RU2644824C2 - Method for obtaining x-ray image of cochlear implant - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: method involves placing the temporal region of the patient's head with an implant inserted between the X-ray source and the X-ray image receiver. As an X-ray source, an X-ray tube with a massive target taken at the end of a long anode tube from a vacuum tank of the X-ray tube or an anode tube with an end target is used. In this case, the anode tube with a massive target is injected into the oral cavity of the patient on the implant side at an angle of about 45° to the sagittal plane of the head. The anode tube with an end target is inserted into the oral cavity of the patient on the opposite side of the head relative to the implant at an angle of about 45° to the sagittal plane. The X-ray image receiver is located close to the temporal region of the head in which the implant is placed.

EFFECT: method provides a good detailed visualization of the structures of the inner ear with the lowest radiation load on the patient and personnel.

3 cl, 1 tbl

Description

The invention relates to medicine, in particular to otorhinolaryngology, and can be used for diagnostic purposes to determine the position of the electrode array of a cochlear implant in the spiral channel of the cochlea.

Currently, various methods of radiation diagnostics of patients after cochlear implantation are known and widely used in otorhinolaryngology, one of them is x-ray in the Stanvers projection and transorbital projection.

In a study by Copeland et al., The disadvantages of using intraoperative traditional radiographs in cochlear implantation were identified. Intraoperative radiography has been recommended for patients with cochleovestibular pathology (Copeland BJ, Pillsbury NS, Buchman CA. Prospective evaluation of intraoperative cochlear implant radiographs. Otology & Neurotology 2004 Vol / 25 Issue 3 - pp. 295-297).

There are also visualization methods available at the pre-, intra- or postoperative stages of cochlear implantation, with various indications. Multispiral computed tomography (MSCT) and magnetic resonance imaging (MRI) are mainly used in preoperative preparation to assess the state of the structures of the temporal bone. A new method, digital volumetric tomography or cone beam computed tomography (CBCT), is increasingly used intra- or postoperatively due to the high information content of the obtained data and lower dose load compared to MSCT (Aschendorff A. Imaging in cochlear implant patients / GMS Curr. Top Otorhinolaryngol. Head Neck Surg. 2011. V. 10. Doc07; IV Ivanova. Radiodiagnosis during cochlear implantation: current state of the problem and development prospects (literature review) Radiology Practice, 2014. - N 6. - C. 50-58; Zubareva A.A., Chibisova M.A., Dudarev A.L., Shavgulidze M.A. of digital volumetric tomography in otorhinolaryngology // Radiation diagnostics and therapy. 2011. No. 4 (2). S. 105-118).

In general, all known visualization methods for cochlear implantation have certain disadvantages.

1. High radiation load.

2. Technical difficulties in carrying out the above methods intraoperatively.

3. The presence of artifacts from the metal parts of the implant when using MSCT.

4. The high cost of these methods.

The disadvantages described above make it necessary to search for new methods for visualizing the electrode array in the cochlear spiral channel during the surgical stage of cochlear implantation.

Closest to the proposed method is the use of X-ray diagnostic apparatus such as C-arc intraoperatively. The use of such devices makes it possible to obtain an image in real time and evaluate the correct position of the electrode array of a cochlear implant.

A relatively new way to obtain intraoperative images is the use of such devices with flat panel detectors. This technology is used in hybrid operating rooms using a fixed C-arc. To obtain an image, a fixed C-arc rotates around the patient, which makes it possible to obtain layered images with subsequent reconstruction of a three-dimensional image (Aschendorff A. Quality control after cochlear implant surgery by means of rotational tomography. Otol Neurotol. 2005 Jan; 26 (1): 34 -7).

The disadvantages of this method are the presence of high doses of ionizing radiation, difficulties in use in the operating room, associated with the dimensions of the equipment.

To eliminate the above disadvantages, a method for obtaining an x-ray image of a cochlear implant is proposed, which includes placing the temporal region of the patient’s head with an implant installed between the x-ray source and the x-ray image receiver, characterized in that an x-ray tube with a massive target at the end of a long anode tube from a vacuum cylinder of an X-ray tube, or an anode tube with open space end anode target, while the anode tube with a massive target is inserted into the patient’s oral cavity from the implant side at an angle of about 45 ° to the sagittal plane of the head, the anode tube with a straight end target is inserted into the patient’s mouth from the opposite side of the head with respect to the implant at an angle about 45 ° to the sagittal plane, and the X-ray image receiver is located close to the temporal region of the head in which the implant is installed.

The technical results of the proposed method are visualization of the electrode array of a cochlear implant, while the microfocus radiography used provides a good detailed visualization of the structures of the inner ear, the patient and staff receive the lowest radiation exposure.

The method is as follows.

X-ray images were obtained using the PARDUS-R X-ray apparatus (ELTEH-Med, Russia).

It is intended for carrying out X-ray examinations in non-stationary conditions, it is used in dentistry, maxillofacial surgery, traumatology. A distinctive feature of the device is the BS-11 (Re) microfocus x-ray tube used in it with a hollow remote anode and a shooting type target. A micron-sized focal spot allows for more detailed aiming shots. It is also envisaged to install a BS-11M (W) tube with a massive target and radiation output opposite to the direction of electron motion in the accelerating gap.

The body of the device is made of plastic. The cap worn on the protruding anode is leaded from the inside and isolates the propagation of x-rays in the lateral directions. The radiation protection of the device allows you to reduce the radiation dose received by the doctor at arm's length to almost the background value. Low power and low radiation level make it possible to use these devices not only in specialized rooms in the clinic, but also in rooms adjacent to residential premises.

We used both microfocus x-ray tubes in the following operating modes. The focal spot size is about 0.1 mm. Physical and technical conditions: voltage 60 ÷ 70 kV, exposure - 0.5 mAs, distance the source of x-ray radiation - an object 60 ÷ 100 mm. The data were obtained during a series of experiments on the cadaver temporal bones, human skull, and pig’s head, into the cochlea of which a cochlear implant electrode array was inserted.

When conducting cochlear microfocus radiography on an implanted pig’s head, new projections (stackings) were proposed that allow the best visualization of the electrode array.

1. An x-ray tube is used with a massive target, taken out at the end of a long anode tube from a vacuum cylinder of the x-ray tube, while the anode tube is inserted into the patient's oral cavity from the implant side at an angle of about 45 ° to the sagittal plane of the head, and the x-ray image receiver is located close to the temporal region of the head in which the implant is installed.

In this case, the anode tube is made of easily atomic material, for example aluminum. The massive target is inclined to the axis of the pipe at an angle of 30-60 °.

2. An X-ray tube with a shot end target can also be used, while the anode tube is inserted into the patient's mouth from the side of the head opposite to the implant at an angle of about 45 ° to the sagittal plane. In this case, the X-ray image receiver is also located close to the temporal region of the head in which the implant is installed.

The X-ray images of the temporal bone obtained during the experiment were compared with the reference versions obtained on a stationary apparatus; the data of preliminary CT examination were regarded as reference images in the study of the skull. The quality of visualization of the electrode array of the cochlear implant and the anatomical landmarks of the temporal bone labyrinth were evaluated. The assessment was carried out by radiologists, otorhinolaryngologists.

Image quality was analyzed according to several criteria:

1) the position of the electrode array relative to the modiolus;

2) visualization of individual electrodes;

3) the presence of artifacts;

4) overall impression of image quality.

Image quality was evaluated on a five-point scale from 0 (very poor quality) to 4 (very good quality) (Table 1).

The proposed method visualized the structures of the temporal bone and individual electrodes of the cochlear implant on 2 cadaver preparations and the skull. The obtained microfocus images of the electrode array, taking into account the criteria used (Table 1), were evaluated by the researchers as good and very good (3-4 points). It was found that microfocus radiography while providing high quality x-ray images additionally provides a good detailed visualization of the structures of the inner ear. It is important that the exposure of one image is 1-2 orders of magnitude less than when using all known diagnostic methods. This causes the lowest radiation load on the patient and staff when using the proposed method.

Claims (3)

1. A method of obtaining an x-ray image of a cochlear implant, comprising placing the temporal region of the patient’s head with an implant installed between the x-ray source and the x-ray image receiver, characterized in that an x-ray tube with a massive target placed at the end of the long anode is used as an x-ray source tubes from a vacuum cylinder of an x-ray tube, or an anode tube with a straight end target, while the anode tube with an array the target is inserted into the patient’s oral cavity from the implant at an angle of about 45 ° to the sagittal plane of the head, the anode tube with a shooting end target is inserted into the patient’s mouth from the opposite side of the head to the implant at an angle of about 45 ° to the sagittal plane, and the receiver X-ray image is located close to the temporal region of the head in which the implant is installed. 2. The method according to p. 1, characterized in that the anode tube is made of easily atomic material, for example, aluminum. 3. The method according to p. 1, characterized in that the massive target is inclined to the axis of the pipe at an angle of 30-60 °.