NL8503057A - Electromagnetic treatment of tissue without surgical implantation - uses quasi-rectangular asymmetric pulses of energy of frequency 10 to 10000 Hz - Google Patents

Abstract

The process for the treatment without surgical implantation of tissues and/or living cells includes use of electromagnetic induction using quasi-rectangular assymetric pulses of associated voltage and intensity having a specific frequency-amplitude relationship. Each pulse comprises a first part with relatively large amplitude and short duration, alternating with a second part of opposite polarity having a smaller amplitude and longer duration. The amplitude of the peak of the first part is 40 times that of the second part, while the duration of the first part is not more than 1/4 of that of the second part. A frequency of 10, 10,000 H2 is used with a voltage of 0.0001 to 0.01 V/cm of tissue.

Description

* N.O. 33391 1

Device for performing a surgical treatment of living tissues and / or cells without surgical intervention.

The invention relates to a device for performing a surgical treatment of living tissues and / or cells without surgical intervention, consisting of an impulse generator and at least one associated coil which is suitable for outside, but in the immediate vicinity of the live tissues and / or cells to be treated, wherein the impulse generator in the inductor coil can generate a substantially sawtooth alternating current, so that the living tissues and / or cells in the immediate vicinity of the inductor coil are periodically electrically operated. voltage pulses are generated, each voltage pulse consisting of a first pulse signal portion with a first polarity connecting to a second pulse signal portion with a polarity opposite to the first.

A device of this type is known from Dutch Patent 7301054.

In the treatment of living tissues and / or cells, this known device has obtained a favorable therapeutic influence on the growth-restoration and maintenance behavior of such tissues and / or cells. However, it has been found that in many cases, especially with long-lasting bone fractures, the desired therapeutic effect did not occur, or at least insufficiently.

the object of the invention is therefore to provide a device which, more particularly in the treatment of bone fractures, gives a better therapeutic effect than the known device.

The present invention is based on fundamental studies and analyzes of cells, with detailed considerations devoted to the interaction between nested particles, such as divalent cations, and hormones at the transitions and interfaces of cells.

In principle, it has been established that by changing the electrical and / or electrochemical environment of a living cell and / or tissue, a change and often even a favorable therapeutic influence can be obtained on the growth, repair and maintenance behavior. of said tissue and / or said cells. This change or influence is accomplished by subjecting the desired tissue and / or cell region to a specially encoded electrical voltage and associated current, thereby interacting the charged particles on the surfaces of the cells> 5 ^ v Sy s * 2 changed. Such changes cause a change in the state of the function of the cell or tissue, which may result in a favorable influence on the treated site. With a certain electrical code, a change can be made in the ability to synthesize proteins from the same cell.

For example, experiments with tissue cultures to study limb rudiments of chick embryos have shown that this code causes increased protein production by similar suitable osteogenic cells. This effect also depends very specifically on the parameters of the electrical code. In other words, this code affects certain metabolic processes in these cell types, such as occur when calcium is absorbed or donated by mitochondria, or the synthesis of collagen, a basic structural protein of bone tissue.

These studies show that the electrical codes elicit individual tissue and cell responses, indicating that each code has a very special information content. Based on these and other studies, it has been found possible to use coded signals to obtain a special response necessary for the functional healing of leg disease. This electrical code has been successfully applied in human and animal patients to non-healed fractures, such as congenital pseudarthrosis and non-healing sites, and to fresh fractures. Particular mention should be made of the successes achieved in the treatment of congenital pseudo-arthosis, since usually 80Z of the children suffering from this disease have to undergo amputation, since conventional treatments such as bone grafting and internal fixation, yielded no result.

Although many studies have been conducted in the past regarding responses of living tissue and / or cells to electrical signals, clinical results using known techniques have so far not always been favorable and have not been in the relevant professional circles general accepted. Indeed, it has heretofore not been realized that electrical signals having a very specific information content are necessary to obtain a very special desirable beneficial clinical effect in tissues and / or cells.

However, the surgical, non-intrusive, direct inductive coupling of the electrical information content of special electrical codes according to the present invention now yields in the living tissue and / or v I-it, Λ * 31 CSS5 -1.:, \ i · Λ »f» ^ '/> V ./ 3 ft * the living cells have a controlled response.

Briefly, the present invention is based on the understanding that the growth, repair and maintenance behavior of living tissues and / or cells can be advantageously modified by the use of special electrical information.

The object of the invention is therefore achieved with a device of the above-mentioned type, which device according to the invention is characterized in that the voltage pulses induced in a measuring coil which is at a distance from the induction coil, currently substantially corresponding with the distance that the induction coil has in the treatment of tissue and / or cells from it, meets the following requirements: a) the duration of the first pulse signal part is at least 4 times the duration of the second pulse signal part, which lasts a maximum of 50 ps , 15 b) the highest amplitude of the second Pulse signal part does not exceed 40 times the highest amplitude of the first pulse signal part, the amplitude in the first pulse signal part not falling further than 25% of the highest amplitude, c) the repetition frequency of the pulses is between 2000 Hz and 1000 20 Hz, d) the first Pulse signal portion corresponds to a field strength of n 0.01-10 mV / cm and the second pulse signal portion corresponds to a signal strength of less than 50 mV / cm, which voltage pulses are further generated in groups with a group repetition frequency of 5-50 Hz, where a group contains at least 1% of the takes the duration of the lead corresponding to this group repetition frequency.

The invention will be better understood after reading the following detailed description and with reference to the drawing, in which: figure 1 is a simplified view showing the treatment of a bit, figure 2 is a perspective view of a treatment unit shown in Figure 1, Figure 3 is a rear view of the unit shown in Figure 2, showing the placement of a coil arranged for treatment purposes, Figure 4 is a block diagram of an electrical device for energizing the coil of Figure 3, 40 Figure 5 is a diagram showing the voltage pulses induced - · V * 4 in the tissue to be treated and / or the cells to be treated, Figure 6 shows other forms of negative impulse parts.

In Figures 1-3, 10 indicates the leg of a patient with a bone fracture indicated by 12, which is an example of a case in which the invention is used to stimulate bone growth for medical purposes. A treatment head 14 is positioned on the outside of the patient's skin and attached using a strap 16 (which is attached to the head 14 by fasteners 16a). A material 18 can be applied to this belt 16, whereby the belt is wrapped around the leg and the treatment head and the treatment head is held against the leg at the desired location.

Foam material 20 which acts as a cushion against the leg and which is further useful for ventilation purposes may be provided on the inner surface of the treatment head 14. They note that the inner surface of the treatment head 14 is curved in its entirety so that it joins the leg under treatment.

In the treatment head 14 there is a coil 22 of a suitable shape. * As shown in Figure 3, the coil 22 is generally of a rectangular shape, so that through the windings of the coil in the center thereof, a "window" arises. The coil can be flat or bent according to the curved shape of the treatment head 14. The coil 22 is provided with terminals 24 protruding from the treatment head 14 and can be connected with a cable 26 forming the connection with an appropriate power circuit, as will be explained in more detail below.

The treatment head 14 is applied to the patient such that the "window" formed by the coil 22 is at the fracture 12, i.e. at the tissue to be treated. The coil 22 is energized in a manner which will be explained further below, and induces an electrical voltage in the tissue to be treated. It has been found that a special type of signal must be induced in the tissue and that it is obtained by energizing the coil 22 through a circuit shown in Figure 4 to obtain the pulse signal shown in Figure 5.

In Figure 4, it is indicated that a variable yaw voltage source 30 is connected through a port 32 and a port 33 to the treatment coil 22 (or optionally the coils, as will be further explained below). Gate 22 is controlled by control units 34 and 36, which provide voltage pulses through treatment coil 22. * v '-Λ3. «1 lï? v v · * <» i * o -¾ A. ** / ί J v /' V V $ 5 induced in the tissue to be treated. Each pulse, as can be seen in Figure 5, consists of a "positive" pulse portion followed by a "negative" pulse portion, because of the electrical energy stored in the treatment coil 22.

Figure 5 shows the voltages to be induced in a measuring coil via the treatment coil 22. The measuring coil is located at a distance from the treatment coil, at least substantially corresponding to the distance the treatment coil has in the treatment of tissue and / or cells. It may be assumed that the variation of the voltage induced in the tissue corresponds to the voltage induced in the measuring coil.

Thus, it is assumed that at time t1 the gate 32 is opened by a suitable signal from the control unit 36 (a pulse width control unit), so that the voltage across the measuring coil jumps from about 0 volts along the Pulse segment 39 to a certain value vl in figure 5. The voltage across the measuring coil then decreases along a second impulse segment, along the part of the curve indicated by 40 in figure 5. The slope of this curve is determined by the L / R time constant of the circuit of Figure 5, ie the self-induction of the treatment coil and the effective resistance of the circuit, including the distributed capacitance, self-inductance and resistance. It is desirable for the treatment of many tissues and cells to adjust the circuit parameters so that the portion 40 of the curve is as flat as possible, so that the voltage occurring across the measuring coil is as rectangular as possible. At time t2, gate 32 is closed by control unit 36. Just before the gate is closed, the voltage across the measuring coil has the value v2, indicated in figure 5. The voltage across the measuring coil changes when the gate 32 is closed via a third imp-30 pulse segment 41 from the value v2 to a voltage with opposite polarity, indicated by v3 in figure 5. The voltage across the measuring coil 22 then decreases from the value v3 to zero, finally reaching this value at the time t3. A predetermined period of time elapses before the pulse repetition frequency control unit 34 outputs an appropriate time signal for actuating the control unit 36 for generating a signal opening gate 32 for reactivation. the cycle just described.

Further control units 35 and 37 are used to control gate 33 such that each of them during a discharge period (per-

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period t1 ... t5 in figure 5) a series of the pulses described above are passed to the coil 22, followed by a period (period t5 ... t6 in figure 5) in which no pulses are transmitted. The control unit 35 thereby determines the width of said discharge period 5 and the control unit 37 determines the repetition frequency of these discharge periods (and thus the duration of the total period t1 ... t6).

For example, the controllers can be monostable multivibrators to generate suitable time signals and they can be adjustable to control the duration and repetition frequency of the pulses within desired limits. Furthermore, the use of an adjustable DC voltage source 30 makes it possible to adjust the amplitude of the pulse signals as required.

They have found that for a satisfactory and effective treatment of living tissues and cells, especially hard tissue such as bone, the following criteria must be met.

In the following explanation, the terms "positive" and "negative" are intended to be relative designations and are used subsequently to indicate that the impulse portions have opposite polarities to a reference potential level.

It has been determined that the "positive" impulse portions exist in a predetermined relationship to the "negative" impulse portions, in order to favorably influence the behavior of living tissues and cells and with uniform results.

The asymmetric waveform induced in the tissues or cells by alternately energizing and extracting energy from an electric coil consists of periodically occurring discharge periods with a series of asymmetric pulses in each discharge period as shown in Figure 5. Each discharge period (tl ... t5) has a duration such that the discharge period takes at least 1% of the entire period duration (tl ... t6). The repetition frequency of the discharge periods is, for example, 5-50 Hz.

The fundamental ratios for the respective frequency-amplitude contents of the "positive" and "negative" pulses in a discharge period are as follows: each "positive" pulse portion must be composed of at least three segments, for example segments 39, 40 and 41 in Figure 5. It has also been found that a substantially rectangular shaped "positive" pulse signal portion is particularly useful in the treatment of tissues and cells. However, it is possible that impulse configurations other than a simple three-segment peak 40 may also be effective. The peak amplitude of the -V -η '• χ * "9 + 7 last segment of each" positive "impulse section, for example the potential v2 in Figure 5, should not be less than about 25% of the peak amplitude of the first segment 39 of the "positive" impulse signal portion, for example, the potential v1 in Figure 5.

5 The "negative" peak amplitude is indicated by v3 in Figure 5.

This "negative" peak amplitude should not exceed about 40 times the "positive" peak amplitude (in this case vl). This alder can be satisfied by applying "negative" impulse sections with a number of different waveforms. » for example, substantially rectangular, trapezoidal shape with an exponential decrease, bell-shaped, or a single peak with an exponential decrease, as shown with waveforms a, b, c, and d in Figure 6.

The duration of each "positive" pulse portion (the time that elapses between times t1 and t2 in Figure 5b) must be at least 4 times the duration of the next "negative" pulse portion (the time that elapses between times t2 and t3 in Figure 5). As noted above, since an electromagnetic coil is used in the treatment device, the energy of each "positive" impulse portion is equal to the energy of each "negative" impulse portion, ie, the area in Figure 5, which is surrounded by the "positive" impulse portions is equal to the area surrounded by the "negative" impulse portions.

The replay frequency of the pulses In the discharge period (related to the time elapsing between times t1 and t4) may be between about 2000 Hz and 10000 Hz.

The width of the pulse train discharge period (the time elapsing between times t1 and t5) should be at least about 1% of the time elapsing between t1 and t6.

If the above criteria are met, then these ratios also ensure that the "positive" and "negative" pulse signal portions have the correct frequency araplitude characteristic sign with respect to themselves and each other, so that a favorable change in behavior from tissues and cells.

They have found that in addition to these ratios just mentioned, the mean magnitude of the "positive" peak potential should be in the range between about 0.01 and 10 mV / cm of tissue and / or cells, which corresponds to about 0.01 and 10 mA / cm 2 tissue and / or cells to be treated.

They have found that higher or lower pulse potentials do not result in a favorable influence on the tissues and / or cells.

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It has also been found that the repetition rate of the release segments should preferably be in the range of about 5-15 Hz for bone and other hard tissues.

Each "negative" pulse portion of each pulse should have a duration no longer than about 50 msec and an average amplitude no greater than about 50 mV / cm of tissue and / or cells to be treated, corresponding to about 50 mA / cm ^ tissue and / or cells to be treated.

It has been found that for the treatment of bone diseases, and more particularly for the treatment of pseudarthrosis and non-healing sites, an optimally induced "positive" impulse signal portion with a spot amplitude between about 1 and 3 mV / cm tissue to be treated (ie 1-3 mA / cm 2 to be treated tissue and / or cells), with a duration of each "positive" pulse signal portion of about 200 msec, and a duration of each "negative" pulse signal portion of about 30 msec and a time course between the times t3 and t4 in Fig. 5 of 10 20 msec., and a pulse repetition frequency of about 4000 Hz and a discharge segment width of about 5 msec and a discharge repetition frequency of about 10 Hz, a presently preferred and optimally induced Pulse Treatment for bone if the above impulse requirements are met.

Treatment of living tissues and cells with the devices described above and more particularly of hard tissues, such as bone, has shown an increased recovery response and uniform results have generally been obtained in all treatments of human and animal patients. Particularly favorable results have been obtained in the treatment of pseudo-arthosis in cases where a convergence of bone parts was obtained after previous attempts with other treatment methods had failed and amputation had been considered as a possible alternative for restoration of function.

For example, regarding coil parameters, coil windows of about 5.0 cm x 6.9 cm (for adults) and 5.0 cm x 3.8 cm (for children) have been found suitable for bone fractures. The wire used for the coil can be copper wire with a diameter of 2.053 mm, which is covered with a layer of varnish in order to insulate the turns from each other. Reels with about 60 turns for an adult and 70 wins for a child are found to be suitable. For oral cavity treatments, the dimensions of the coil should be correspondingly small.

The inductance of the treatment coil should be between about 5 μH and 5 mH, and preferably between 1 and 3 MH, and the spring position should be sufficiently low (for example, 10 "^ - 10-½) for a strong input signal to the coil, between about 32 V, to induce the appropriate pulse potential in the treated tissue and / or the treated cells As the inductance of the treatment coil becomes smaller, the slope of the curve 40 becomes steeper. generated "positive" * impulse flatter or more rectangular.

The induced potential can be sensed with a measuring coil arranged next to the treatment coil 22 at a distance corresponding to the distance between the material to be treated and the treatment coil. For example, a used measuring coil is circular with a diameter of about 0.5 cm and with about 67 or 68 turns. The potential generated by the coil is divided by the length of the wire (in cm) to obtain the induced voltage per cm, which corresponds to the number of induced V / cm of treated tissue and / or cells under treatment.

Examples

In order to demonstrate the effectiveness of applying the direct inductive coupling of electromagnetically induced, pulsating voltages and simultaneously occurring currents for the growth and repair of hard tissue, applications have first taken place in cases of innate and acquired pseudo- arthrosis. From a group of patients, only those who had previously had unsuccessful surgical treatment were accepted (inoculation, internal fixation). For most of these patients, at least one qualified orthopedist had suggested the amputation. In some cases, the main problem was the lack of a bone matrix, which could be made radiographically visible in the form of slits in the bone of more than 2 mm in width at the fracture site. In those cases, a treatment according to the invention resulted in the production of collagen, which is the main supporting protein in the bone structure.

To date, approximately 30 patients have been treated with this abnormality, with 75% of treated patients achieving success by reuniting the leg pieces.

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These clinical results clearly demonstrate that, once the special pathology of bit disease has been established, favorable selective treatment can be achieved using the appropriate coded changes of the electrical environment.

Similar results have been obtained in a study of lateral fermoral and radial osteotomy in 160 rats. These animals were divided into two main groups; one group was treated and the other group served for control for 14 days after surgery. At autopsy, the extent of the fracture repair was determined by X-rays and tissue evaluation, along with non-destructive mechanical testing. These animal experiments were used to evaluate the effectiveness of the treatments. When the osteotomic fissure was generally wider than 0.1 mm, compared to the control animals, significantly increased matrix production was observed in the treated animals after treatment.

This has further evolved by investigating the behavior of these bones in mechanical testing. This was done by loading a rat's bone as a console on various deformations according to the test method described in 20 "Acceleration of Fracture Repair by Electromagnetic Fields. A Surgically Noninvasive Method" by C.A.L. Bassett, R.J. Pawluk and A.A. Pilla, published in the aforementioned "Annals of the New York Academy of Sciences," biz. 242-262. The samples were deformed in the antero-posterior, the lateral-medial, the postero-anterior, the medial-lateral, and again in the antero-posterior positions.

In summary, it can be said that a unique electromagnetic and surgical, non-intrusive treatment technique has been described. Induced impulse characteristics, which relate to the time-frequency-amplitude ratios of the entire impulse or irapulse sequence, appear to be very significant. Selecting special time-frequency araplitude ratios is key to successfully treating different cell behaviors in a wide variety of tissues.

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Claims (1)

1. Device for performing a surgical treatment of living tissues and / or cells without surgical intervention, consisting of an impulse generator and at least one associated induction coil suitable for treatment outside, but in the immediate vicinity of the live tissues and / or cells, wherein the pulse generator in the induction coil can generate a substantially sawtooth alternating current, thereby periodically generating electrical voltage pulses in the living tissues and / or cells located in the immediate vicinity of the induction coil each voltage pulse consisting of a first pulse signal section having a first polarity adjacent to a second impulse signal portion having a polarity opposite to the first, characterized in that the voltage pulses induced in a measuring coil spaced from the induction coil , at least substantially corresponding to the distance that the induction coil has in the treatment of tissue and / or cells relative to it satisfies the following requirements: a) the duration of the first pulse signal part is at least 4 times the duration of the second pulse signal part, which lasts a maximum of 50 ps , b) the highest amplitude of the second pulse signal portion does not exceed 40 times the highest amplitude of the first pulse signal portion, the amplitude in the first Pulse signal portion falling no further than 25% of the highest amplitude, 25 c) the repetition frequency of the pulses are between 2000 Hz and 1000 Hz, d) the first pulse signal portion corresponds to a field strength of 0.01-10 mV / cm and the second pulse signal portion corresponds to a signal strength less than 50 mV / cm, which voltage pulses are further generated in groups with a group repetition frequency of 5-50 Hz, where a group contains at least 1% of the corresponding frequency for this group repetition frequency e takes a period of time. ********* - ·> r - * i C J - 0 -