SU827077A1 - Osteostimulator - Google Patents

Description

I

The invention relates to electromedical technology, and more specifically to electrical devices for promoting healing of fractures, injuries and defects of bone tissue and can be used in healthcare and veterinary medicine.

An osteostimulator is known, which contains a DC source, a current transducer and working electrodes 1.

A disadvantage of the known device is the use of working-material aggressive to living tissues, the possibility of infection penetration and the development of inflammatory processes in soft tissues with the subsequent development of the near-electrode osteomyelitis, the relative complexity of the current stabilizer.

The purpose of the invention is to accelerate the consolidation of bone fractures.

This goal is achieved by the fact that the osteostimulator is provided with a mechanical clamp, which is an osteostimulator case covered with a bioinert polymeric material, while the working electrodes are made of a conductive bioinert material and mounted on the case, and the current transducer consists of a field-effect transistor and a resistor included H circuit in series with current source and electrodes. Polyethylene is used as a bioinert polymeric material. Carbon fiber is used as a conductive bioinert material.

FIG. 1 depicts an osteostimulatory, common. FIG. 2 - circuit diagram in principle.

A housing 1 contains a small source electric power source 2, a transducer 3, and working electrodes — cathode 4 and anode 5, made of a bioinert conductive component, such as carbon plastic. To ensure

compression of bone fragments during the operation and subsequent mechanical fixation on the surface of the bone in the housing 1 are provided with round 6 and shaped 7 holes. 6 holes are designed for

fixing the osteostimulatory torus to the bone fragments. Outside, in addition to the surfaces of the roller 4 and the anode 5, the housing 1 is covered with a layer 8 of bioinert polymer, for example polyethylene. 7 holes are designed for

ensuring squeezing and subsequent fixation of bone fragments. One of the working electrodes 4 or 5 is connected to the source 2 of electrical energy directly, and the other through a converter 3. Field-effect transistor 9 and a resistor

10 is turned on in such a way that any change in the stimulation current between the electrodes 4 and 5 causes a change in the voltage drop across the resistor 10 and the field effect transistor 9, counteracting the change in the stimulation current.

By selecting a resistor 10, a selected value of the stimulation current is set, the parameters of the field-effect transistor 9 determine the allowable lower limit of the voltage variation of the source of electrical energy 2.

An osteostimulator is fitted as follows.

At first, the osteostimulor with screws (not shown in the drawing) is fixed to the proximal bone fragment in such a way that the cathode electrode 4 is directly adjacent to the bone fracture site. A squeezing device is inserted into the extreme shaped hole 7 located at the distal end of the osteostimulator. The rods are inserted into both of the other shaped holes and partially screwed into the distal bone fragment so that the bone fragments converge and squeeze at the fracture site.

When the supply voltage varies, the current fluctuations of the converter for a given value of 18 µA do not exceed 5%, which indicates a sufficiently high efficiency of the converter to stabilize the current of the osteostimulator.

The use of the proposed osteostimulant provides the following benefits:

1) the combination of functions of the stimulator and mechanical fixation of bone fragments;

2) reducing the cost of bioinert working electrodes;

3) low mass, size, and high efficiency of the converter to stabilize the current.

Claims (3)

1. Osteostimulant containing DC source, current transducer and working electrodes, characterized in that, in order to accelerate the consolidation of bone fractures, it is equipped with a mechanical retainer, which is an osteostimulator body coated with a bioinert polymeric material, while working electrodes . are made of a conductive bioinert material and mounted on the housing, and the current converter consists of a field effect transistor and a resistor, connected in series with the current source and the electrodes. 2. Osteostimulator under item 1, characterized in that polyethylene is used as a bioinert polymeric material. 3. Osteostimulator under item 1, characterized in that carbon fiber is used as a conductive bioinert material. Sources, information taken into account in the examination 1. US Patent No. 3842841, cl. A 61 N 1/20, 1973. / t j /ABOUT :P