RU2546438C1 - Manufacturing method of implant for plastic repair of bone tissue defects - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: during modelling of an implant there used is a sterilised food foil, out of which a volumetric element is formed, which is introduced to a plastic repair zone of defects of bone tissue; after that, by deforming the above volumetric element by forces perpendicular to its longitudinal axis, treatment of end face zones of the implant is achieved according to the shape of bone surfaces facing to them; with that, when necessary, the volumetric element is filled with new portions of foil till thickness of the same volumetric element is achieved, which corresponds to actual thickness of bone in the bone defect section; after than, the formed implant model is removed and used for further manufacture of the implant from donor bone tissue.

EFFECT: method allows reducing labour intensity and reducing modelling time.

8 dwg

Description

The invention relates to medicine, namely to surgery, to methods for plastic surgery of defects in bone tissue resulting from trauma or after removal of neoplasms.

Known methods for homoplasty of bone cavities with bone fragments and spongy shavings of tubular bones: Abstract. dis. ... cand. honey. sciences. - M., 1957. - 16 p .; G.L. Rusanov. Replacing defects of tubular bones with crushed bone tissue: Abstract. dis. ... cand. honey. sciences. - L., 1963. - 40 p.).

The disadvantages of these methods is the possibility of necrotic and rejection of free, malnourished bone fragments, the risk of allergic reactions and infection of the recipient (HIV, hepatitis B and C).

As the closest analogue, a method has been adopted for manufacturing an implant for plastic surgery of bone defects, including determining the size and volume of the plastic zone with subsequent modeling of the implant (see RF patent No. 2335258, IPC A61F 2/00, publication date 10.10.2008).

The disadvantage of the closest analogue is the limited scope and increased complexity of the implant modeling process.

The problem to which the invention is directed, is to develop a simple method for manufacturing an implant for plastic defects of complex, mainly extended shape with low material consumption.

The technical result achieved by solving the problem is expressed in expanding the scope, as well as in reducing the complexity and time of the method due to the use of bulk elements from food foil for the manufacture of the implant model.

The problem is solved in that in the method of manufacturing an implant for plastic bone defects, including determining the size and volume of the plastic zone with subsequent modeling of the implant, in the process of modeling the implant use a sterilized food foil, from which form a volume element that is introduced into the plastic zone of bone defects tissue, after which, by deforming this volumetric element by forces perpendicular to its longitudinal axis, they work out the end zones of the implant in accordance with the form my bone surfaces facing them, and, if necessary, supplement the volume element with new portions of foil until the thickness of this volume element corresponds to the real thickness of the bone in the area of the bone defect, after which the implant model formed in this way is removed and used for further manufacturing of the implant from donor bone tissue.

A comparative analysis of the essential features of the proposed technical solution with the essential features of analogues indicates its compliance with the criterion of "novelty."

In this case, the distinguishing features of the claims solve the following functional tasks.

The sign “sterilized food foil is used in the process of implant modeling” provides the possibility of using available material with low cost for modeling, which is easy to sterilize.

The sign “form a volumetric element, which is introduced into the plastic zone of defects in bone tissue, after which, by deforming this volumetric element with efforts perpendicular to its longitudinal axis, they work out the end zones of the implant in accordance with the shape of the bone surfaces facing them, and, if necessary, supplement the volumetric element with new portions of foil until the thickness of this volumetric element is reached, which corresponds to the real thickness of the bone in the area of the bone defect ”, provides the possibility of modeling and simple rrektsii shape and size of the implant in accordance with the characteristics of the bone defect, and the resulting model has sufficient strength and rigidity.

The sign “remove the implant model thus formed and use it for further manufacturing of the implant from donor bone tissue” makes it possible to manufacture the implant in accordance with the model.

Figure 1 shows the x-ray of patient A in example 1 to the implementation of the proposed method.

Figure 2 shows a model of an implant made of food foil.

Figure 3 shows a diagram of the implementation of the proposed method of the patient And according to example 1.

Figure 4 shows the implant of donor bone tissue, fixed using a plate in patient A in example 1.

Figure 5 shows the x-ray of patient B according to example 2 before the implementation of the proposed method, the defect zone is indicated by an arrow.

Figure 6 shows a diagram of the implementation of the proposed method of the patient B according to example 2.

Figure 7 shows the implant of donor bone tissue, fixed using a plate in patient B according to example 2.

On Fig shows a radiograph of patient B according to example 2 after the implementation of the proposed method.

The inventive method is as follows.

Pre-provide surgical access to the plastic zone of defects in bone tissue (nonunion, pseudarthrosis, improper adhesion) in a known manner and determine the characteristics (size and volume) of the plastic zone.

Next, a volume element is formed from pre-sterilized food foil, which is introduced into the plastic defect zone of bone tissue, after which, by deforming this volume element by forces perpendicular to its longitudinal axis, they work out the end zones of the implant in accordance with the shape of the bone surfaces facing them.

If necessary, supplement the volumetric element with new portions of the foil to achieve a thickness of this volumetric element corresponding to the actual thickness of the bone in the area of the bone defect, or reduce the volume by removing excess food foil or increasing the deformation of the volumetric element.

Next, the formed implant model is removed, if necessary, temporarily increasing the distance between its external surface and the bone surfaces facing it.

Then, according to the characteristics of the model, marking is made with a marker on donor bone tissue. The implant is taken with the help of an osteotome and a hammer or with the help of a pendulum saw, its characteristics are compared with the model and, if necessary, corrected using miniature bone nippers.

At the end, the finished implant is transferred to the plastic zone of defects in bone tissue and fixed using one of the generally accepted methods.

Example No. 1. Patient A, 38 years old, was admitted with a gunshot fracture of the 2 metacarpal bone with a soft tissue defect in the extensor tendons of the 2 fingers, a bone defect (Fig. 1). Upon admission, primary surgical treatment of the wound and external fixation with an impromptu apparatus were performed. A month after the injury, secondary surgical treatment of the wound, skin plastic with a radiation graft on a vascular pedicle with retrograde blood flow was performed.

2 months later, a surgical operation was performed, during which the defect plastic zone was temporarily filled with an implant model in the form of an elongated trapezoid made of food foil with dimensions of 4.5 cm × 2.0 cm × 0.5 cm (Fig. 2). In accordance with the model, a cortical spongy implant was taken from the upper third of the tibia and separately spongy implants in the form of small “chips”. A cortical-spongy implant is installed in the plastic area of the defect of the second metacarpal bone and fixed with screws through the plate (Figs. 3, 4). On the sides of the main implant are placed "chips" of spongy bone.

The wound is sutured in layers. Immobilization of the hand and forearm with a gypsum splint. Within 4 weeks, the tire is constant, within 2 weeks removable. The duration of immobilization is 2.5 months. Then exercise therapy, massage, physiotherapy.

Example No. 2. Patient B., 22 years old, was hospitalized for pseudarthrosis of the scaphoid. He turned in 2 years after the injury. On the x-ray revealed a false joint of the scaphoid at the level of the middle part, a significant bone defect, shortening, severe deformation of the type of "humpback" (hump) (figure 5).

The palm incision provided surgical access to a bone defect, the contents of the cyst, scar tissue were removed, and the sclerotic ends of the fragments were resected.

A surgical operation was performed, during which the defect plastic zone was temporarily filled with the implant model in the form of a trapezoid made of food foil measuring 1.5 cm × 1.4 cm × 1.0 cm (Fig. 2). In accordance with the model, a cortical spongy implant was taken from the iliac crest and separately spongy implants in the form of small “chips”. A cortical-spongy implant is installed in the plastic zone of the scaphoid defect and fixed with a mini-plate ("De Puy") with angular stability on 4 screws with a diameter of 1.5 mm (Fig.6, 7). On the sides of the main implant are placed "chips" of spongy bone.

The wound is sutured in layers. To close the skin wound, a rapidly absorbable suture material Vicryle Rapide was used, which can be left under a plaster cast (Zolotov A.S., Zolotova Yu.A., 2010). Immobilization of the wrist joint and first finger with a plaster splint. After 5 days, the swelling decreased, the gypsum splint transferred to a circular dressing. Sutures were not removed. The duration of immobilization is 2.5 months. Then exercise therapy, massage, physiotherapy. Inspection after 8 months. On control x-rays, bone fusion (Fig. 8).

Claims (1)

A method of manufacturing an implant for plastic surgery of bone defects, including determining the size and volume of the plastic zone with subsequent modeling of the implant, characterized in that during the simulation of the implant using sterilized food foil, from which form a volumetric element that is inserted into the plastic bone defects zone, after which, deforming this volumetric element by efforts perpendicular to its longitudinal axis, they achieve the development of the end zones of the implant in accordance with the shape facing m of bone surfaces, and, if necessary, supplement the volumetric element with new portions of foil to achieve a thickness of this volumetric element corresponding to the actual thickness of the bone at the site of the bone defect, after which the implant model thus formed is removed and used for further production of the implant from donor bone tissue.

Images