RU2845302C1 - Digital method for dental implantation with single-step bone tissue augmentation using individual alloimplants - Google Patents

Abstract

FIELD: medical science.

SUBSTANCE: invention relates to medicine, specifically to surgical dentistry and maxillofacial surgery, and is intended for use in reconstructive surgeries. Surgical intervention is preceded by computed tomography and intraoral scanning of a patient. Computed tomography data are converted to STL format. Bone implant is simulated with individual parameters with subsequent milling of the pre-lyophilised bone biomaterial with guides with diameter of 0.25 mm less than the diameter of the implant for its fixation to the alveolar process and avoiding the onset of deformations. Intraoral scanning data are used to create a navigation template taking into account the bone graft parameters. Under local anaesthesia, mucosa is incised, and a mucoperiosteal flap is dissected and thrown back. Navigation template is established. Milled bone implant with individual parameters of the pre-lyophilised bone biomaterial is placed in the surgical area. Osteotomy of the bone bed is performed along the pre-milled guide of the navigation template taking into account individual anatomic-topographic features by means of burrs, drills, taps. Individually milled bone graft is fixed by the anatomical retention and the dental implant. Cover screws are placed on the endosseous implants.

EFFECT: by the uniform distribution of the occlusion loads on the bone tissue, the method enables providing primary stability, creating favourable conditions for bone tissue integration and extending the indications for dental implantation.

1 cl, 2 ex

Description

The invention relates to medicine, in particular to surgical dentistry and maxillofacial surgery, and is intended for use in reconstructive operations.

A method of dental implantation used for low bone density is known, which consists of the following stages. An incision is made in the mucous membrane and periosteum. The alveolar process of the jaw is exposed, the bone bed is formed with a guide drill or a spherical bur. During drilling, the thickness of the cortical bone layer and its density are specified. The drills create a bone bed diameter at the level of the cortical plate corresponding to the diameter of the inserted implant, and at the level of the spongy substance - making up half or a third of the implant diameter, depending on the bone density. The newly formed bone canal is filled with autoplasma in the form of a gel enriched with platelets, after which the implant is installed using the instrumental screwing method. Before suturing, a membrane of autoplasma enriched with platelets is placed on the alveolar process [1].

The disadvantage of this method is the presence of excess load at the initial stages of functioning of the intraosseous part under the influence of occlusal forces, insufficient primary stability of the intraosseous part, creation of intraosseous stress during installation due to the difference in diameters of the bone bed, narrow indications for use, the impossibility of individually restoring the volume of bone tissue in the area of the dental implant.

A method of dental implantation is known, applied in case of significant horizontal resorption of alveolar processes, consisting of resection of the ridge to the level of sufficient thickness of the alveolar processes. It is performed by cutting the mucosa and periosteum, detaching the mucoperiosteal flap and exposing the crest of the alveolar process, grinding the ridge to the level when the thickness of the bone will allow implantation, using a Lindenman cutter or fissure bur, and further preparation of the bone bed for the implant [2].

The disadvantage of this method is the presence of excess load at the initial stages of functioning of the intraosseous part under the influence of occlusal forces, insufficient primary stability of the intraosseous part, narrow indications for use, and the impossibility of individually restoring the volume of bone tissue in the area of the dental implant.

A method of dental implantation is known, which consists of the following stages. A horizontal incision is made in the mucous membrane from the vestibular side slightly below the transitional fold and two vertical incisions are made through the crest of the alveolar process. The mucoperiosteal flap is peeled back and thrown back until the bone tissue is exposed. A pre-prepared surgical template is fixed, which determines the direction of drilling at the planned site. Bone beds are created using burs, drills, and taps, the depth of which does not reach the bottom of the maxillary sinus or the vascular-nerve bundle of the lower jaw by 2 mm. Implants are inserted into the bone beds without completely immersing the intraosseous part of the implant into the bone tissue. Decortication of the alveolar process surface and perforation of the bone plate are performed. Platelet-rich autoplasma in the form of a gel, superficially demineralized bone alloimplant in the form of a plate or bone block, in which holes are created using a surgical template, and a membrane for targeted bone regeneration from preserved dura mater, or amnion, or tendon, or demineralized bone tissue saturated with antimicrobial drugs that suppress the growth of aerobic and anaerobic microflora are successively placed on this area. The method allows to reduce the risk of inflammatory complications, to create the possibility of implantation in case of significant jaw atrophy [3].

The disadvantage of this method is the presence of excess load at the initial stages of functioning of the intraosseous part under the influence of occlusal forces, insufficient primary stability of the intraosseous part, and the impossibility of individually restoring the volume of bone tissue in the area of the dental implant.

A method of dental implantation is known, which consists of the following stages. Before the surgical intervention, a CT scan of the patient is performed. The CT data is converted to STL format. A bone implant with individual parameters is modeled with subsequent milling of pre-lyophilized bone biomaterial. Under local anesthesia, an incision is made in the mucous membrane, the mucoperiosteal flap is peeled off and thrown back. A milled bone implant with individual parameters from pre-lyophilized bone biomaterial is placed in the surgical intervention area. Osteotomy of the bone bed is performed along a pre-milled guide of the bone implant, taking into account individual anatomical and topographic features using burs, drills, and taps. Fixation of the individually milled bone implant is carried out due to anatomical retention and a dental implant. Screw plugs and gum formers are installed on intraosseous implants [4].

The disadvantage of this method is the mobility of the bone implant during the formation of the bone bed, due to which the accuracy of the implant positioning is lost. The lack of digital planning implies the creation of holes for implants in the bone block directly in the oral cavity, which increases the risks associated with transplant deformation.

We have taken this method as a prototype.

The aim of the invention is to reduce the invasiveness and time of surgical intervention, reduce the risk of complications, and increase the accuracy of the installation of dental implants and bone blocks by planning the operation in a single digital protocol.

The method is carried out as follows.

Before the surgical intervention, the patient undergoes computed tomography and intraoral scanning. The computed tomography data is converted to STL format. A bone implant with individual parameters is modeled, followed by milling of pre-lyophilized bone biomaterial with guides 0.25 mm smaller in diameter than the implant diameter to fix it to the alveolar process and avoid deformations. The intraoral scanning data is used to create a navigation template taking into account the parameters of the bone graft. Under local anesthesia, the mucous membrane is incised, the mucoperiosteal flap is peeled back and folded back. A navigation template is installed. A milled bone implant with individual parameters made of pre-lyophilized bone biomaterial is placed in the surgical intervention area. Osteotomy of the bone bed is performed along a pre-milled guide of the navigation template, taking into account individual anatomical and topographic features using burs, drills, and taps. Fixation of the individually milled bone implant is performed due to anatomical retention and a dental implant. Screws-plugs are installed on the intraosseous implants. The method allows for uniform distribution of occlusal loads on bone tissue, ensuring primary stability, creating favorable conditions for bone tissue integration, and expanding the indications for dental implantation. The positive effect of using the proposed method is expressed in uniform distribution of the occlusal load on bone tissue, ensuring primary stability, creating favorable conditions for bone tissue integration, and expanding the indications for dental implantation.

The proposed method is confirmed by the following clinical examples.

Clinical example #1

Patient M. (48 years old) complained of aesthetic and functional discomfort caused by the absence of teeth 36, 37. There were no concomitant diseases, and no contraindications to implant treatment were identified.

When collecting the anamnesis, it turned out that there was an unsuccessful experience with the installation of dental implants, and complications arose during the process of osseointegration.

The CBCT analysis revealed a lack of bone volume for the installation of dental implants. And the exit site of the inferior alveolar nerve significantly complicates the positioning of implants and the implementation of bone grafts. The lack of bone support led to the formation of a pronounced soft tissue defect of the alveolar process.

In order to create a virtual model of the patient, the files obtained during oral cavity scanning ( STL format) and the files obtained during CBCT ( DICOM format) were combined. Using the Diagnokat program, a three-dimensional model of the lower jaw ( STL format) was obtained and a bone graft was modeled. Using the RealGuide program, three-dimensional positioning of the implants and bone block was performed. At the next stage, a surgical template was modeled and technological holes were made in the bone graft for dental implants in the PlastyCad program. Then, an individual bone graft was made in the laboratory using CAD/CAM technology. In parallel with this, the design of the surgical guide template was printed using a 3D printer.

Under local anesthesia, an incision was made in the soft tissues of the lower jaw in the area of teeth 3.5, 3.6 and vestibular and lingual mucoperiosteal flaps were formed. The incision was made with a special design with a shift to the vestibular side, to obtain a suture line in the projection of the apex of the alveolar ridge after fixation of the bone graft.

Using a guide template fixed to the lower jaw teeth, the bed for the implants was prepared. Preliminary installation of dental implants was performed to eliminate angular divergence. The implants were then removed.

The bone graft was positioned on the alveolar process, the cortical plate of the alveolar process was perforated for additional vascularization and secured using two dental implants with subsequent fixation of screw plugs.

Bone graft was placed into the spaces above the screw covers created by the installation of dental implants. Suturing.

The patient was prescribed drug therapy. During the healing process, preventive examinations, X-rays and professional hygiene were carried out.

As a result of the manipulations performed, the bone graft was fixed to the alveolar process using dental implants, without additional fixation methods, which allows us to talk about a decrease in trauma and a reduction in the time of surgical intervention. Digital planning made it possible to reduce the risks of complications associated with inaccuracy in the placement of the bone block and the angles of convergence of the implants relative to the technological holes in the graft.

Clinical example #2

Patient C. (50 years old) complained of aesthetic and functional discomfort caused by the absence of teeth 45, 46. There were no concomitant diseases, and no contraindications to implant treatment were identified.

When collecting anamnesis, it was revealed that there had previously been a fracture of the lower jaw in the area of the chewing teeth on the right. As a result, teeth 45 and 46 were removed.

The CBCT analysis revealed a lack of bone volume for the installation of dental implants. And the exit site of the inferior alveolar nerve significantly complicates the positioning of implants and the implementation of bone grafts. The lack of bone support led to the formation of a pronounced soft tissue defect of the alveolar process.

In order to create a virtual model of the patient, the files obtained during oral cavity scanning ( STL format) and the files obtained during CBCT ( DICOM format) were combined. Using the Diagnokat program, a three-dimensional model of the lower jaw ( STL format) was obtained and a bone graft was modeled. Using the RealGuide program, three-dimensional positioning of the implants and bone block was performed. At the next stage, a surgical template was modeled and technological holes were made in the bone graft for dental implants in the PlastyCad program. Then, an individual bone graft was made in the laboratory using CAD/CAM technology. In parallel with this, the design of the surgical guide template was printed using a 3D printer.

Under local anesthesia, an incision was made in the soft tissues of the lower jaw in the area of teeth 45 and 46, and vestibular and lingual mucoperiosteal flaps were formed. The incision was made with a shift to the vestibular side, to obtain a suture line in the projection of the apex of the alveolar ridge after fixation of the bone graft.

Using a guide template fixed to the lower jaw teeth, the bed for the implants was prepared. Preliminary installation of dental implants was performed to eliminate angular divergence. The implants were then removed.

The bone graft was positioned on the alveolar process, the cortical plate of the alveolar process was perforated for additional vascularization and secured using two dental implants with subsequent fixation of screw plugs.

Bone graft was placed into the spaces above the screw covers created by the installation of dental implants. Suturing.

The patient was prescribed drug therapy. During the healing process, preventive examinations, X-rays and professional hygiene were carried out.

In this clinical case, in difficult clinical conditions associated with a fracture of the lower jaw, it was possible to achieve the desired result. After the manipulations, the bone graft was fixed to the alveolar process using dental implants, without additional fixation methods, which allows us to talk about reducing trauma and reducing the time of surgical intervention. Digital planning made it possible to reduce the risks of complications associated with inaccuracy in the placement of the bone block and the angles of convergence of the implants relative to the technological holes in the graft.

Sources of information:

1. RF Patent No. 2435547, application No. 2009146682/14, Vyacheslav Dmitrievich Arkhipov (RU), Alexey Vyacheslavovich Arkhipov (RU), dated 12/15/2009.

2. Paraskevich V.L. Dental implantology: Fundamentals of theory and practice. - 2nd ed. - M.: OOO "Medical information agency", 2006. - p. 259.

3. RF Patent No. 2416376, application No. 2009113836/14, Volova Larisa Teodorovna (RU), Arkhipov Vyacheslav Dmitrievich (RU), Arkhipov Alexey Vyacheslavovich (RU), Volov Nikolay Vyacheslavovich (RU), dated 04/13/2009.

4. RF Patent No. 2624164, application No. 2015155780, Kolsanov Alexander Vladimirovich (RU), Volova Larisa Teodorovna (RU), Popov Nikolay Vladimirovich (RU), dated 12/24/2015.

Claims (1)

A digital method of dental implantation with one-stage bone tissue augmentation using individual alloimplants, characterized by the fact that before the surgical intervention, computed tomography and intraoral scanning of the patient are performed, the computed tomography data are converted to STL format, after which a bone implant with individual parameters is modeled with subsequent milling of pre-lyophilized bone biomaterial with guides with a diameter of 0.25 mm less than the diameter of the implant for its fixation to the alveolar process and to avoid the occurrence of deformations, the intraoral scanning data are used to create a navigation template taking into account the parameters of the bone graft, under local anesthesia, an incision of the mucous membrane is made, peeling off and folding back the mucoperiosteal flap, then a navigation template is installed, a milled bone implant with individual parameters from pre-lyophilized bone biomaterial is placed in the area of the surgical intervention, osteotomy of the bone bed is performed according to a pre-milled guide of the navigation template, taking into account individual anatomical and topographic features using burs, drills, taps, fixation of the individually milled bone implant is carried out due to anatomical retention and a dental implant, then screw plugs are installed on the intraosseous implants.