example, swallowing) movements, and in the process of slower influences (for example, drug tests). high school

The invention is based on the task of improving the method of monitoring the normality of the middle ear system by measuring the coefficient of reflection of the sound pulse from the eardrum as a function of frequency,

That ensures an increase in the reliability of diagnosis of middle ear pathologies, and makes it possible to carry out diagnostics in real time.

The task is solved by the fact that when implementing a method of monitoring the norm of the middle ear system, which is based on the acoustic impact on the patient's middle ear and measuring the main parameters of the ear, according to /"F, which diagnose the state of his system, according to the invention, the new thing is that in quality parameters of the middle ear C 50 measure the coefficient of reflection of the sound impulse from the eardrum as a function of frequency, c convert it into a dimensionless parameter, which is a combination of the flexibility of the eardrum, active

From" components of the impedance of the middle ear at the lower resonant frequency and the volume of the tympanic cavity - the norm factor, which for a normal ear is equal to one.

Measurement of the coefficient of reflection of the sound pulse from the tympanic membrane as a function of frequency, and its transformation into a dimensionless parameter - the norm factor, i.e.: od o Mekv(226) PM elor. (226) o ' mu 0 where m is the volume of the tympanic cavity, provides an increase in the reliability of diagnosis of pathologies 4») bor. middle ear.

The use of pulse signals allows, by changing their frequency and follow-up time, to obtain a change in the 22 parameter of the norm and resonance frequency both in the process of fast (for example, swallowing) movements, and in the process of slower influences (for example, drug tests). The filling frequency of sound pulses is selected equal to 660 Hz (for men) or 1000 Hz (for women). These frequencies are close to the resonant frequencies of the middle ear of a man or woman. The duration of the pulses is chosen to be equal to 1.5 periods at the selected frequency, i.e.: tp 15 vBO no tms o, or x 151000 emo o The frequency range of such a pulse at the level of 0.707 from the maximum 60 is equal to: zm 1 - V og or oAge 100o tto i.e. it occupies the range from 440 to 880 Hz or from t 15 15 665 to 1335 Hz. The number of parcels and the intervals between them are chosen depending on the interval of the change of the process under investigation. because the acoustic ear impedance meter, which implements the method of monitoring the state of the middle ear system discussed above and is selected as a prototype, is the closest in technical essence to the proposed one.

The acoustic ear impedance meter contains a sounding signal generator (a tone with a frequency of 226, 660, or 1000

Hz), connected by the output to the telephone, which emits a signal through a narrow tube of the sound canal into the external auditory canal, a microphone with a probe tube for receiving the signal reflected from the eardrum, connected by the output to the input of the measuring system, which amplifies the signal, filters and rectifies it, an indicator, the input of which is connected to the output of the measuring system, the output recorder, the input of which is also connected to the output of the measuring system, a compressor for changing the pressure in the external auditory canal, which transmits compression or vacuum to the external auditory canal by means of a tube, manometer for pressure control, connected to the output of the compressor, electric motor for driving the compressor, connected by the output to the input 7/0 of the Compressor and to the input of the output recorder, for recording the tympanogram |Lysovsky V.A., Eliseev V.A.

Hearing aids and apparatus! - M.: Radio and communication, 1991 - 192 p.|.

The disadvantages of the acoustic ear impedance meter are: the need to completely seal the external auditory canal and create an excess or lack of static pressure in it, which is especially difficult and dangerous for babies; the need to average data over the time of measurement, which, together with the time of preparation for measurements, does not 7/5 allow them to be carried out in real time.

The invention is based on the task of improving the ear echo spectrometer, in which, by introducing between the acoustic probe and the external auditory canal a sound duct made in the form of a flexible tube of a calculated length with a diameter equal to the diameter of the external auditory passage, and the air pressure in the sound duct and the ear is equal to atmospheric, it is ensured simplifying the diagnostic procedure and increasing its safety for babies, and it becomes possible to carry out diagnostics in real life.

The problem is solved by the fact that in the ear echo spectrometer for monitoring the normality of the middle ear system, which contains an acoustic probe in which a telephone and a microphone are located, a sounding signal generator and a measuring system, according to the invention, what is new is that it additionally has a sound pipe inserted into it, which is made in the form of a flexible tube, in the elastic entrance of which an acoustic probe is inserted, and its exit is made with the possibility of tight installation in the external auditory canal of the patient, and the measuring system is made on the basis of a computer, and contains a sound board connected by a bidirectional bus with by a central processor, the output of which is connected to the telephone input, and the microphone input "ip" is connected to the microphone output, a non-volatile memory device connected by an output to the central processor, a non-volatile memory device, with connected by a bidirectional bus with the central processor, the display and the printer, connected by inputs with (o with the central processor, keyboard and mouse, connected output with the central processor, while the probing signal generator is made in the form of a hard disk connected by a bidirectional bus with the computer's central processor. with

The drawing shows the structural diagram of the proposed computer ear echo spectrometer.

The computer ear echo spectrometer contains a sound pipe 1, which is made in the form of a flexible tube, into which an acoustic probe C is inserted, which contains a telephone 4 and a microphone 5, and its output is made with the possibility of tight installation in the external auditory passage of the patient 2, the measuring system is made on the basis of the computer 14, and which contains a sound board 10, connected by a bidirectional bus to the CPU 6, the output "oc" of which is connected to the input of the telephone 4, and the microphone input "ip" with "connected to the output of the microphone 5, non-volatile storage device (VSD) 7, connected to the output from the CPU 6, random access storage device (RAM) 8, " connected by a bidirectional bus to the CPU 6, display 11 and printer 12 , connected by the inputs to the CPU b, the tamish keyboard with 13, connected by the outputs to the CPU 6, the probing signal generator, made in the form of a hard disk 9, connected by a bidirectional bus to the central processing unit (CPU) 6 of the computer. ;" Let's consider the method of express control of the norm of the acousto-mechanical system of the ear on the example of the operation of a computer ear, echo spectrometer. Electric pulses with amplitude Ao from the output "ots!" sound card 10 of the computer 14 are sent to the telephone 4. The source of electrical pulses is the recorded, using

Ge" keyboard and mouse 13, on the hard disk 9 in real time function: у - у | zipsya BO I) at dk 227 107 o zabo u -utvipsrya 1000 4) at dhkt18l107s 00 The number of parcels and the intervals between them are selected depending on the interval of change of the process under investigation. Phone 4 converts electrical impulses into acoustic ones. The acoustic pulses emitted by the telephone 4 simultaneously enter the microphone 5, which converts them into direct electrical pulses, which enter the microphone input "ip" of the sound board 10, and

F further into RAM 8 of computer 14, and to the entrance of sound duct 1, through which they reach the tympanic membrane of the human ear and are reflected from it. The characteristic length of sound attenuation in the sound duct 1 with a diameter of Я -Obosm o, which is approximately equal to the diameter of the external auditory canal 2, is equal to 1 -ББОГЦ. : 29 yu - |v Yasya I stu VELO Zdayu nzyaM r noz 16.1077.415 10 or at 1-1000 Гг4 s: ho e10Yam where and 122 kg/m, - 342.107 m/s - air density and speed of sound in it, ш- 185 0 kg/m's - air viscosity coefficient. The length of sound line 1 is chosen equal to 1 m. At 60, the attenuation coefficient in sound pipe 1 at frequencies is 440; 660; 880 Hz equals 0.937; 0.926; 0.914, and at frequencies of 665, 1000, 1335 Hz it is equal to 0.925; 0.918; 0.891. The change in the attenuation coefficient in the selected ranges "255 from the value at 660 or 1000 Hz can be neglected in comparison with the changes in the reflection coefficient calculated from the expression for the normalization factor: 0.89-0.71-0.84, i.e. 0.18/0 .71-0.25 (2595). The reflected acoustic pulses (echo pulses) through the sound channel 1 arrive at the microphone 5, their amplitude is equal to (2 (put 3 and b5 - the attenuation coefficient in the sound channel 1, g) - the reflection coefficient from the tympanic membrane.

Microphone 5 converts acoustic echo pulses into electrical ones. Electric echo pulses from the microphone 5 enter the microphone input "ip" of the sound board 10, and then into the RAM 8 of the computer 14, which already contains information about the amplitude of the direct pulses, it is equal to: Koovv (Pt de Coeur (TP "calculated damping factor 9 in sound pipe 1 ( Cor (bBO)- 0.926 0 - for men, Cor 10003 - 0.919 - for women). In CPU 6, with the help of, for example, the application package Mayar, there are dependences of the reflection coefficient on the frequency, which are displayed on the screen display 11, and which are entered in OZP 8: x- Kk? (pt Per Ou . Necessary values

Hans and Tr are transferred to the printer 12. By changing the frequency and time of following pulses, it is possible to obtain a change in the normal parameter and resonant frequency both in the process of fast movements (for example, swallowing) and in the process of slower influences (for example, drug tests). PZP 7 is used by CPU 6 to store the basic I/O system VIO5, which is part of the operating system UUipdomuv, which, in turn, is permanently located in RAM 8 and organizes the management of all units of the computer 14 and its interaction with the doctor, who 7/ 5 carries out the diagnostic procedure.

The program for processing direct and echo pulses in CPU 6: 1) after the arrival of the echo pulse and direct pulse, their spectra are found with an interval of 22 Hz (20 frequencies in the range of 440-880 Hz or 33.5 Hz (20 frequencies in the range of 665-1335 Hz ); are recorded in RAM 8;

C) there is the frequency dependence of the reflection coefficient from the tympanic membrane chu (A yuyu (put Per ut ; the values of Khin ri | ii are displayed on the display screen 11; 4) if several pulses are used, then the procedure similar to paragraphs 1-3 is carried out with each of the pulses ; in each of the spectra there is 3U(i,i) with entry in OZP О8 хюно, Про, ЮИ ; after the end of the series of dependences, the kines and trives are displayed on the display screen 11 and can be printed by the printer 12; 5) there is the ratio of the value of the active component of the impedance K to the value of air impedance in the plane of the tympanic membrane 24 dosdiZed, 1 hudi deya MN. 1- Khwin Ge) de ved, - 84,107 m2 (for men) and Vl. - 130 lo m2 (for women) - the area of the tympanic membrane; to 12 sch 3. 1 1 1 . kg/m; so- 34710 2 m/s - air density and sound speed in it; сч 6) there is a Q-factor according to the value of 40 Hz) for men or 5 Hz) for women, i.e., with a frequency of 0.865) their - 4401660 - BBOI1000 - 06651; , (Se) a. ve) and 0.71. 1st (0.533 6) there is a norm factor: « 1 ,

And M. --- - I - - with MT Mel, and if it is not equal to 1, a conclusion is made about the presence of pathologies of the human middle ear. "» If necessary, the selected X(I) dependence can be processed to find the parameters of the middle ear: the mass of the auditory ossicles together with the eardrum and its flexibility (equivalent volume): 8 b pmek.oo

F ktode o where tdneh trobo. Vl. - 42107 Kkg/ som Vl sh-.a.5 ; MG, and that -vbB.107.2OYA Region. with 50 In 1 place Mel. ----- se diolnn» NI

The use of the invention makes it possible to increase the reliability of diagnosis of middle ear pathologies, makes it possible to carry out diagnostics in real time, simplifies the diagnostic procedure and increases its safety for babies.

Claims (2)

Formula of the invention 60, Sh, 1. The method of monitoring the norm of the middle ear system, which is based on the acoustic impact on the middle ear of the patient and the measurement of the main parameters of the ear, which diagnose the state of his system, which differs in that the parameters of the middle ear measure the coefficient of reflection of the sound impulse from the eardrum as a function frequency, turn it into a dimensionless parameter, which is a combination of flexibility 65 of the tympanic membrane, the active component of the impedance of the middle ear at the lower resonant frequency and the volume of the tympanic cavity - a norm factor, which for a normal ear is equal to one. 2. An ear echo spectrometer for monitoring the normality of the middle ear system, containing an acoustic probe in which a telephone and a microphone are located, a probing signal generator and a measuring system, which is distinguished by the fact that a sound pipe, which is made in the form of a flexible tube, is additionally introduced into it, in an elastic the input of which has an acoustic probe inserted, and its output is made with the possibility of tight installation in the external auditory canal of the patient, and the measuring system is made on the basis of a computer and contains a sound board connected by a bidirectional bus to the central processor, the output "eye" of which connected to the telephone input and the "ip" microphone input connected to the microphone output, a non-volatile memory device connected by an output to the CPU, a random access memory device connected by a bidirectional 7/0 bus to the CPU, display and printer connected by inputs to the central processing unit, keyboard and mouse connected by outputs to the central processing unit, while the generator with the onding signal is made in the form of a hard disk connected by a bidirectional bus to the central processor of the computer. « (Se) Зо сч с (зе) (Se) - and? (o) (95) name) name) 4) 60 b5