FR2684872A1 - ELECTROSTIMULATION DEVICE BY HIGH FREQUENCY CURRENTS MODULATED BY LOW FREQUENCY CURRENTS. - Google Patents

Abstract

An electrostimulation device using high-frequency currents, comprising a means for on-off modulation of high-frequency signals by various low-frequency signal modes, which signals sporadically receive their values from a set of low-frequency modes having transmission periods of about 10-15 ms and a duty cycle, i.e. the transmission time/period ratio of the signal, of about 0.19-0.41.

Description

 The present invention relates to an electrostimulation device, by high frequency currents modulated by low frequency currents.

 This device is intended in particular for the withdrawal and detoxification of drug addicts, the regulation of biorhythms, electro-analgesia for chronic and post-operative pain, stress suppression, and electro-drug anesthesia for major operations.

 There is already known an application of electrostimulation to the anesthesia of patients who have to undergo a surgical intervention. This avoids the patient having to endure an awakening that is known to be uncomfortable, as well as frequent post-operative complications.

 In addition, savings are made by reducing or even eliminating the doses of usual drugs.

 Various methods and devices for electrostimulation are known in the prior art. Thus, the applicant has already described in French patent 1 350 877 a method and a device for electric anesthesia by application of high frequency currents, emitted according to successive oscillation trains separated by dead intervals.

 According to other methods, the regimes of the currents used are varied continuously, in the hope of thus achieving regimes useful for stimulation, without however these having been identified.

 However, such methods have the drawback of emitting a large quantity of signals, the regimes of which are inadequate for achieving effective neurostimulation. These signals are transmitted in a completely useless, if not harmful, manner, which makes neurostimulation ineffective for a portion of the total duration of treatment.

 The present invention aims to improve the efficiency of such an alternating emission of different current regimes by defining the most appropriate regime changes to avoid habituation of the patient.

 The object of the present invention is a device for electrostimulation by high frequency currents, characterized by the fact that it comprises means for modulating all or nothing these high frequency signals by different regimes of low frequency signals which take sporadically their values among a set of low frequency regimes whose emission periods are between approximately 10 and 15 ms and whose cyclic ratio, that is to say the ratio of the duration of emission of the signal to its period , is between about 0.19 and 0.41.

 Thus, the signals transmitted by the device of the invention satisfy the condition, corollary of the preceding ones, according to which the duration of transmission of the signals is between approximately 2.9 and 4.1 milliseconds.

 According to a preferred embodiment of the invention, one of the regimes of the set of low frequency regimes is chosen as the pilot regime, that is to say as the main signal for modulating the high frequency signal, while the other low regimes frequencies intersect successively, the pilot regime being systematically restored between two of these regimes.

 In other words, the pilot regime is the low frequency regime chosen to systematically succeed any other low frequency regime.

 Advantageously, the pilot regime is chosen for the one with the highest duty cycle.

 In a preferred variant of this embodiment, the pilot regime begins the modulation, then it is followed by the regime with the lowest duty cycle. Then the pilot speed is restored and again replaced by the speed with the highest duty cycle, that is to say immediately lower than that of the pilot speed.

 We have thus defined with only three low frequency regimes a succession of four phases which constitute a cycle, which can be repeated as long as necessary without the appearance of any habituation phenomenon.

 In a particular embodiment of the invention, the set of low frequency regimes is constituted by a first regime with a period close to 12 ms and a duty cycle of approximately 0.33; by a second regime whose period is around 13 ms and whose duty cycle is close to 0.23; and by a third regime of about 10 ms period and a duty cycle close to 0.30.

According to a preferred variant of this embodiment, the succession of the plans obeys the following succession rules
In a first phase called the pilot phase, the speed with the highest duty cycle (ie the first speed or pilot speed) is used to transmit the low frequency signals for a few hours, preferably two hours.

 Then, for a period of between ten and thirty minutes, preferably fifteen minutes, the regime with the lowest duty cycle (ie the second regime), replaces the pilot regime.

 In a third phase, the pilot scheme is again emitted for a period of between half an hour and two hours, preferably one hour.

 Finally, during a fourth phase, the speed with the highest duty cycle outside of the pilot speed (i.e. the third speed), comes to interrupt the pilot speed again for twenty minutes, then the cycle of these four phases start again.

 In other words, the low frequency regimes succeed each other with an alternation of pilot regimes and non-pilot regimes following a repetitive cycle which comprises at least four phases, the first phase corresponding to the emission of the pilot regime for a period of between one hour and three hours, and preferably for two hours, the second phase corresponding to the emission of a regime different from the pilot regime and whose duty cycle is lower for a period of between ten and thirty minutes, and preferably for twenty minutes, the third phase corresponding to emission of the pilot regime for a period of between half an hour and two hours, preferably for one hour, and the fourth phase corresponding to the emission of a regime different from the pilot regime and whose duty cycle is higher than that of the second phase regime for a period of between fifteen and thirty minutes s, preferably twenty minutes.

 Furthermore, the high frequency signal, modulated by the various low frequency signal regimes, is advantageously two-phase.

 Indeed, during the duration of transmission of this signal, the high frequency voltage is positive while it is negative during the rest of the period of emission of the high frequency signal.

 The values of the period and duration of transmission of the high frequency signal are chosen such that the variation curve of the voltage of the high frequency signal delimits, on either side of the zero voltage axis, two algebraic surfaces whose sum is zero.

 In other words, the average intensity delivered by this high frequency current is zero, which allows the patient to tolerate a voltage of several tens of volts while the energy transmitted to his brain has a fairly low value. but not zero, which results from the modification of the electrical characteristics of the signal after crossing the particular dielectric which constitutes the skull of the patient.

 Preferably, the duration of positive transmission of the high frequency signal is between 0.9 and 3.75 pus and its period is between 4 and 10 ps.

 More precisely, the ratio of these two times, ie the duty cycle, must be between 0.20 and 0.40.

 The device of the present invention comprises, for performing transcutaneous brain stimulation, an ophryaque electrode and a pair of retro-mastoid electrodes, the latter two being electrically connected.

 According to a first variant of this embodiment, the signals are also applied between the ophryaque electrode and a low occipital electrode. The ophryaque electrode then operates alternately with the pair of retro-mastoldian electrodes and with the low occipital electrode, the signals of this application being out of phase with those applied between the ophryaque electrode and the retro-mastoldian electrodes.

 In this variant, the device according to the invention comprises means making it possible to send alternately to the retro-mastoldian electrodes and to the low occipital electrode and with a determined phase shift the high frequency signals modulated at low frequency.

 According to a second variant, the signals are also applied between a second ophryaque electrode and a low occipital electrode, which makes it possible to make the two sets of electrodes thus formed completely independent. It is in fact understood that, in this way, each set of electrodes has its own ophryaque electrode.

 According to this variant, the two ophryaque electrodes are electrically distinct but physically merge, so as to apply their signals to the same place.

 Thus, between the electrodes of each set of electrodes, two electric fields appear which are strictly electrically distinct.

 In this particular variant, a phase shift can be determined so as to imply a partial overlap of the two electric fields during a common interval of emission of the signals.

 The common action of two alternating or partially alternating electric fields in these regions of the skull has the advantage of stimulating the peri-aqueductal region whose analgesic role is known, without however creating local overdensity of current thanks to the phase shift between the signals.

In order to better understand the invention, we will now describe an embodiment given by way of non-limiting example of the scope of the invention and shown in the drawing in which
- Figure 1 shows a variation curve as a function of time of the voltage of a high frequency signal emitted by the device of the invention.

FIG. 2 represents a modulation by a low frequency signal of the high frequency current of FIG. 1, in accordance with the invention,
FIG. 3 represents, according to one embodiment of the invention, electrodes placed on the head of a patient,
FIG. 4 represents two high frequency currents modulated in phase shifted low frequency, emitted according to the embodiment of FIG. 3, and
FIG. 5 represents two high-frequency modules with phase-shifted frequency bases emitted according to an embodiment similar to that of FIG. 3.

 In FIG. 1, the high frequency signal has a period equal to 6 days and a transmission time t 'equal to 1.2 days.

 This high frequency voltage goes from a negative value to a positive value in an extremely short "rise time" time, between 50 and 150 ns.

 The "fall time", that is to say the time from a positive value to a negative value, of the voltage of the high frequency signal is of the same order of magnitude, ie approximately 50 ns.

 We see that the duty cycle of high frequency waves, or in other words the ratio of the positive transmission time t 'to the transmission period> is equal to 0.20, a value which is well understood in the range 0.20 to 0.40.

 According to the invention, this signal has a zero mean current, that is to say that it delimits around the zero voltage axis a surface S1 in its positive part equal to that delimited in its negative part S2.

 In Figure 2, the signal in Figure 1 is modulated by a low frequency signal.

 This low frequency signal has a period T and a duty cycle whose values are close to 12 ms and 0.33.

 By means of this modulation, the duration t of emission of the low frequency signals corresponds to the time of passage of the high frequency wave train.

 In Figure 2, the unit of the time scale is the millisecond, while the period of the high frequency signals is of the order of a microsecond, which is why the shape of the high frequency signal is represented by rectangles thin vertical.

 FIG. 3 represents electrodes placed on the skull of a patient, according to an embodiment of the invention.

 Electrodes 1a and 1b are said to be ophryaque while two electrodes 2a are said to be retromastoid and one electrode 2b is said to be low occipital.

 To clarify the drawing, the two ophthalmic electrodes 1a and 1b have been shown one next to the other, but it is obvious that these two electrodes are merged in the same location.

 In a variant, they can be replaced by a single ophryaque electrode which simultaneously plays the role of both.

 The electrodes form two sets of electrodes generally designated by a and d.

 The first a consists of the ophryaque electrode la and the pair of retromastoid electrodes 2a, while the second b comprises the other ophryaque electrode lb and the low occipital electrode 2b.

 Between each set of electrodes, an electric field applies, the shape of the current lines of which has also been shown in this FIG. 3.

 It is clearly seen that the two retromastoldian electrodes 2a are electrically coupled while an electric field shown in solid lines applies between, on the one hand, the electrode la and on the other hand, the pair of electrodes 2a.

 Another electric field, shown in broken lines, applies between the ophryaque electrode 1b and the low occipital electrode 2b.

 In this embodiment, the neuro-stimulation therefore takes place thanks to the joint action of two electric fields, which in particular makes it possible to reach the PAPEZ circuit which is composed of the crosslinked formation, of the hippocampus, of the amygdala, the hypothalamus and the ventral peri-aqueductal region which is known to have analgesic properties.

 According to this embodiment, the wave trains of the signals of each electric field applied to the sets a and b of electrodes are phase shifted by a time 9 as shown in FIG. 4.

In this figure, V represents the voltage applied between the
a electrodes la and 2a while Vb represents the potential difference between lb and 2b.

 Thanks to the use of two ophryaque electrodes, the embodiment of the device according to the invention allows partial overlapping R of the wave trains of the signals. However, local overdensity of current is avoided thanks to a significant phase shift.

 FIG. 5 represents two signals emitted by another embodiment of the invention, similar to that represented in FIG. 3.

 Unlike the previous figure, the signal offset here is total, without partial overlap of the probe trains a and b.

 It is observed that in this particular embodiment, the phase shift 9 is strictly equal to the duration of transmission of the signals, so that the voltage Vb immediately succeeds the voltage Va.

In addition, in the variant shown, the duration without emission is also identical to cl
Thus, the period T is divided into three portions of identical durations 9: the emission of a signal by the set of electrodes a, the emission of a signal by the set of electrodes b and the absence resignation.

 It is understood that the embodiment which has just been described does not have any limiting character and that they can receive any desirable modifications without departing from the scope of the invention.

Claims (10)

 1 - Device for electrostimulation by high frequency currents, characterized in that it includes means for modulating all or nothing these high frequency signals by different regimes of low frequency signals which sporadically take their values among a set of regimes low frequencies whose transmission periods are between approximately 10 and 15 ms and whose duty cycle, that is to say the ratio of the duration of transmission of the signal to its period, is between approximately 0.19 and 0 , 41.  2 - Electrostimulation device according to claim I, characterized in that the set of low frequency regimes is constituted by a first regime with a period close to 12 ms and a duty cycle of about 0.33; by a second regime whose period is approximately 13 ms, and whose duty cycle is close to 0.23; and by a third regime of approximately 10 ms of period and duty cycle close to 0.3.  3 - Electrostimulation device according to any one of the preceding claims, characterized in that the set of low frequency regimes comprises a pilot regime which systematically follows any other low frequency regime during the modulation of the high frequency regime.  4 - Electrostimulation device according to claim 3, characterized in that the regime with the highest duty cycle is chosen as the pilot regime.  5 - Electrostimulation device according to any one of claims 3 and 4, characterized in that the low frequency regimes succeed one another with alternating pilot regimes and non-pilot regimes following a repetitive cycle which comprises at least four phases, the first phase corresponding to the emission of the pilot regime for a period of between one hour and three hours, and preferably for two hours, the second phase corresponding to the emission of a regime different from the pilot regime and whose cyclic ratio is lower for a period of between ten and thirty minutes, and preferably for twenty minutes, the third phase corresponding to the emission of the pilot regime for a period of between half an hour and two hours, preferably for one hour, and the fourth phase corresponding to the emission of a regime different from the pilot regime and whose duty cycle is greater to that of the regime of the second phase for a period of between fifteen and thirty minutes, preferably twenty minutes.  6 - Electrostimulation device according to any one of the preceding claims, characterized in that the period of the high frequency signal is between 4; js and lOjis and that its duty cycle, that is to say the ratio of the duration of positive issue during the period is between 0.20 and 0.40.  7 - Electrostimulation device according to any one of the preceding claims, characterized in that the average intensity of the high frequency current is zero.  8 - electrostimulation device according to any one of the preceding claims, characterized in that the signals are applied between on the one hand, an ophryaque electrode (la) and on the other hand two retro-mastoldian electrodes (2a) connected electrically between them.  9 - Electrostimulation device according to claim 8, characterized in that the signals are also applied between the ophryaque electrode (la) and a low occipital electrode (2b), the signals of this application being out of phase with those applied between the ophryaque electrode and the retromastoldian electrodes.  10 - Electrostimulation device according to claim 8, characterized in that the signals are also applied between a second ophryaque electrode (lb) and a low occipital electrode (2b) the signals of this application being out of phase with those applied between the first ophryaque electrode (la) and the retromastoldian electrodes (2a).