RU195878U1 - Artificial temporal bone (study guide) - Google Patents

Abstract

The utility model relates to the field of medicine, namely to otorhinolaryngology and 3D-modeling. Simulate the temporal bone on a computer using CT images in a special program. Next, the resulting master model is divided into three parts, and the section planes of this model pass strictly along the three knees of the facial nerve canal. Each of the three parts is separately printed on a 3D powder printer, then the silicone molds are removed from them. Fill artificial plasticite. The resulting parts of the temporal bone are manually connected in series using colorless gel-based glue. In this case, the path of the facial nerve canal in its three knees is preliminarily laid with yellow polymer thread. The proposed model fully and on the same scale repeats the complex anatomy of the temporal bone and makes it possible to master the basic skills for beginning otosurgeons. Under the conditions of import substitution, the cost of a domestic analogue of artificial temporal bone is 5-7 times cheaper than foreign analogues. This tutorial can be used to educate students, graduate students and residents of medical schools throughout the Russian Federation.

Description

The utility model relates to medicine, namely to otorhinolaryngology.

The temporal bone is a pair, one of the most complex bones of the skeleton, located between the occipital and sphenoid bones, is a part of both the formation and the roof of the skull, participates in the formation of the temporomandibular joint and connects to the zygomatic bone [1]. It consists of 4 parts: stony, drum, mastoid and scaly [2]. Recently, in Russia and abroad, hanging demand has acquired courses on dissection of the temporal bone in order to enhance practicing specialists their otosurgical skills. The use of endoscopy, and in some cases surgical treatment using the synergism of otorhinolaryngologists and neurosurgeons, requires an increasingly advanced technique for owning temporal bone dissection [3]. Achievements of scientific and technological progress, the emergence of high-quality linzovaya optics, new materials and prostheses, today allow performing high-tech operations on the temporal bone with a minimum amount of intervention. The development of various types of operations on the temporal bone requires otosurgeons to have a detailed knowledge of the landscape of this structure and an understanding of the spatial relative positioning of the main anatomical structures [4]. In addition to the theoretical basis, the basis of training of otosurgeons is the acquisition of practical skills in temporal bone surgery [5]. For these purposes, the cadaveric material of the human temporal bone is used as an object of intervention. In connection with the advent of new technologies and partly the complexity of the legislation on the removal of autopsy material, it became possible to introduce artificial temporal bone into the training program.

A. Multi-center study of the Jenaer model of the temporal bone. Laryngorhinootologie 2004; 83: 6: 363-366.) [6]. Однако данный продукт в условиях российского рынка имеет высокую стоимость.The prototype of this utility model is an artificial temporal bone manufactured by Facon (Germany) (Schneider G.,

A. Multi-center study of the Jenaer model of the temporal bone. Laryngorhinootologie 2004; 83: 6: 363-366.) [6]. However, this product in the conditions of the Russian market has a high cost.

The technical problem that we are solving is the creation of an artificial temporal bone as a model for training otosurgeons in performing high-tech operations on a given anatomical structure and at the same time having a low cost.

The technical result achieved is the model of the temporal bone that we propose, which fully and on the same scale repeats the complex anatomy of the temporal bone and makes it possible to master the basic skills for beginning otosurgeons. To implement the utility model, a combination of 3D printing technology, investment casting and application of materials similar in their physical and mechanical properties to the natural temporal bone was used.

A brief description of the drawings.

Figure 1. Model of the temporal bone in 3D modeling.

Figure 2. Silicone flask for pouring artificial stone, and a hole in the flask for pouring material.

Figure 3. Ready artificial temporal bone in a three-point fixative, a - dura mater (stained with red latex), b - region of the sigmoid sinus (stained with blue latex).

Figure 4. Antromastoidotomy with exposure of the dura mater.

and - a dura mater.

Figure 5. Antromastoidotomy with exposure of the sigmoid sinus, and sigmoid sinus.

Figure 6. The posterior tympanotomy (mastoid process, top view), and - the posterior region of the posterior tympanotomy.

Figure 7. Decompression of the facial nerve (open antromastoidal

cavity, top view), and - the facial nerve (yellow polymer thread), the descending knee.

To obtain computer images of the temporal bone, patients aged 25 to 50 years were selected with a diagnosis of otosclerosis, who performed this study in preparation for stapedoplasty. From this series of images, the most significant from the point of view of normal anatomy were selected. When choosing computed tomography (CT) images, special attention was paid to the airiness of the mastoid process, the clear course of the facial nerve canal, the condition of the auditory ossicle chain, the normal standing of the dura mater and sigmoid sinus. A generalized 3D model of the temporal bone was obtained (Fig. 1). Together with the specialists of the Tempoorum LLC commercial association (Russia), in the Vibrazh computer program, the temporal bone was divided into three parts, and the interface planes were drawn along the course of the facial nerve canal. The three parts obtained were printed separately on a 3D powder printer using polyamide material. Subsequently, the silicone molds were removed from the obtained three fragments (Fig. 2) for the possibility of casting the material into them and replicating the product. It is worth noting that even the individual three fragments of the temporal bone were morphologically very difficult to cast into the obtained silicone molds. In this regard, additional silicone liners were placed in the resulting molds. The liner on the supports was installed in the obtained form and an artificial stone, plasticite, was poured. According to literature data, the density of normal bone is 1500-2000 units of Hd. The closest in parameters is the material of artificial stone. After pouring into plastic mold, it hardened for 48 hours. Then the parts were removed from the forms, and the forms themselves were used for further replication of the product. The obtained three parts are fully consistent with the natural temporal bone, repeating its anatomical

 structure on a scale of 1: 1 (Fig. 3-7).

At the final stage of the work, the obtained parts of the temporal bone were manually connected in series. At the same time, the course of the channel of the facial nerve in its three knees was preliminarily laid with yellow polymer thread. Fragments of the temporal bone were fixed to each other using colorless glue on a gel basis so that all surfaces of the temporal bone were butt to butt. The upper surface of the model was stained with red latex, simulating the dura mater, and the sigmoid sinus region with blue latex (Fig. 3.).

The proposed training manual is used in the State budgetary institution of public health "Research Clinical Institute of Otorhinolaryngology named after L.I. Sverzhevsky" of the Department of Health of the city of Moscow when conducting master classes on cochlear implantation and is included in the educational programs for otosurgeons for the implementation of state programs guarantees for the rehabilitation of patients with bilateral deafness (Fig. 4-7).

Thus, in Russian medical universities at the departments of otorhinolaryngology, product samples can be introduced. Under the conditions of import substitution, the cost of a domestic analogue is 5-7 times cheaper than foreign analogues. This tutorial can be used to educate students, graduate students and residents, medical schools throughout the Russian Federation.

List of references:

1. Trifunov E.G., Dergunova N.I., Mikheeva A.E. Radiation diagnosis of diseases and injuries of the temporal bone (compendium of a radiation diagnostician). 3rd edition, ELBI-SPb, 2017 .-- 320 p.

2. Faramarzi M., Mohammad Hossein M.N., Amini M., Heydari ST, Samiei A., Motasaddi Zarandy M., Eftekhari A., Ghasemi MM, Baradaranfar M.N., Naderpour M., Mohammad A., Mohammadi S. Assessment of Otolaryngology Residency Training Program in Iran: Perspectives of Faculty Members and Recently Graduated Medical Students. Iran J Otorhinolaryngol. 2019 31 (102): 25-33.

3. Lin B.J., Hong K.T., Chung T.T., Liu W.H., Hueng D.Y., Chen Y.H., Ju D.T., Ma H.I., Liu M.Y., Hung H.C., Tang C.T. Endoscopic transorbital transtentorial approach to middle incisural space: preclinical cadaveric study. Acta Neurochir (Wien). 2019 161 (4): 831-839. doi: 10.1007 / s00701-019-03831-6.

4. Komune N., Matsuo S., Miki K., Matsushima K., Akagi Y., Kurogi R., Iihara K., Matsushima T., Inoue T., Nakagawa T. Microsurgical Anatomy of the Jugular Process as an Anatomical Landmark to Access the Jugular Foramen: A Cadaveric and Radiological Study. Oper Neurosurg (Hager-stown). 2019 16 (4): 486-495. doi: 10.1093 / ons / opy198.

5. Maas A.I., Kosyakov S.I., Kharlamov K.A. The methodology of simulation training of the skills. Vestn Otorinolaringol. 2019 84 (1): 60-63. doi: 10.17116 / otorino20198401160. Russian

A. Multi-center study of the Jenaer model of the temporal bone. Laryngorhinootologie 2004; 83: 6: 363-366.6. Schneider G.,

A. Multi-center study of the Jenaer model of the temporal bone. Laryngorhinootologie 2004; 83: 6: 363-366.

Claims (1)

Artificial temporal bone as a teaching aid, including three parts made of artificial stone, the models for the manufacture of which are printed using a 3D printer, while the three parts are connected and fixed with colorless glue, butt to butt, with the formation of the facial canal in its three knees, laid with a yellow polymer thread imitating the meninges, the area is made of red latex, the area of the sigmoid sinus is made of blue latex, and p lastikrit.

Images