RU227645U1 - Implantable obturator for ultrasound stimulation of osteogenesis - Google Patents

Abstract

The utility model relates to medicine, in particular traumatology and orthopedics. It can be used to stimulate osteogenesis in clinical practice and when performing experiments on the bone system to stimulate osteogenesis. The effect of the implantable obturator for contact ultrasound exposure is realized due to the fact that it is a structure containing a metal rod including two cylindrical sections of different diameters, the first cylindrical section of a larger diameter has holes for fastening to the skin surface, the second cylindrical section has a thread, while a ring made of polymer material is placed on the second cylindrical section, the length of the second cylindrical section exceeds the height of the ring made of polymer material, the second cylindrical section is made with the possibility of changing the length.

Description

The utility model relates to traumatology and surgery and is intended to stimulate osteogenesis in bone cavities by contact ultrasound exposure.

There are various methods for activating osteogenesis, including physical (electromagnetic exposure, laser therapy, ultrasound exposure) and non-physical (allo- and autografts, medications) methods of influence. Stimulation of osteogenesis is most relevant in patients with predisposing factors to impaired bone reparation, especially in the treatment of open fractures accompanied by extensive damage to soft tissues. In the treatment of open fractures, the main problems are the development of infectious complications (inflammation of soft tissues, osteomyelitis) and impaired consolidation (delayed consolidation, formation of pseudoarthroses).

When using biocomposite materials, it is necessary to introduce them into the fracture area, which is undesirable in the case of open fractures due to the risk of infectious complications. The use of invasive electrophoresis involves inserting a spoke through the bone marrow canal and the fracture area, which is also unacceptable in the case of open fractures (risk of infection spreading through the bone marrow canal). Laser osteoperforations involve intervention on the bones in the fracture area, which is also extremely undesirable.

A method is known (RU Patent No. 2430714) for optimizing the conditions of reparative osteogenesis, according to the decision, in the postoperative period, when treating patients with fractures of tubular bones, vibroacoustic action is used with the Vitafon device from 14 to 21 days after surgery, in a mode of 1 for 15 minutes, 6 times a day.

The disadvantage of this solution is the thermal effect on the skin.

The closest in technical essence to the proposed solution is a screw (RU Patent No. 183993) for inserting an ultrasonic waveguide, which is a hollow rod including a connected cylindrical threadless section, a threaded section and a cap with an opening, characterized in that the first cylindrical threadless section, the cylindrical threaded section, the second cylindrical threadless section and the cap are connected in series, while the cap has additional openings for fixation on the skin, its opening is designed with the possibility of inserting a waveguide, and the threaded section has an M8 thread.

The disadvantage of this solution is that during the ultrasound exposure the device heats up and causes thermal injury to the skin. There is also a communication of the bone marrow canal with the environment through the screw cannula, which creates a risk of bone infection.

The technical objective of the claimed solution is to simplify the device, as well as to eliminate: infection and thermal burns of the skin and internal layers of muscle tissue.

The technical result of the claimed solution is the elimination of infection and thermal burns of the skin and internal layers of muscle tissue.

The specified technical result is achieved due to the fact that an implantable obturator for ultrasonic stimulation of osteogenesis was proposed, containing a metal rod including two cylindrical sections of different diameters, on the first cylindrical section of a larger diameter, holes are made for fastening to the skin surface, on the second cylindrical section, a thread is made, while on the second cylindrical section, a ring made of polymer material is placed, the length of the second cylindrical section exceeds the height of the ring made of polymer material, the second cylindrical section is made with the possibility of changing the length.

Fig. 1 shows a general view of the implantable obturator for ultrasonic stimulation of osteogenesis.

The implantable obturator for ultrasonic stimulation of osteogenesis is made in the form of a metal rod, including two cylindrical sections of different diameters, on the first cylindrical section 1 of a larger diameter, holes 2 are made for fastening to the skin surface, on the second cylindrical section 3 a thread is made, while on the second cylindrical section a ring 4 made of a polymer material is placed

Fig. 2 shows an X-ray of a bone defect of the femoral condyle 5 with an obturator 6 installed in it.

The proposed device is used as follows.

The proposed implantable obturator is introduced into the formed bone cavity in order to stimulate osteogenesis. In this case, the second cylindrical section 3 is fixed using a thread in the cortical layer of the bone in which there is a bone defect. The first cylindrical section is located on the skin surface, to which it is fixed using sutures passing through openings 2. A ring 4 made of a polymer material, located under the first cylindrical section 1, isolates it from the skin surface and muscle tissue layers, thereby preventing thermal damage to the skin during ultrasonic exposure. The ultrasonic exposure itself is carried out by acoustic contact of the working end of the ultrasonic waveguide-instrument (for example, when using the Yarus traumatological ultrasound device) with the first cylindrical section of the implantable obturator.

Clinical example 1.

The experimental animal (white rabbit) developed a bone defect in the femoral condyle 5 (Fig. 2). An implantable obturator 6 (Fig. 2) was installed in the defect, and ultrasound exposure was performed daily. Filling the defect with bone tissue for 6 weeks (bone density 580 Hounsfield units).

Clinical example 2.

The experimental animal (white rabbit) developed a bone defect of the femoral condyle. No ultrasound exposure was performed. Filling the defect with bone tissue for 7 weeks (bone density 490 Hounsfield units).

Thus, as a result of using the proposed utility model, the following is achieved: simplification of the device, as well as elimination of: infection and thermal burns of the skin and internal layers of muscle tissue.

This creates more optimal conditions for the activation of reparative osteogenesis and, as a consequence, a reduction in the period of fracture consolidation.

Claims (3)

1. An implantable obturator for ultrasonic stimulation of osteogenesis, comprising a metal rod including two cylindrical sections, on the first cylindrical section of a larger diameter there are holes for fastening to the skin surface, on the second cylindrical section there is a thread, wherein on the second cylindrical section there is a ring made of a polymer material, which is designed with the possibility of isolating the first cylindrical section from the skin surface and layers of muscle tissue, wherein the first cylindrical section is designed with the possibility of acoustic contact with the working end of the ultrasonic waveguide-instrument. 2. An implantable obturator for ultrasonic stimulation of osteogenesis according to paragraph 1, characterized in that the length of the second cylindrical section exceeds the height of the ring made of polymer material. 3. An implantable obturator for ultrasonic stimulation of osteogenesis according to claim 1, characterized in that the second cylindrical section is designed with the possibility of changing length.