RU2452390C1 - Method of dinamic multi-spiral computed tomographic diagnostics of otosclerosis - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to medicine, namely to otolarytngology and radiodiagnostics, and is intended for early diagnostics of otosclerosis. Performed is multi-spiral computed tomography with three-dimensional dynamic scanning with section thickness 0.5 mm and interval 0.25 mm in axial projection. Simultaneously performed is impact with probing audio signal, exceeding perception threshold by 15-20 dB, and with test frequency 1000 Hz on middle ear structures with 1 second interval for 4-5 seconds. Multiplanar and three-dimensional reconstructions are built. If it is determined that volume of movements of stirrup stapes in oval window niche.

EFFECT: method makes it possible to increase accuracy of diagnostics of otosclerosis

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Description

The invention relates to medicine, in particular to otorhinolaryngology and radiation diagnostics, and can be used for early diagnosis of otosclerosis, namely osteosclerotic changes in the base plate of the stapes.

Otosclerosis is a disease that affects the bone capsule of the labyrinth. Progressive conductive hearing loss, characteristic of otosclerosis, develops as a result of the formation of an otosclerotic lesion in the oval window, which gradually reduces the mobility of the foot plate of the stapes and eventually immobilizes it (Plester D., Hildmann H., Steinbach E. Atlas der ohrchirurgie - Stuttgart: Kohlhammer, 1989 . - 174 s.).

The diagnosis of otosclerosis is traditionally established by eliminating other causes leading to conductive hearing loss with unchanged eardrum. For a more accurate diagnosis, visualization of the stapes, determination of its mobility is necessary.

Examination of patients with otosclerosis includes otoscopy, speech examination of hearing, tuning forks, audiometry, impedancemetry (Soldatov IB, Stegunina L.I., Khrappo N.S., Mirkina A.E. Functional diagnosis and issues of modern surgery for otosclerosis. - M .: Medicine, 1974). However, traditional methods have the following disadvantages.

With otoscopy, the doctor does not see any changes or there are so-called indirect signs of otosclerosis - wide external auditory canals, decreased or absent sulfur secretion (Toynbing-Bing symptom), decreased skin sensitivity of the external auditory canal and eardrum, thinning of the tympanic membrane (transillum symptom through the tympanic membrane of the hyperemic mucous membrane of the promotorium). It is understood that the symptoms described are not pathognomonic. Data from a hearing study in patients with otosclerosis depend on the form of the disease and on the stage. So, with a tympanal form, a significant decrease in hearing acuity is noted in the type of violation of air conduction with relatively well-preserved bone conduction. When examining hearing with tuning forks, damage to the sound-conducting apparatus is determined (sound through the bone is lateralized to the side of the worse hearing ear, Rinne and Jelle experiments are negative). With a cochlear form, progressive hearing loss is noted not only in low, but also in high tones, bone conduction is shortened.

Audiometry is a study necessary to determine the degree of hearing loss. The result of auditory tests is a graph (audiogram) that reflects the nature and degree of hearing impairment in humans. However, it is not possible to determine which pathology of the sound-conducting system leads to conductive hearing loss.

Impedanceometry is not too helpful in this - an objective technique that allows you to study the static and dynamic characteristics of the sound-conducting system of the hearing organ. In clinical practice, two impedancemetry techniques are most often used - tympanometry and acoustic reflexometry. Tympanometry allows you to evaluate the mobility of the eardrum and auditory ossicles. Acoustic reflexometry can detect contractions of the auricular muscles in response to sound stimulation. Impedansometry does not allow visualization of the pathological process, which affects the choice of tactics and volume of surgical intervention.

The prototype of the present invention can be considered classical computed tomography of the temporal bone (Valvassori GE, Buckingham RA Radiology of the temporal bone. In: Valvassori GE, Potter GD, Hanafee WN, Garter BL, Buckingham RA (eds). // Radiology of the ear, nose and throat. Thieme, Stuttgart, 1992). The studies are carried out according to the bone reconstruction program in a step-by-step mode with a slice thickness of 1 mm, the tomograph step is 1 mm, the voltage is 120 kV, and the current strength is 300 mA. The first series of sections is carried out in the axial plane, the second series of sections is in the coronary projection.

This diagnostic method allows you to obtain information about the condition of the ligamentous apparatus of the tympanic cavity, allows you to evaluate the density characteristics of the auditory ossicles, however, it is impossible to assess the mobility of the auditory ossicles chain, in particular the stirrup base plate in the niche of the oval window.

The objective of the invention is to improve the accuracy of diagnosis of otosclerosis.

This problem is solved by the method consisting in the fact that they carry out multispiral computed tomography with volume dynamic scanning with a slice thickness of 0.5 mm and an interval of 0.25 mm in axial projection, while simultaneously acting with a sounding sound signal exceeding the perception threshold by 15-20 dB and with a test frequency of 1000 Hz, on the structures of the middle ear with an interval of 1 second for 4-5 seconds, build multi-planar and three-dimensional reconstructions and, when determining the decrease in the range of motion of the foot plate of the stirrup, the oval in the niche In comparison with the norm or absence of the range of motion of the base plate of the stapes, a otosclerosis is diagnosed with a window.

In practice, the diagnostic method is as follows.

1. The patient’s head is located in a standard head stand, fixed to prevent a change in position.

2. A system is inserted into the external auditory meatus that delivers sound vibrations of a given frequency and intensity to the structures of the middle ear. The sound delivery system is based on an impedance audiometer (Impedance Audiometer АТ235h, Interacoustics, Denmark) with a built-in audiometry unit. Two air telephones are connected to the connector of the audiometer of the specified apparatus in a modification of the in-channel sound conduction with silicone tubes attached to them for conducting sound. The tubes, in turn, are connected to disposable earbuds that fit tightly into the ear canal of the test ear. For the purity of the test and the elimination of sound loss, the absolute tightness of the system is required. In cases of the patient having hypertrichosis, excess hair growing in the external auditory meatus must be removed in advance, because they can create an air gap between the earmold and the skin.

3. To mark the study area perform a tomogram. Tomography begins from the lower edge of the mastoid process and ends at the level of the upper edge of the mastoid process.

4. Tomography is carried out according to the protocol:

MSCT protocol of the temporal bone.

Tomography mode surround dynamic Cut thickness 0.5 mm Gantry Tilt 0 Field of study about 4 cm Voltage 80 kV Amperage 300 mA Type of reconstruction bone

1. After performing tomograms, the first series of sections is carried out in axial projection. Scanning progression from the temporal bone to the cranial vault. At the same time, in the manual mode of audiometry for 4-5 seconds, a probing sound signal is intermittently supplied to the test ear with a test frequency of 1000 Hz and an intensity exceeding the perception threshold by 15-20 dB (i.e., sound is transmitted for the first second, to the second second is not served, etc.). The sound intensity is selected on the basis of a previously made audiogram or on the basis of a test audiogram conducted immediately before MSCT examination.

2. Then, the investigated temporal bone is reconstructed with a 0.5 mm enlargement and reconstruction.

3. After obtaining sections in the axial projection, a multiplanar reconstruction (MPR) is performed in the coronary projection.

4. For the second (other side) of the temporal bone, a similar study is carried out, starting from 2 points.

19 patients with suspected otosclerosis were examined on a Toshiba 320-spiral Aquilion ONE computed tomography scanner, the proposed method.

EXAMPLE 1. Patient P., 37 l. Directing diagnosis of otosclerosis. The patient underwent dynamic multispiral computed tomography of the right temporal bone. The study was performed on a Toshiba 320-spiral Aquilion ONE computed tomograph with volume dynamic scanning with a slice thickness of 0.5 mm. The patient's head was located in a standard head stand, fixed to prevent a change in position. A one-time earmold is inserted into the external auditory canal, connected to an air telephone (in the modification of in-channel sound conduction), which in turn is connected to the audiometry connector of the impedance audiometer (Impedance Audiometer АТ235h, Interacoustics, Denmark). There is no sound yet. To mark the area of study performed tomogram. Tomography was performed from the lower edge of the mastoid process and finished at the level of the upper edge of the mastoid process, the field of study was about 4 cm, the voltage was 80 kV, the current strength was 300 mA, the type of reconstruction was bone. After performing tomograms, the first series of sections in axial projection was performed. Scanning progression from the temporal bone to the cranial vault. At the same time, for 4-5 seconds, they were exposed to a sounding sound signal of 55 dB (40 dB + 15 dB) and with a test frequency of 1000 Hz using an impedance audiometer on the structures of the middle ear with an interval of 1 second (i.e., for the first second, sound is heard, for the second second is not applied, etc.). Then, a reconstruction of the right temporal bone was performed with an increase and reconstruction of a 0.5 mm section. After obtaining sections in the axial projection, a multiplanar reconstruction (MPR) was performed in the coronary projection. On tomograms received pneumatic drum cavity. The chain of auditory ossicles is traced throughout. The base of the stirrup is compacted, there is a limitation in the mobility of the base of the stirrup. In the bone capsule of the labyrinth, the focus of spongiosis is determined anterior to the vestibule window with a size of 1.8 × 0.9 mm. The remaining structures of the inner ear without visible pathological changes. The internal auditory meatus is not dilated. Based on dynamic MSCT data, otosclerosis was diagnosed. Subsequently, the patient underwent stapedoplasty on the right, which confirmed the accuracy of the dynamic MSCT data.

EXAMPLE 2. Patient S., 35 l. Directing diagnosis of otosclerosis. The patient underwent a similar dynamic multispiral computed tomography of the right temporal bone according to the described technique. It was revealed that the temporal bone of the pneumatic structure is on the right. The cells of the mastoid process are aerial. The drum cavity is pneumatized. The chain of auditory ossicles is traced throughout. The base of the stapes is compacted, thickened to 0.9 mm, with a functional test it practically does not shift. In the bone capsule of the labyrinth, the focus of spongiosis is determined anterior to the vestibular window 2 × 2 × 3.5 mm in size. The remaining structures of the inner ear without visible pathological changes. The internal auditory meatus is not dilated. Based on dynamic MSCT data, otosclerosis was diagnosed. Subsequently, the patient underwent stapedoplasty on the right, which confirmed the accuracy of the dynamic MSCT data.

The developed method has the following advantages.

1. Allows you to determine the range of motion of the base of the stapes, to evaluate the work of the ligamentous apparatus of the stapes.

2. Allows you to determine the range of motion of the base plate of the stapes in the niche of the oval window, which allows early otosclerosis to be detected.

Thus, the developed method of dynamic (functional) multispiral computed tomographic diagnosis of otosclerosis improves the accuracy of diagnosis of this disease, which in turn affects the timely and optimal choice of tactics and volume of surgical intervention.

Claims (1)

A method of dynamic multispiral computed tomography diagnosis of otosclerosis, which consists in conducting multispiral computed tomography with volumetric dynamic scanning with a slice thickness of 0.5 mm and an interval of 0.25 mm in axial projection, while simultaneously exposing a sound signal exceeding the perception threshold by 15 -20 dB and with a test frequency of 1000 Hz, on the structures of the middle ear with an interval of 1 s for 4-5 s, construct multi-planar and three-dimensional reconstructions and when determining the reduction in the volume of motion eny treadable stirrup plate in the oval window niche as compared with a norm or absence of motion of the stapes plate treadable diagnosed otosclerosis.