RU2066554C1 - Gastroenteric tract electrostimulator - Google Patents

Abstract

FIELD: medical equipment; can be used in postsurgical therapy both in ambulant and clinical conditions, as well as in prophylaxis of gastrointestinal disturbances. SUBSTANCE: electrostimulator comprises capsule 1 which accommodates series-connected environment condition monitoring unit 5, signal level analyzer 6, microprocessor 7 and pulse shaper 8 connected to power supply 3. Electrodes 4 are made on the external surface of capsule 1, the total number of electrodes is 2+n, where n=2, 3, 4 ... and is determined by the degree of medical effect and technological potentiality of manufacture of electrodes which are connected to the outputs of unit 8 and inputs of environmental condition monitoring unit 5. The stimulator generates stimulating pulses with parameters optimized for each branch of the gastroenteric tract and produces a scanning effect on its muscular tissues; unit 8 produces electrostimulating pairs from electrodes 4 of opposite polarities whose field strength directions are orthogonal. EFFECT: enhanced efficiency. 3 cl, 4 dwg

Description

 The invention relates to medical equipment and can be used, for example, in post-surgical therapy both in outpatient and in clinical settings, as well as in the prevention of gastrointestinal diseases.

 Known electrical stimulator of the gastrointestinal tract, containing drainage tubes on which electrodes are placed (see SU, ed. St. N 1389776, 1988).

 A disadvantage of the known electrical stimulator is the relatively high trauma of patients due to the need to remove the electrodes along with the tubes through the throat.

 The closest to the invention according to the set of essential features is an electrostimulator of the gastrointestinal tract containing a capsule in which a power source is located, two electrodes are made on the outer surface of the capsule (see RU, ed. St. N 936931, 1982).

 At the same time, a generator is also located in the capsule, and the capsule body is made in the form of two electrical insulated parts serving as electrodes and in contact with the intestinal wall.

 However, the known electrical stimulator has a relatively low electrical stimulation efficiency, due to the partial coordination of the electric field of the two electrodes with the morphology of the muscle tissue of the gastrointestinal tract, as well as the lack of adaptation of the stimulation to the condition and conditions of various sections of the gastrointestinal tract. In addition, it is characterized by inefficient energy consumption, which may affect operational reliability. In addition, the lack of adaptation of stimulation to the condition and conditions of various parts of the gastrointestinal tract can lead to side effects on the patient's body.

 The lack of effectiveness of electrical stimulation, due to the lack of adaptation of stimulation to the condition and conditions of various sections of the gastrointestinal tract, is explained by the fact that each section of the gastrointestinal tract that passes the stimulator has its own morphological features (geometric dimensions, direction, etc.), as well as its specific pH value of the internal environment, which determines its functional and physiological purpose, i.e. the conditions of use in each department of the tract should be different.

 However, the known electrical stimulator produces electrical impulses with averaged parameters that are not optimized for each department, which can also cause side effects on the patient's body.

 The relatively low efficiency of electrical stimulation, due to the partial coordination of the electric field of the two electrodes with the morphology of the muscle tissue of the gastrointestinal tract, is explained by the fact that the muscle tissue contains external longitudinal and internal circular layers, simultaneous or alternating electric effects on which require the presence of electric fields, the directions of the intensities of which directed mutually orthogonally, which is absent when using the known electrical stimulator. When it moves, the electric field of the two electrodes stimulates mainly only the longitudinal muscle layer, i.e. the wave of peristalsis in this case does not occur or occurs quite rarely and is unstable, which reduces the effectiveness of electrical stimulation.

 The low reliability of the known electrical stimulator due to inefficient energy consumption is caused by the inability to minimize energy consumption in passive storage mode, since the known electrical stimulator is in a state of dynamic operation continuously, starting from the moment of its assembly and further during storage and after the patient is introduced into the gastrointestinal tract.

 The aim of the invention is the creation of an electric stimulator that provides simultaneous or alternating presence of electric fields, the directions of the intensities of which are mutually orthogonal, without compromising the overall characteristics; ensuring the adaptation of electrical stimulation to the state and conditions of various sections of the gastrointestinal tract, reducing the side effects of electrical stimulation on the patient's body; Minimize power consumption in passive storage mode.

 This is achieved by the fact that in the electric stimulator of the gastrointestinal tract, containing the capsule in which the power source is located, two electrodes are made on the outer surface of the capsule, a serially connected environmental monitoring unit, a signal level analyzer, a microprocessor and a pulse shaper placed in the capsule are introduced , n electrodes, where n 2,3,4, and is determined by the degree of therapeutic effect and the technological feasibility of manufacturing electrodes, and the electrodes are connected to the outputs of the shaper pulse and a control unit with inputs state environment, with all the electrodes disposed on the outer surface of the capsule.

 In addition, the capsule can be made in the form of a tubular element with caps, at the opposite ends of which along the cylindrical surface there is one group of electrodes.

 In addition, the capsule can be made in the form of two connected caps, on each of which along the generatrix surface there is one group of electrodes.

 The increased number of electrodes, their location and the formation of the electrode system in the form of separate groups allows at the same time: to vary the number of electrodes involved in stimulation, to enhance or weaken the impulse effect; to create a scanning effect on the longitudinal and circular layers of the muscle tissue of the gastrointestinal tract by enumerating combinations of pairs of bipolar electrodes; maintain functionality when individual electrodes fail, i.e. increase operational reliability; to create such a switching of the electrodes, in which the electrostimulating pairs are formed simultaneously or alternately from bipolar electrodes, the directions of the field intensities of which are mutually orthogonal.

 The introduction of a series-connected environmental monitoring unit, a signal level analyzer, a microprocessor and a pulse shaper simultaneously allows: a pulse shaper to generate electrical pulses with parameters optimized for each section of the gastrointestinal tract, which increases the efficiency of electrical stimulation and eliminates side effects on the patient; create an autonomous diagnostic monitor for measuring pH, while the pH values are functionally dependent on the values of the impedance of the resistance between the electrodes entering the input of the environmental monitoring unit; vary by combinations of pairs of bipolar electrodes, which, with a small time value of a pause between series of pulses and a relatively low speed of movement of the capsule, allows you to create a scanning effect on the longitudinal and circular layers of muscle tissue of the gastrointestinal tract with relatively low microprocessor speed (the above action provides a stable character of stimulation, for example, in the form of a wave of peristalsis, which significantly increases the effectiveness of electrical stimulation); generate feedback in the power circuit of the proposed device, minimizing power consumption in storage mode.

 Thus, in the implementation of the invention increases the efficiency of electrical stimulation and operational reliability.

 In FIG. 1 shows the proposed design of an electric stimulator with one example of a capsule in the form of a tubular element with caps, at the opposite ends of which one group of electrodes is located on a cylindrical surface; in FIG. 2 functional electrical circuit; in FIG. 3, the proposed design of an electric stimulator with another example of a capsule in the form of two connected caps, on each of which one electrode group is located along a generatrix surface; in FIG. 4 is a circuit diagram of an environmental condition monitoring unit, an example of implementation.

 The proposed electrical stimulator contains a capsule 1, in which are located the electronic unit 2 and the power source 3 (see figure 1). On the outer surface of the capsule 1, electrodes 4 are made, the total number of which is (2 + n), where n is 2,3,4, and is determined by the degree of the therapeutic effect and the technological feasibility of manufacturing the electrodes 4. The electronic unit 2 consists of a series 5 state control unit external environment, the analyzer 6 signal level, the microprocessor 7 and the shaper 8 pulses (see figure 2). The electrodes 4 are connected to the outputs of the pulse shaper 8 and to the inputs of the environmental monitoring unit 5. In addition, the capsule 1 can be made, for example, in the form of a tubular element 9 with covers 10, at the opposite ends of which along the cylindrical surface there is one group of electrodes 4 (see figure 1). In this case, the covers 10 may have, for example, hemispherical. domed or other shape.

 In addition, the capsule 1 can be made, for example, in the form of two connected caps 11, on each of which along the forming surface there is one group of electrodes 4 (see figure 3), while the caps 11 can have, for example, a spherical, conical or other other shape.

 The total number of electrodes 4 is determined by the technological capabilities of their manufacture. So, for example, vacuum deposition allows you to get the maximum number of electrodes located around the circumference, due to the possibility of forming a minimum gap between adjacent electrodes with an electrode thickness of approximately 20 μm.

 In addition, the number of electrodes 4 is determined by the desired degree of therapeutic effect achieved when using the proposed electrical stimulator. So, for example, the increased number of electrodes allows you to vary the number of electrostimulating pairs of bipolar electrodes in order to enhance or weaken the pulse effect.

 Unit 5 monitoring the state of the external environment may, for example, contain K identical comparators 12, where K 2,3,4, and is equal to the number of electrostimulating pairs of bipolar electrodes 4 (see figure 4). In this case, the inverting input of each comparator 12 is connected through a reference resistance 13 to a power source 3 for supplying a reference voltage, and non-inverting to the output of a voltage divider 14, the inputs of which are connected to a pair of bipolar electrodes 4 for measuring the impedance of the electrodes.

 The output of each comparator 12 is connected to the corresponding input of the signal level analyzer 6. Comparators 12 compare voltages and generate MORE or LESS signals.

 The signal level analyzer 6 may, for example, comprise a decoder and a status register (result register). The decoder circuit may consist of logical elements of CMOS transistors and implements a truth table for selecting the minimum level recorded by the environmental monitoring unit 5. Signals MORE or LESS come from the output of the comparators 12 of the unit 5 for monitoring the state of the external environment to the inputs of the logic elements. Passing through the logic elements, the above signals are analyzed in pairs (previous with subsequent) and converted at one of the outputs to a low logic level, and to the rest to a high one. A low logic level is a sign of starting a microprocessor 7 program that implements an operating mode with a minimum value of the registered parameter. These levels are received in the state register, which is used by the microprocessor 7 as a register of applications, each of which corresponds to its own program of work of the microprocessor 7.

 The microprocessor 7 may, for example, comprise a control unit, a memory unit or an EEPROM block in which several groups of stimulating parameters are stored, and a synchronization unit.

 The pulse generator 8 may, for example, contain linear switches for three states, providing a supply of a + or or - signal level to each electrode 4 of the power supply 3, as well as disconnecting them from the power circuit, a pulse distributor in a series consisting of a counter and encoder and providing alternate switching of potential key inputs to the output of the counter and blocking unused keys, a controlled frequency divider having input control buses and providing the formation of a pulse sequence of necessary about the number of pulses in a series (the total number of pulses in each series is determined by the total number of electrodes 4) with a series repetition rate close to the repetition rate of the natural wave of motility, and a control synchronizer that generates the frequency that is necessary to form the required duration of stimulating pulses (6-10 ms), while the input of the control synchronizer is the input of the pulse shaper 8, and the output is connected to a controlled frequency divider.

 The proposed electrical stimulator works as follows.

An electrical stimulator is introduced into the patient’s gastrointestinal tract by ingestion. A series of rectangular pulses with parameters optimized for a given section of the gastrointestinal tract come from the pulse shaper 8 to the electrodes 4. In this case, in a pause between the series of pulses, the environmental monitoring unit 5 measures the impedance between the electrodes 4, and the measurement results are sent to the corresponding inputs analyzer 6 signal level. The signal level analyzer 6 is connected to the microprocessor 7 by means of multiphase communication, each of which is an input to the corresponding program of the microprocessor 7 containing a certain group of stimulating parameters. In accordance with each program, the parameters of the 8 pulse shaper are controlled depending on its design, such as:
its shutdown in the storage mode, in which the pulse shaper 8 is in static mode with minimal power consumption from the power source 3, which significantly increases operational reliability;
its inclusion in contact with a liquid medium (in the gastrointestinal tract);
the amplitude of the stimulating pulses, which is in functional dependence, for example, on the pH of different parts of the gastrointestinal tract, which allows the proposed electrical stimulator to perform the functions of an autonomous diagnostic pH monitor;
the number of electrostimulating pairs of bipolar electrodes 4 involved in stimulation to enhance or attenuate the pulse effect;
the choice of the required switching of the electrodes 4, in which, for example, simultaneously or alternately, the formation of electrostimulating pairs from bipolar electrodes 4 is carried out both within each group and from the electrodes of both groups. The above-mentioned formation of electrostimulating pairs, the directions of the electric field intensities of which are mutually orthogonal, provides simultaneous or alternate excitation of both longitudinal and circular layers of muscle tissue, regardless of the orientation of capsule 1 in any section of the gastrointestinal tract, which significantly increases the efficiency of electrical stimulation;
sorting out the combinations of the above pairs, each of which is shifted relative to the previous combination, for example, by a set step, which creates a circular scanning effect on the muscle tissue of the gastrointestinal tract, which significantly increases the degree of effect of electrical stimulation. The above effect is possible due to the presence of a large number of electrodes, their location, small temporal value of the pause between series of pulses and the small speed of the capsule;
pause duration between series of pulses;
the duration of individual pulses.

 An electrical effect on muscle tissue causes, in particular, the appearance of a response in the form of a stable wave of peristalsis, which promotes an electrical stimulator and contents, for example, of the intestinal tract, into its distal sections, to which another series of impulses is applied, and the process repeats.

Claims (3)

 1. The gastrointestinal tract electrical stimulator, containing the capsule in which the power source is located, two electrodes are made on the outer surface of the capsule, characterized in that serially connected environmental monitoring unit, a signal level analyzer, a microprocessor and a pulse shaper are inserted in a capsule, n electrodes, where n 2, 3, 4, and is determined by the degree of therapeutic effect and the technological feasibility of manufacturing electrodes, the electrodes are connected to the outputs of the pulse shaper and with the inputs of the environmental monitoring unit, while all the electrodes are located on the outer surface of the capsule.  2. The pacemaker according to claim 1, characterized in that the capsule is made in the form of a tubular element with caps, at the opposite ends of which along the cylindrical surface there is one group of electrodes.  3. The pacemaker according to claim 1, characterized in that the capsule is made in the form of two connected caps, on each of which along the forming surface there is one group of electrodes.

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