RU2141852C1 - Method of compensation of bone tissue decalcification - Google Patents

Abstract

FIELD: medicine, namely physiotherapy. SUBSTANCE: electrophoresis of 2-per cent xydiphone is performed from negative electrode. Maximum density of acting current is equal to threshold feeling of patient. Carrier frequency equals muscle tremor frequency. Carrier frequency is amplitude-modulated to depth of 30 per cent. Use is made of signals coming from pulse and respiration pickups. Current density is increased up to maximum value during inhalation and systole and decreased during exaltation and diastole. EFFECT: enhanced efficiency of treatment.

Description

 The invention relates to medicine, in particular to physiotherapy, and is intended to compensate for decalcification of bone and muscle tissue during prolonged space flights.

 A known treatment method implemented in the "Device for physiotherapy" / 1 /, in which the area of the pathological focus is affected by a signal with a voltage corresponding to the threshold sensation by the patient, synchronous with the respiratory rate and pulse of the patient. This method has not been studied to compensate for the loss of calcium in bone and muscle tissue.

There is a method of treating pain syndromes in the face, consisting in exposure to algic zones by electrophoresis of a 2% solution of xidiphon with a negative active pulse by a rectangular pulse current, with a pulse duration of 1 ms, a pulse repetition rate of 50 Hz and a current density of 0.005 - 0.1 mA / cm ² for 10-20 min / 2 /, which is taken as a prototype.

 The indicated regimen for the administration of xidifon indicates optimal solution concentrations, but is not physically adequate.

 The technical problem to be solved is improving the effectiveness of the treatment of diseases associated with impaired calcium metabolism.

 The problem can be solved in the following way. The theoretical justification of the proposed method is the fulfillment of Fick's law: maintaining the maximum concentration gradient of xidifon between the bone or muscle tissue where the xidiphone is supposed to be pumped, and its concentration on a dampened napkin under the negative electrode. Coordination with the influx and outflow of blood of the introduction of new portions of xidiphone provides this condition. Experimental verification showed that xidifon can be pumped most rapidly and at greater depths into the rhythms of blood flow using signals of a threshold applied to the patient's sensation of current, modulated by signals from the patient's pulse and respiratory sensors.

The proposed method for compensating for decalcinization of bone and muscle tissue involves electrophoresis of 2% xidifon from a negative active electrode. In this case, the maximum density of the acting electric current is chosen corresponding to the threshold sensation of the patient (tingling, tingling) for the type of electrodes used. These sensations are observed at a current density of 0.05 - 0.1 mA / cm ² , but in some patients with reduced or increased sensitivity they may go beyond this range specified in the prototype. The duration of the pulses used is chosen at least 1 ms (as in the prototype), or with a minimum duty cycle for a frequency of 10 Hz, it can be up to 100 ms. For the efficiency of electrophoresis, this parameter is not significant. The duration of the procedure, as in the prototype, is 10-20 minutes The carrier frequency of the acting signal is chosen equal to the frequency of muscle tremor (10 ± 3) Hz and modulated to a depth of 30% in amplitude by signals from pulse and respiration sensors. In this case, the current is increased to maximum threshold values during the phases of inspiration and systole and is reduced in amplitude by 30% during exhalation and diastole.

 An experimental check was carried out on rabbits, which were injected with a xidifon from a negative electrode at a current density 2 times less than muscle twitching and modulation amplitudes by 30% using signals from a pulse sensor installed on the rabbit’s ear and a respiratory sensor (thermodiode in front of the nose). A histochemical analysis of the penetration depth of xidiphon when stained with calcium with an Eriochron black T confirmed that the biofeedback regimen is effective in terms of speed, depth of administration and the amount of added xidiphon and bound calcium compared to the pulsed regime used in / 2 / of the same duration (20 min).

 An indirect confirmation of the effectiveness of the biofeedback regimen was the comparison of the electrophoresis of xidiphone with constant potential and biofeedback mode in the treatment of periodontal disease. When using xidiphone in biofeedback mode, inflammation, bleeding gums and gum pockets quickly disappeared / 3 /.

The proposed method for compensating decalcification of bone and muscle tissue can be carried out using the known device / 1 /, which contains pulse and respiration sensors, first and second amplifiers, three potentiometers, an adder, a delay line, a power amplifier, a polarity switch, a switch, a control unit and indication and generator. The known device / 1 / should be supplemented with special electrodes connected from its graphite fabric connected to its outlet, well-fitting the surface of the arms or legs, using about 20-30 cm ² , as well as napkins moistened with 2% xidiphone.

Literature
1. RF patent N 2033204, A 61 1/36, 1995.

 2. USSR author's certificate N 1569024, A 61 1/30, 1990, BI N 21.

 3. Zaguskin SA, Zaguskina LD, Kantor IR, Savchenko LA, Elimination of microcirculatory hypoxia in periodontal tissues using biocontrolled chronophysiotherapy. Methods for the correction of hypoxia in tissues. - Nalchik: 1990, 57-63.

Claims (1)

 A method of compensating for bone decalcification, including electrophoresis of 2% xidifon from a negative active electrode for 10 to 20 minutes, characterized in that the exposure is carried out by electric current with a maximum density corresponding to the threshold sensation of the patient for the type of electrodes used, while the carrier frequency, equal to the frequency of muscle tremor (10 ± 3) Hz, they are modulated to a depth of 30% in amplitude by signals from pulse and respiratory sensors with an increase to maximum density during inspiration and systole and a decrease in expiratory time and diastole.