RU2160127C1 - Method for treating diseases and applying local impulse electric stimulation - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: method involves stimulating segmental reflexogenic zones and biologically active zones related to pathologic focus or organ in combination with direct action upon the pathologic focus projection. Electrodes are set in innervation zones and current impulses are sent to nerves available in the innervation zones. Impulse shape is maximum approximated to nerve fiber action potential shape in Ranvier interception zone by creating bipolar asymmetric impulse shape with short high amplitude cathode outburst followed by long-term low-amplitude anode phase. The total component of the so formed impulse is provided with the mentioned shape equal to zero. Impulse duration is varied depending on current frequency from 0 to 1.3 ms. EFFECT: wide range of functional applications. 14 dwg

Description

 The invention relates to medicine, namely to medical methods of treating a disease and rehabilitating local impulse electrical stimulation, which consists in a multi-channel electrical effect of low-frequency impulse currents on human organs and tissues.

 The method can be applied in the treatment of diseases of the musculoskeletal system, including diseases of the spine, joints, muscles, the consequences of fractures and injuries. The method can also be used to treat diseases.

- broncho-pulmonary system (bronchial asthma, chronic bronchitis and pneumonia);
- nervous system (radiculitis, neuritis, neurocirculatory dystonia, etc.);
- gastrointestinal tract (peptic ulcer, cholecystitis, pancreatitis, bowel disease);
- The genitourinary system is inflammatory and functional, including nocturnal enuresis and male impotence;
- cardiovascular system (hypertension, vascular disease of the upper and lower extremities);
- to normalize muscle tone, local blood circulation and metabolic processes, eliminate muscle dystrophy, prevent the formation of pressure sores, reduce the duration of rehabilitation treatment;
- to improve performance and reduce fatigue during monotonous work (operators, conveyor workers, etc.);
- to eliminate pain of various etiologies (after injuries, radiculitis, neurology, etc.);
- for training the muscular system of athletes and recovery from sports injuries;
- in cosmetology;
- body shaping with weight reduction;
- elimination of wrinkles on the face and neck;
- restoration of the shape of the mammary glands in women of childbearing age.

 To date, it has been proven that the widely used local pulsed electrical stimulation enhances the functionality of the neuromuscular system both in the process of recovery after high training loads, and for the treatment of injuries and diseases of the musculoskeletal system.

 Electrical stimulation of the neuromuscular apparatus is a method of non-pharmacological treatment and prevention, expanding one's own compensatory capabilities of the human body, significantly increasing its protective functions. High efficiency and the absence of negative side effects allow us to recommend the method for use in aerospace, clinical, sports medicine, in various industrial activities. In addition, electrical stimulation is well established in cosmetology and for body shaping with weight loss.

 Currently, pulsed electrotherapy is universally recognized as one of the leading methods of physical treatment, successfully competing with drug and other types of therapy. Several of the most used methods of low-frequency pulsed electrical stimulation with a wide range of therapeutic effects have been developed. Among them: electrosleep, diadynamic therapy, amplipulse therapy, interference therapy, fluctuation, percutaneous electroneurostimulation.

 In these methods, by changing the shape and duration of the pulse, using medium-frequency filling of low-frequency pulses, varying the frequency response of the current, as well as using combined modes, including sending currents of different frequencies, sending currents and pause, special methods of applying electrodes, it is possible to normalize the function of the central nervous system and higher autonomic centers, changes in the state of general and local hemodynamics (lowering blood pressure, reducing the frequency of cardiac contractions, vasodilation, increased collateral blood flow and microcirculation), elimination of pain, swelling, smooth muscle spasms of blood vessels and internal organs, anti-inflammatory and trophic-stimulating effects, stimulation of skeletal muscles.

 Opportunities for improving the therapeutic methods of low-frequency pulsed electrotherapy are associated with the search for the most physiological and effective form of pulses, as well as the introduction of elements of automatic programmatic regulation of frequency and amplitude parameters of exposure.

 The study of the effects of local pulsed electrical stimulation showed that it is accompanied by significant local changes in blood circulation, metabolism, as well as significant reflex reactions at the system level (changes in respiration, blood circulation, thermoregulation, dynamics of central fatigue, etc.).

 A known method of treating diseases and rehabilitation of local pulsed electrical stimulation and a device for its implementation. The method consists in superimposing surface multilayer electrodes connected to a four-channel motion corrector. Electrical stimulation of the muscles is carried out by a sequence of pulses at a voltage of up to 60 V, a duration of 50-200 μs, with a frequency of 20-50 Hz. The duration of a series of pulses varies from 0.2 to 0.5 s, depending on the type of muscle being stimulated. The strength of the extensor muscles increases by 40-70%, the maximum electrical activity by 35-47% (see ed. Certificate of the USSR N 1669438 of 08/15/91).

 The known method has inherent disadvantages in that it provides for electrical stimulation of only individual motor nerves and muscles. Proposed in the known method, the order of installation of the electrodes and modes of electrical stimulation do not provide stimulation of the activity of internal organs and individual life support systems.

 The closest analogue of the proposed method for the treatment of diseases and rehabilitation with local pulsed electrical stimulation is a method consisting in applying several electrodes to a pathological focus and creating a multi-channel electrical effect of low-frequency pulse currents on human organs and tissues of a given shape and frequency for a given time (See US Patent 5702429 dated 12/30/97).

 The disadvantages of the closest analogue include the lack of effectiveness of the therapeutic effect due to the shape of the active pulse, which in phase structure differs significantly from the current caused by the action of membranes of the neuromuscular cells of a healthy person, which is best perceived by excitable structures and causes the most adequate response of the body. In the known method does not provide a mechanism for the impact of electrical stimulation on the internal organs and segmental systems. Electrode installation schemes have not been developed so that various organs (somatic and visceral) receive polysegmental spinal innervation (afferent and efferent), and internal organs also have bulbar. These disadvantages make the known method less functional and low efficient.

 The objective of this method of treatment and rehabilitation of local pulsed electrical stimulation is to expand the functionality of local pulsed electrical stimulation by developing a mechanism of therapeutic effects of electrical stimulation at physiological, reflex and neurocirculatory levels, in creating a therapeutic effect to normalize the functions of the affected organs or organ system.

 The problem is solved by a method of treating diseases and rehabilitation with local pulsed electrical stimulation, which consists in applying several electrodes to a pathological focus and creating a multi-channel electrical effect of low-frequency pulse currents on human organs and tissues of a given shape and frequency for a given time and characterized in that together with direct exposure the pathological focus is affected by the corresponding segmental and reflexogenic zones and biologically active zones associated with a pathological focus or organ by additional installation of electrodes in the zones of innervation and the supply of current pulses to the nerves associated with the central nervous system located in these zones of innervation, while the shape of the pulses is maximally approximated to the shape of the action potential of the nerve fiber in the interception zone Ranvier, approaching in phase structure to the current of action of the membrane of the neuromuscular cells of a healthy person by the formation of a bipolar asymmetric pulse shape with a short high-amplitude cathodic ejection followed by a prolonged low-amplitude anode phase, and provide a total component of the formed pulse of the above shape, equal to zero. The pulse duration varies depending on the frequency of the current from 0 to 1.3 ms.

 The essence of the proposed method is as follows.

 In FIG. 1 shows the innervation zone of the sympathetic part of the autonomic nervous system, and in FIG. 2 - parasympathetic department of the autonomic nervous system, determining zones and points of innervation for installing electrodes, in FIG. Figure 3 shows a diagram of the sympathetic part of the autonomic nervous system, (preglinar (solid line) and postganglionic (dashed line) fibers directed: to the left to the internal organs, to the right to the somatic - peripheral blood and lymph vessels, lymph nodes, smooth muscles and glands of the skin, Fig. 4 is a diagram of the parasympathetic part of the autonomic nervous system (prenglionic (solid line) and postganglionic (dashed line) fibers), Fig. 5 shows the outgoing (afferent) paths of the spinal cord and brain ha (diagram) afferent innervation: on the left - of internal organs, on the right - somatic, in Fig. 6 shows a graphical characteristic of a bipolar asymmetric impulse, in Fig. 7 - a diagram of the installation of electrodes for diseases of the bronchopulmonary system with an asthmoid component and pulmonary emphysema. , the reflex and neurocirculatory mechanism of the therapeutic effect of electrical stimulation, the effect of which is aimed at strictly local areas. The therapeutic effect of electrical stimulation is expressed in the normalization of the function of the affected organ or organ systems.

 Previously, electrical stimulation of motor nerves and muscles was used best. In the method it is proposed to carry out in addition to this also stimulation of the activity of internal organs and individual systems. The nerves of each segment of the spinal cord are directed to the internal organs and segmental systems (Fig. 1, 2).

 All organs (somatic and viscentral) receive polysegmental spinal innervation (afferent and efferent), and the internal organs also receive bulbar innervation (Fig. 3, 4).

 The main feature of the method is the formation of bipolar pulsed currents, approaching in phase structure to the current of action of the membrane of the neuromuscular cells of a healthy person, which are best perceived by excitable structures and cause the most adequate response of the body.

 To increase the effectiveness of the impact, pulsed currents to several procedural fields are used simultaneously (with the multichannel version), which significantly increases the impact on different body structures (pathological focus, segmental and reflex effects, on other systems) during one session.

 The electric current of the bipolar asymmetric pulse changes the concentration of tissue ions in the cell membrane and, changing its permeability, acts like natural biocurrents (Fig. 6).

 In this regard, it is the most universal irritant for all excitable structures.

 Electrical stimulation of the above pulse shape not only prevents the development of muscle atrophy (as with other types of electrical stimulation), but also activates hormonal regulation (stimulation of the corticoid function of the adrenal cortex) and activates the processes of tissue respiration; enhances venous circulation and lymph flow; normalizes the function of the affected organ or organ system with segmental exposure (see Fig. 3, 4).

 The segmental specificity of the exposure zones comes to their organ focus, exposure to them gives a specific, practically established therapeutic effect for each of them.

 The impact methodology is designed in such a way that, in addition to the direct impact on the focus of the disease, an impact is made on the corresponding segmental and reflexogenic zones. The output impulse should be as close as possible in physical effect to the impulse of the central nervous system of a healthy person, which allows (with the specified exposure pattern) to regulate the work of organs and systems of the human body, forcing it to work in the "health" mode.

 To implement the proposed method, any known multichannel devices for electrical stimulation can be used, which have the ability to reproduce the shape of the output pulse of the maximum close to the potential action of the nerve fiber in the zone of Ranvier interception. These apparatuses include apparatuses having computer software, for example, commercially available apparatuses of the Miorhythm type. Consider the application of the proposed method on the example of the location of the electrodes in diseases of the bronchopulmonary system with asthma component and pulmonary emphysema.

 The technique involves the impact on the patient simultaneously with six channels of the device for electrical stimulation.

 Channel 1 and 2 are located symmetrically along the posterolateral surface of the chest along the course of 6-8 intercostal spaces to strengthen the respiratory muscles.

 Channel 3 - on the anterior abdominal wall - strengthening the muscles of the anterior abdominal wall, contributing to the maximum participation in the breathing of the diaphragm.

 Channel 4 - paravertebral at the level of 1-4 thoracic vertebrae on both sides - reflexogenic zone, exposure to it leads to the appearance of a pronounced pleuro-pulmonary reflex with increased blood and lymph circulation in the lung tissue and to bronchospasmalitis effect.

 Channel 5 - parallel and lower than the clavicle on both sides, the reflexogenic zone, which is responsible for the regulation of respiratory function.

 6 - channel - paravertebral at the level of 8-10 thoracic vertebrae on both sides, the effect on the adrenal segment in order to increase glucocorticoid function.

 Subsequently, asymmetric bipolar pulses are fed to the installed electrodes, which are characterized by a short high-amplitude cathodic ejection followed by a long continuous low-amplitude anode phase.

 The total component of the pulse of this form is equal to zero, which determines the gentle current effect and good tolerance of the procedures by the patient. The pulse duration varies depending on the frequency of the current from 0 to 1.3 ms. The frequency of the current varies from 20 to 500 Hz, depending on the type of stimulating muscle. The amplitude of the pulses is continuously adjustable from 0.1 to 1.3 ms. The range of adjustment of the output current is from 1 to 120 mA. The device is powered by AC 220 V, 50 Hz. The duration of electrical stimulation sessions increases from 15 minutes to 60 minutes. The course of electrical stimulation consists of 10-20 daily sessions. Parameters stabilization occurs after the first course and does not change 3-6 months after it.

 A wide range of regulation of exposure parameters, the uniqueness of the output pulse, well-established methods allow the use of the method for various diseases. The choice of the location of the electrodes, the number of channels used, the parameters of electrical stimulation (shape, frequency, amplitude), the duration of the procedure and the course of treatment depend on the purpose of the exposure, the general condition of the body, the nature and stage of the disease, the presence of concomitant diseases, and individual characteristics of the patient.

The differences of the proposed method are as follows:
1. The most optimal form of the output pulse (as close as possible to natural bio-pulses), which allows you to regulate the work of organs and systems of the human body.

 2. The bipolarity of the output pulse with equal areas of different polarities gives a comfortable perception of the impact, ie the procedure is pleasant.

 3. The presence of channels of continuous vibration allows for a short period of exposure to eliminate pain.

 4. The multi-channel effect solves the problem of simultaneous effects on different structures of organism (pathological focus, reflex, segmental, biologically active zones).

 5. Symphase, amplitude and frequency modulation of the exposure signal minimizes the effects of adaptation of the stimulated tissue.

 6. The proposed method allows for the provision of pulsed electrical stimulation not only of motor nerves and muscles, but also of internal organs.

 7. Determines the arrangement of the electrodes and the creation of channels of exposure for diseases of various tissues and organs.

The main contraindications for the application of the proposed method:
1. Diseases or damage to the skin at the sites of application of the electrodes.

 2. The presence of an artificial pacemaker.

 3. Oncological and oncological diseases.

 4. Acute infectious diseases.

 5. Thrombosis and thrombophlebitis.

 6. Heart failure 2B-3 Art.

 7. The state of psychomotor agitation and convulsive readiness.

 8. Stimulation of the zones of bile and urinary calculi.

 9. Individual intolerance to electric current.

 10. Disorders of cerebral circulation.

 According to the proposed method, no more than twelve galvanic channels of influence are used, which is enough for a full effect from all characteristic zones and points on the human body.

The modes of operation of the channels are as follows:
- stimulation mode in frequency and amplitude;
- stimulation mode with modulation (drift) of frequency;
- mode with constantly adjustable purity (anesthesia).

Frequency modulation in the first two modes can be carried out in three ranges: 20-120 Hz
120-250 Hz
250-500 Hz.

 In channels with a constantly adjustable frequency, a frequency change can carry out 5-324 Hz.

 Simultaneous operation of channels with frequency drift and constantly adjustable frequency is possible. Stimulation channels can operate in group and ring modes.

 Specific exposure regimens are determined by the physician depending on the type of disease. When determining the areas of position of the electrodes, they are guided by the necessary number of channels of electrical stimulation effect on the affected focus or organ. In this case, the schemes of zones of innervation of the spinal segments shown in FIG. 1-5. As an example of exposure to various spinal segmental zones of FIG. 12 - fatigue treatment.

 The use of the method of treating diseases and rehabilitation with local pulsed electrical stimulation showed that its positive effect is determined by a number of reasons, but two of them, apparently, are of significant importance.

 Firstly, the physiological and therapeutic effect of currents is based on short-term, rhythmically repeating superthreshold shifts in the concentration of basic inorganic ions near semipermeable membranes of nerve and muscle cells of various organs and tissues in the affected area. As a result, depolarization of those excitable structures occurs, the lability of which allows the frequency of the acting pulse current to be absorbed, which is manifested by a reduction in muscle fibers, both skeletal and smooth, by rhythmic pulsation along afferent nerve fibers, directed to the neurons of the posterior horns of the spinal cord, providing closure of segmental reflexes and the formation of an ascending impulse to the visual tubercles of the diencephalon and the cerebral cortex. For those excitable structures that are unable to assimilate the stimulation rhythm due to their low lability, which is most typical for autonomic nerve fibers, smooth muscle cells under the action of frequencies close to 100 Hz, a peculiar physiological pessimum of excitation arises when, being bombarded by a high-frequency pulse current, they cease to respond with depolarization to each impulse of the stimulating current, and soon cease to respond to endogenous stimulation received by the efferent somatic and autonomic nerve fibers. As a result, the tone of smooth muscle cells of the vascular wall and internal organs decreases, smooth muscle spasms are eliminated, the activity of the sympathetic ganglia and autonomic nerve fibers decreases, which is also accompanied by an antispasmodic effect, an improvement in tissue trophism, and a decrease in their oxygen demand. Thus, depending on the frequency of the pulsed current and the characteristics of the target organs and tissues on which it acts, the main biotropic phenomenon underlying the action of this physical factor can lead to polar opposite results.

 In particular, the biopolar form of pulses with a short cathode spike determines a strong but short and sparing stimulating effect on excitable structures that can elicit the response of the overwhelming majority of even slow-reacting nerve and muscle cells, in particular smooth muscle cells, autonomic nerve fibers, and damaged striated muscle cells ( denervation, peripheral neuritis, etc.). Therefore, the presence of impulses with such characteristics in the package provides a pronounced irritant effect, stimulates all tissue structures. Intense muscle fibrillation occurs, as a result - reflex arterial hyperemia, increased microcirculation, stimulation of venous and lymph outflows, elimination of tissue edema, increased local tissue temperature. Powerful afferent impulse aggravates the irritating effect of exposure, causing bright subjective sensations. The ability of low-frequency and long-duration pulses to excite the vast majority of not only motor, but also sensitive tissue elements makes them an inadequate irritant for acute symptoms, severe pain syndromes, the presence of a vegetative component in the structure of the pain syndrome, and vascular disorders.

 As the duration of the pulses in the package decreases and their frequency increases, the intensity of irritation decreases, since shorter pulses are not able to elicit a response from slowly reacting nerve and muscle cells and, therefore, the repertoire of current-responsive structures is limited to myelinated somatic nerves and intact striated muscle cells . The relatively high frequency of stimulating pulses leads to the development of the above-described phenomenon of the physiological pessimum of excitation, which also covers slowly reacting structures. Therefore, pulses of minimum duration and maximum frequency have a weak irritating effect, the contraction of only healthy skeletal muscles and, on the contrary, the relaxation of smooth muscle cells, the removal of spasms of blood vessels and internal organs, moderate afferent impulse along the nerve nerves with a decrease in the conductivity and spontaneous activity of autonomic nerve fibers and ganglia. Excitation of a limited number of motor and sensory tissue elements determines the moderate nature of subjective sensations.

 Secondly: The high, compared with other methods, analgesic activity of the currents is due to the pronounced neurotropy of its impulses, which are very close in form to the potentials of the nerve fiber and differ favorably in this regard from impulses of a sinusoidal and half-sinusoidal form.

 Apparently, several different mechanisms are involved in the development of the analgesic effect. When a pulsed current is brought to the painful focus, a powerful, regular afferent pulsation arises along the same fibers that conduct pathological pulses. As a result, there is a blockade of pain impulses, which, due to their randomness and weak rhythmic structure, give way to therapeutic impulses. Therefore, the pain syndrome stops almost immediately after the start of the procedure.

 Prolonged continuous conduct of external impulse introduces the nerve fiber into a state of so-called parabiosis, characterized by a temporary loss of ability to perform specific activity, in particular to conduct impulses of pain sensitivity and the predominance of trophotropic tissue functions. Under the influence of electrical stimulation in the nerve fiber, the production of endogenous opiate-like substances - endorphins, which have a much greater analgesic effect than pharmacological drugs of narcotic analgesics due to the higher means for opiate tissue receptors, is enhanced. Reaching the subcortical nuclei of the so-called limbic system, impulses stimulate the production of endogenous opiates in them - enkephalins, identical to the analgesic properties of endorphins. Thus, a long-term consequence of pain relief is achieved: analgesia persists for more than two hours after the procedure. After the specified time, the pain resumes, but with less intensity and for their relief, a second procedure can be performed. A consistent course of pulsed electrotherapy procedures leads to the elimination of pain.

 The analgesic effect is non-specific and does not depend on the genesis of pain. The pains of traumatic, inflammatory, ischemic and spastic origin of pain associated with irritation of peripheral nerves and roots of the spinal cord are most effectively stopped. The effectiveness of therapy depends on the correct selection of the parameters of the current, depending on the nature, severity and severity of the pain syndrome. In case of severe pain due to acute trauma accompanied by tissue softening, when vegetative nerve fibers are irritated with vegetalgia, sympathoganglionitis, and solaritis, and in acute vegetovascular disorders accompanying pain, it is advisable to use a fixed current frequency at the upper limit of the prescribed range.

 In FIG. 7-8 are examples of the application of electrodes in lumbosacral osteochondrosis, in arthroso-arthritis of the knee joint.

 In FIG. 9-10 are examples of the application of electrodes when restoring the shape of the mammary glands in women of childbearing age and treating the urogenital system of an inflammatory and functional nature, including nocturnal enuresis (Fig. 10) and male impotence (Fig. 11), in the treatment of sensorineural hearing loss / Fig. 13/.

 The parameters of electrical stimulation and the duration of one procedure are selected depending on the condition and individual characteristics of the patient. A typical duration of the procedure is up to 30 minutes.

 When conducting local pulsed electrical stimulation, the patient is placed mainly in the pose of the best muscle relaxation. Head and legs in horizontal position, arms along the body. Treatment is carried out at the earliest possible period of the disease in the absence of signs of inflammation. After the first procedure, the patient is monitored for one, two days, after which a second procedure is performed.

 The following procedures are carried out every day for 20-30 days. After the procedure, the patient must be warmly covered and left for 10-15 minutes. It is forbidden to install electrodes directly on the spine. At the beginning of the procedure, slight hyperemia of the skin appears in the area of application of the electrodes, in the future the patient notes the appearance and intensification of a sensation of heat, the weakening and disappearance of pain. Then more general sensations appear: heaviness and warmth in the back and limbs, general relaxation, rest, drowsiness. The feeling of warmth, muscle relaxation, and pain relief persists after the end of the procedure for several hours (from 2 to 5 hours after the first procedure). After 2-3 procedures, usually the pain relief in the interprocedural period is preserved, then the degree of weakening increases, the mobility of the spine and joints increases, the stiffness of the muscles of the back and limbs decreases, and the impaired sensitivity of the organs improves. The course of treatment of the proposed local pulsed electrical stimulation improves blood circulation, metabolic processes and the morphofunctional state of the underlying tissues and organs.

Claims (1)

 A method for the treatment of diseases and rehabilitation with local pulsed electrical stimulation, which consists in applying cutaneous electrodes and creating a multi-channel electrical effect of low-frequency pulse currents on human organs and tissues of a given shape and frequency for a given time, the pulse duration from 0 to 1.3 ms, characterized in that together with the approach to the pathological focus of the pulse current, they act on the corresponding segmental, reflexogenic zones and biologically active zones associated this pathological focus, while the shape of the pulses is maximally approximated to the shape of the action potential of the nerve fiber in the Ranvier interception zone, and according to the phase structure to the current of action of the membranes of the neuromuscular cells of a healthy person by forming a bipolar pulse shape with a short high-amplitude cathodic ejection followed by a prolonged low-amplitude anode phase and provide the total component formed by the pulse of the above shape equal to 0.

Images