HRP20211548A1 - Device for organism therapy comprising methods like electro-analgesic therapy and/or edema therapy - Google Patents

Abstract

The invention relates to a device for treating an organism including procedures such as electro-analgesia treatment and edema treatment (100). The device (100) contains at least one pair of electrodes, each electrode having a contact surface for contact with the organism, a current generator arranged to deliver an electrical signal as output to the positive and negative poles, and a processor (1) arranged to manage the electrical signal. In use, an electrical signal is transmitted to the body. The electrical signal is characterized by a period from 1ms to 10s, whereby the electrical signal contains within one period at least one positive and one negative peak value, which has the duration of the positive or negative peak value, with the duration of the peak values being shorter than 9µs, the peak current strength is at least 45mA, and the total power of the electrical signal is less than 75mW. The invention relates to a device for organism therapy comprising methods like electro-analgesic therapy and oedema therapy (100). The device (100) comprises at least one pair of electrodes, each electrode having a contact surface for contact with the organism, a current generator arranged to deliver an electrical signal as output to the positive and negative poles, and a processor (1) arranged to manage the electrical signal. In use, an electrical signal is transmitted to the body. The electrical signal is characterized by a period from 1 ms to 10 s, whereby the electrical signal comprises within one period at least one positive and one negative peak value, which has the duration of the positive or negative peak value, with the duration of the peak values being shorter than 9 µs, the peak current strength is at least 45 mA, and the total power of the electrical signal is less than 75 mW.

Description

The field to which the invention relates

The invention relates to a device for the treatment of the organism. The device disclosed herein can be used for treatments such as electro-analgesia treatment and edema treatment. The use of the device is not limited to any of the above treatments.

Technical problem

Pain is an unpleasant feeling. Pain may be related to existing or possible tissue damage. Pain is an important biological property that is essential for life and adaptation to the environment. Despite this important role, pain relief has been a fundamental goal of medicine since the very beginnings of the medical profession.

The predominant method of pain control is the use of chemical products. However, the use of chemical products can cause side effects.

It is also known that by interfering with the normal function of nerve pathways, pain can be alleviated using electrical impulses. In fact, by properly stimulating the nerves using electrical impulses of appropriate characteristics, the function of nerve fibers affected by specific diseases such as some forms of poly neuropathy can be partially and at least temporarily recovered.

It is also known that as a result of physical illness or trauma, an abnormal accumulation of fluid can occur under the skin or in one or more body cavities. Edema is usually treated with diuretic procedures, massage and chemical products for internal and external use. Drainage of excessive interstitial fluid is preferred in the treatment of edema.

Dynamically induced mechanical drainage such as external massage is known to be used. However, the massage can prove to be excessive and sometimes does not reach deeper into the affected tissues. With trauma, it is sometimes almost impossible to apply any form of massage. Another known method involves statically induced mechanical drainage, such as the use of elastic bandages.

It is also known that the effect of deeper and more gradual drainage can be achieved by using electrical current pulses of certain properties to induce very small contractions and relaxations of the muscle tissue in and around areas affected by edema.

Furthermore, it is known that electrical impulses applied to organisms can increase the production of ATP.

The object of the invention is to improve the device and method using electrical current pulses to improve pain relief and/or edema treatment.

State of the art

In the state of the art, there are a large number of devices that produce electro-signals with the purpose of reducing pain, for example US patent US6760627B2. In the state of the art, TENS devices are known, which are used in physical therapy for the recovery of muscles and tissues as well as for reducing pain. By searching the relevant patent databases and patent applications, the inventor has not found that there is a device that functions in the manner described in this description of the invention.

Presentation of the essence of the invention

The device disclosed herein for the treatment of an organism including procedures such as electro-analgesia treatment and edema treatment includes:

- at least one pair of electrodes, of which each electrode

has a contact surface for contact with the organism

- a current generator adjusted to give an electrical signal as an output to the positive pole and the negative pole, whereby a pair of electrodes is connected to the poles, so that when the device is in use, the electrical signal is transmitted to the organism through the contact surfaces of the electrodes,

- a processor set to manage an electrical signal, wherein the electrical signal is characterized by a period (T) lasting from 1ms to 10s, wherein the electrical signal contains within one period (T) at least one positive and one negative peak value that has the duration of the positive peak value that is, the duration of the negative peak value, where the duration of the peak values is shorter than 9 µs, the peak current strength is 45 mA, and where the total power of the electrical signal is less than 75 mW.

This invention includes, among other things, a device for the induction of electro-analgesia, which in use shows obvious positive effects in the treatment of edema and which uses complex waveforms of certain electrical properties. The output electrical signal is applied to the treated part of the body so that the contact surfaces of the electrodes are placed in electrical contact with the patient's body on opposite sides of the treated part of the body.

The theory that would explain the electro-analgesic effect of certain complex waveforms applied to the treated part of the body has not been fully clarified. However, it is believed that when electrical impulses of certain electrical properties pass near pain-affected nerve fibers, they induce the movement of sodium (Na+) and chloride (Cl-) ions in the extracellular fluid surrounding the nerve. The movement of Na+ and Cl- ions results in a redistribution of ion concentration around the nerve fiber, which directly affects the way nerve signals are transmitted along the nerve fiber.

Electrical signals containing impulses can be used to induce increased randomness in the distribution of ions around a nerve fiber whereby a certain amount of noise is introduced into the electrical impulses as the electrical impulses are transmitted along the nerve fiber, so it could be said that the original information of the electrical nerve signal hidden by the forest.

Also, it is believed that the positive effect of the device presented here on edema is caused by inducing very small contractions and relaxation in the surrounding muscle tissue. These very small muscle contractions and relaxations are thought to cause increased fluid drainage from the surrounding tissue, which creates a positive effect on the treated edema.

Figure 1 shows the different waveforms generated by the device to induce an electro-analgesic effect. The amplitude of the waveforms shown in Figure 1 is the electric current output from the device disclosed in this invention.

Figure 1A. shows the waveform of an electric current signal of alternating polarity to be used in an electro-analgesic device. In Figure 1A. is the duration of the peak value of each individual electrical pulse/peak value tp the same as the duration of the pause between two alternating pulses tpp and the pause duration tpau. The cycle is formed between the beginning of the first peak value and ends after the negative peak value (tp + tpp + tp). The cycle together with tpau forms the period T.

For easier understanding of the essence of the invention, the treated part of the body is considered to be a completely electrically resistive load, although in reality it is nonlinear and has reactive components due to which the rise and fall time of the signal becomes finite.

For example, if the electrical impulses shown in Figure 1A. have the following parameters:

f = 50 Hz (tp = 9 µs, tpp = tp, tpau = 19.973 ms), I = 50 mA, Rload = 2000 Ω then the total amount absorbed by the treated part of the body per pair of alternating pulses is equal to

Q = I2 x R x (tp x 2) = 90 µJ

From the above formula, it can be calculated that the energy absorption rate of the treated part of the body is equal

W= Q x f = 4.5 mJ/s

Improved results are obtained when the duration of each electrical pulse is significantly shortened and when the amplitude of the signal is increased accordingly to keep the absorption rate of the total energy at the same value, then the electro-analgesic effect becomes more pronounced and the post-treatment pain relief effects last longer. Figure 1B. shows the waveform of the signal, which is the result of modifying the waveform of the signal shown in Figure 1A. in the manner described.

For example, if the signal with shortened duration and increased amplitude shown in Figure 1B. should have a total amount of absorbed energy equal to the signal shown in Figure 1A., the parameters used in the previous example should be corrected with the following values: f = 50 Hz (tp = 5 µs, tpp = 20 µs , tpau = 19.97 ms), I = 67 mA, Rload = 2000 Ω then the total amount of energy absorbed by the treated part of the body for each pair of alternating pulses is equal to

Q = I2 x R x (tp x 2) = 90 µJ

From the above formula, it can be calculated that the energy absorption rate of the treated body part is equal

W = Q x f = 4.5 mJ/s

The electrical signal shown in 1C. results in electro-analgesic effects that are even more pronounced, while the level of total energy absorption remains unchanged. The described modification of the signal waveform is achieved by shortening the pause tpp between two alternating peak values of one cycle tcyc while maintaining the frequency.

In fact, the electro-analgesic effect is most pronounced when the tpp pause is shortened almost to zero as soon as possible as shown in Figure 1D.

It must be noted that the waveforms shown in all figures are idealized because in reality various electrically reactive components, such as output inductance, will distort the waveforms somewhat. In particular, the rise time and fall time of electrical impulses are in reality finite as is the pause tpp.

Further improvement of the electro-analgesic effect was achieved by adding a specific amplitude of oscillation to each peak value of the electrical signal shown in Figure 2A. to increase the level of random ion movement around the treated nerve, causing more noise to be generated to improve masking of electrical nerve pain signals.

The amplitude variance of each pulse can be periodic or aperiodic with a constant or variable amplitude level.

Figure 2C. shows electrical pulses with periodic amplitude oscillations, which have been shown to have a longer-lasting analgesic effect after treatment. Figure 2C. shows the described complex waveform of the signal with the introduced periodic oscillation amplitude.

The randomness added to the ion motion can be achieved using the aperiodic amplitude variance of the electrical pulses as shown in Figure 3C. Figure 3 shows the addition of aperiodic amplitude variance to electrical pulses using a white noise signal source to modulate the amplitude of the signal. It was found that the introduction of aperiodic oscillation amplitude of electrical impulses will have a longer lasting electro-analgesic effect compared to the periodic oscillation amplitude shown in Figure 2C.

Periodically changing the signal amplitude of the electrical signal in time, for example shaping the envelope of a sine wave, results in a visible positive effect on the speed of recovery of the affected edema(s). Figure 11 shows electrical pulses whose amplitudes vary in the time domain produced by the device. For example, Figure 11 represents the signal shown in Figure 1D. with amplitude varying in the time domain, but the signal waveforms shown in Figures 2C. and 3C. they can also be modified as described.

Although the theory of the effect of the described electrical signal waveform on edema is not well known, it is believed that each electrical impulse applied to intracorporeal tissues causes very small contractions and relaxations in the surrounding muscle tissue. It is believed that these very small muscle contractions and relaxations cause a certain amount of fluid drainage from the surrounding tissue, which creates the described positive effects on edema. It is also believed that by varying the amplitude of the waveforms of the device, there is a corresponding variation in the strength of contractions and relaxation of muscle tissue, which is the cause of an additional positive effect on edema by ensuring a more gradual drainage of fluids from the surrounding tissues.

Electrical signals are usually applied to the treated area of the body using two electrodes of low resistance, whose contact surfaces are placed on the patient's skin. It is preferable that the contact surfaces of the pair of electrodes are located on opposite sides of the area to be treated. It is desirable that the net amount of ion movement in such an arrangement is zero, since electrical impulses of opposite polarity are constantly alternating.

Brief description of the drawing

Reference is made to the drawings showing embodiments of the invention. However, the invention is not limited to the embodiments shown.

Figure 1.A. Display of the output electrical signal according to one possible embodiment of the invention

Figure 1.B. Display of the output electrical signal according to another possible embodiment of the invention

Figure 1.C. Display of the output electrical signal according to the third possible embodiment of the invention

Figure 1.D. Display of the output electrical signal according to the fourth possible embodiment of the invention

Figure 2.A. Display of the output electrical signal according to a further possible embodiment of the invention

Figure 2.B. Display of the output electrical signal according to another possible further embodiment of the invention

Figure 2.C. Display of the output electrical signal according to the third further possible embodiment of the invention

Figure 3. Illustration of adding aperiodic amplitude variance to electrical pulses using a white noise signal source to modulate the amplitude of the signal

Figure 4. Display of output electrical signals for three channels according to one embodiment of the invention

Figure 5. Display of output electrical signals for three channels according to another embodiment of the invention

Figure 6. Schematic representation of one embodiment of an organism treatment device including procedures such as electro-analgesia treatment and edema treatment

Figure 7. Schematic representation of another embodiment of an organism treatment device including procedures such as electro-analgesia treatment and edema treatment

Figure 8. Illustration of an organism treatment device including procedures such as electro-analgesia treatment and edema treatment in use with a single pair of electrodes

Figure 9. Illustration of an organism treatment device including procedures such as electro-analgesia treatment and edema treatment in use with three pairs of electrodes

Figure 10. Schematic representation of an organism treatment device including procedures such as electro-analgesia treatment and edema treatment with three pairs of electrodes

Figure 11. Display of the output electrical signal according to the next further possible embodiment of the invention

A detailed description of at least one way of realizing the invention

The present invention is essentially an improved organism treatment device including procedures such as electro-analgesia treatment and edema treatment 100. The device disclosed herein comprises at least one pair of electrodes, each electrode having a contact surface for contact with the organism. The contact surface can be mounted, placed or held next to the area of the organism to be treated. When using the device, the contact surfaces are positioned on opposite sides of the body area to be treated.

In the standard version, this device contains a current generator adjusted to give an electrical signal as an output to the positive and negative poles of the electrodes. The current generator can be any source that provides electrical energy such as a battery or a direct current source. A pair of electrodes is electrically connected to the poles so that, while they are in use, an electrical signal is transmitted to the body through the contact surfaces.

Furthermore, this device contains a processor with the purpose of controlling the output electrical signal. The processor is programmed to configure the output electrical signal settings.

In one embodiment, the output electrical signal that configures the processor is characterized by a period (T) from 1ms to 10s, whereby the electrical signal contains within one period (T) at least one positive and one negative peak value, that is, it has a duration of a positive peak value and a duration of a negative peak values, where the duration of the peak values is shorter than 9 µs. Improved effects of the application of this device are obtained when the duration of the peak values is shorter than 9 µs because when the peak values last shorter, such electrical signals have a more pronounced and longer electro-analgesic effect on the organism.

In one embodiment, the peak current strength is at least 45 mA, and the total power of the electrical signal is less than 75 mW. It was also discovered that there are somewhat more pronounced effects on edema. The explanation for this can be found in the reduced permeability of edema. A shorter peak duration also improves outcomes related to wound healing. The shorter duration of the peak value stimulates or replaces the body's own body signals.

It should be kept in mind that the output level of the electrical signal is negligible, almost equal to zero, for the greater part of the duration of the individual period. The duration of the electrical signal within one period close to zero (ie when the output level is negligible) will be denoted as tpau.

In one embodiment, the duration of the peak value is shorter than 6 µs. A peak duration shorter than 6µs gives better results than devices found in the prior art. Electric impulses shorter than 6 µs penetrate the skin of the organism and a possible explanation could be that such impulses are capable of breaking through already damaged cell walls. Furthermore, a peak value shorter than 6 µs can at least partially remove pathogens.

In another embodiment, the peak current is at least 65 mA, preferably at least 95 mA.

In some other designs, peak currents of up to 500 mA are possible. The peak current strength in the domain of 100 mA to 500 mA is preferably combined with the duration of the peak value between 100 ns and 3 µs. The best results were achieved with peak currents in the domain of 150 mA to 400 mA in combination with durations of peak values in the domain between 150 ns and 1 µs.

In a further embodiment, one peak value has an energy of at most 1.5 mJ, preferably at most 1 mJ. In the performance that combines peak voltage/current strength and peak energy, improved results of the analgesic effect were obtained. The power transmitted through the electrodes per pulse is a maximum of 50 mW, preferably a maximum of 25 mW. With a lower power level, the level of comfort for the body increases. Preferably, power in the range of 1 mW to 30 mW is combined with peak durations in the range of 100 ns to 3 µs.

A typical period duration (containing one positive peak and one negative) is between 1ms and 10s (0.1 – 1000Hz). It is preferable that the period is between 10ms and 1s.

The current generator can provide either direct current or alternating current. The peak values within an individual period are separated by at least the peak value separation time tpp, where the peak value separation time tpp is shorter than the peak value duration. It was found that the effect of electro-analgesia is most pronounced when the peak separation time is reduced. A shorter peak-to-peak interval results in a healthier cell because it provides a minimum voltage to the cell by improving the transport process between cells.

In one embodiment, the device disclosed here may include multiple pairs of electrodes, and each electrode has contact surfaces for contact with the organism. In this embodiment, contact with the area of the organism to be treated can be established in different locations. In fact, when in use the contact surfaces of the electrodes can be positioned/held/mounted around the area to be treated.

In one application, the electrical signals generated at each pair of electrodes may have a similar period, but are phase shifted. The phase shift results in the induced movement of ions within the organism. This leads to further improvement of the results of analgesic treatment.

In the next version, it is possible to use N pairs of electrodes. Using 3 pairs of electrodes has proven to be very good, as it allows positioning/mounting/holding the contact surfaces around the area to be treated set at approximately 2pi/N around that area.

In one embodiment, the phase shift is such that the peak value in the electrical signal in the electrodes of the first pair is at least 70% of its duration when the peak value in the electrical signal in the electrodes of the second pair begins. This additionally improves the induced movement of ions in the organism, if the contact surfaces of the first and some other pair of electrodes are positioned/held/mounted close to each other on the area to be treated.

In a further embodiment, the device presented here also contains a corresponding interface connected to the processor, wherein the interface contains an input device for adjusting the energy of the electrical signal, while the processor contains a limiter for limiting the increase in the energy of the electrical signal to a limit value. The interface allows the operator to configure the electrical signal. One of the parameters under the operator's control is the amount of energy in a particular peak value and/or the total delivered current. In order for a sudden increase in energy or current on the skin of an organism to induce pain, the rate of increase is limited to a certain threshold. The threshold can be accessed by the processor from ROM memory. Such an implementation is possible that the processor controls the electrical signal so that the energy/power increases by a maximum determined amount per second (= threshold implementation).

In a further embodiment, the human interface may contain an input device for adjusting the duration of the peak value (or the highest amplitude of the current) of the electrical signal, wherein the processor contains a converter that allows the energy of the peak value to remain basically equally independent of the adjustment of the duration of the peak value (or the highest amplitude of the current) . It has been found that sensation and sensation at an established level of comfort for an individual patient remains the same even when a significantly higher amplitude of current is applied if the duration of each individual peak value is shortened accordingly to keep the rate of energy absorption unchanged.

In another embodiment, at least one peak value of the electrical signal is modulated by the modulating signal. By adding additional modulation to the peak signal, further improved results were obtained. By adding a certain amplitude of oscillation to each electrical pulse, the level of random ion movements around the treated nerve is raised, causing more noise to be created to improve the masking of electrical nerve pain signals. The amplitude variance of each pulse can be periodic or aperiodic with a constant or variable amplitude level. The modulation signal can be a periodic signal. This allows a periodic signal to be added to the peak signal. The added periodic oscillation amplitudes result in a longer-lasting analgesic effect after the treatment.

In a further embodiment, the modulation signal is a signal with noise, preferably the noise is white noise, which is, for example, obtained from a white noise source. This design results in added randomness to ion movements achieved by using aperiodic amplitude variance of electrical pulses. Electrical pulses are modulated using a white noise source. It was found that the introduction of aperiodic amplitude of electrical impulse oscillations will cause a longer lasting electro-analgesic effect even compared to periodic amplitude of oscillations.

To enable modulation, the device disclosed herein further comprises at least one modulator. In the next embodiment, the device described here contains at least one, preferably at least two electronic switches controlled by a processor. Each of the electronic switches can enable the electrical signal to be switched on and off. The switch can be used to configure the duration of the peak value. A combination of two switches can be used to change the polarity and thus allow obtaining a positive and negative peak value. A MOSFET is used as an electronic switch.

In the next embodiment, the device contains at least one capacitor. The capacitor can collect a charge that will be output as a peak signal across the poles to the electrodes/contact surfaces.

The application of this device includes the distribution of an electrical signal through the contact surfaces of a pair of electrodes, where the contact surfaces are mounted opposite the area of the organism to be treated; the electrical signal is characterized by a period (T) from 1ms to 10s, whereby the electrical signal contains within one period at least one positive peak value and the next negative peak value, which has the duration of the positive peak value and the duration of the negative peak value, whereby the durations of the peak values are shorter than 9 µs and where the total electrical signal power is less than 75 mW.

The electrical signal is transmitted to the body through contact surfaces. The two contact surfaces are preferably located/are positioned/held on opposite sides of the area to be treated. In another application, it is possible to mount/position/hold at least three pairs of contact surfaces (electrodes) around the area to be treated. Phase-shifted electrical signals are delivered to pairs of contact surfaces, which makes it possible to induce the movement of ions in the treated area of the organism.

The performance of the device with two electrodes is shown in Figure 8.

The recommended method of application of the device is for the operator to place the contact surfaces (100,101) of the electrodes (13,14) on the area 20 that includes the part to be treated 21. A typical placement of the electrodes would be laterally on opposite sides of the treated nerve fiber or edema as shown in FIG. pictures 8 and 9.

Anterior and posterior upper chest placement, anterior neck placement, and transcranial placement should be avoided to prevent possible side effects or spasms in these vital areas. People who have pacemakers and similar artificial aids based on electricity should not be treated to avoid the risk of dysfunction of medical aids.

Good electrical contact between electrodes of low electrical resistance and the skin should be ensured by using a textile soaked in a saline solution of conductive gel.

Figure 8 shows the application of the device where the output 10 has two poles (102,103). A suitable high frequency electrical conductor 12 connects the poles (102,103) to the low electrical resistance electrodes 13 and 14. The electrodes 13 and 14 are preferably made of surgical steel to reduce the electrochemical action of the metal and the patient's skin and are between 30 and 50 mm in diameter, but are not limited to that material and diameter. The contact surfaces of the electrodes 13 and 14 are placed on the skin 19 at opposite positions around the treated part of the body and laterally from the nerve fiber 21, although other positions of the electrodes are possible, depending on the particular case to be treated with the device.

Any of the electrical signals shown in Figures 1A., 1B., 1C., 1D., 2C. and 3C. can be applied to electrodes 13 and 14, which causes movement of ions in the treated tissue, especially around the nerve fiber 21. The movement of ions induced by the described application of the output signal is mostly linear with a net movement close to zero, except for a certain amount of random chaotic movement caused by irregularities in the ion concentrations in the treated tissue 20.

According to a more preferred embodiment, the rotational movement of ions around the nerve fiber can be induced, which results in a greater number of ions around the treated nerve fiber under the influence of the device's electrical impulses, which makes it more efficient.

Figure 9 shows the device according to the invention which has 3 sets of poles (102,103,104,105,106,107) provided in three channels CH1, CH2, CH3. The channels deliver an electrical signal as shown in Figure 4.

The outputs 10 of the current/current generator are connected by high-frequency electrical conductors 12 to six electrodes of low resistance 13, 14, 15, 16, 17 and 18. The contact surfaces of the electrodes are equally placed on the skin 19, here radially, around the treated part of the body with considerable separation from 60°. Each pair of electrodes 13 and 14, 15 and 16, 17 and 18 is placed on opposite sides of the treated part of the body, and each pair is placed in such a way that the same output electrical cables 12 from all three identical outputs 10 are placed next to each other (102,104,106, respectively 103, 105, 107).

Output signals from three identical outputs 10 are synchronized in the manner shown in Figure 4 to produce rotational movement of ions in the treated tissue 20 around the nerve fiber 21.

Figure 4 shows the first channel CH1 showing a positive peak value. When more than 50% tp of this peak value passes, the next positive peak value is formed as an output on channel CH2. Preferably, the second peak value forms after 70% of the first peak value has passed. A third positive peak value on the CH3 channel forms after a similar period of time.

A negative peak value is formed as an electrical signal on channel CH1 while a positive peak value on channel CH3 lasts. The next negative peaks form afterwards at CH2 and CH3.

It is obvious that if N pairs of electrodes are used, N synchronized signals can be used with similar settings as in Figure 4.

The ion motion induced by the described application of the three synchronized output signals is mostly rotational with the net motion of the ion in the clockwise (CW) or counterclockwise (CCW) direction if the synchronization is performed in the manner shown in Figure 4. However, if the direction rotation changes periodically, then the net movement of ions is close to zero.

An embodiment of the device using the electrical signal design as shown in Figure 4 is shown in Figure 10.

The three outputs (1010, 1020, 1030), channels CH1, CH2, CH3 are controlled or monitored by the central processing unit 1 which is set to synchronize the three outputs in the manner shown in Figure 4. The user interface 2 is realized either in the form of an electronic indicator with by a suitable input device such as a keyboard or may be in the form of a graphical user interface on a personal computer connected by line 78 to the central processing unit 1 by means of a digital data link. The three synchronized output signals are then applied to the treated part of the patient 11 by the electrode arrangement as shown in Figure 9.

It must be noted that all previously described waveforms shown in Figures 1C., 1D., 2C., 3C. and 11. can combine in the previously described synchronization manner to induce rotational movement of extracellular ions in the treated tissue. An example of a complex waveform used by the device of the invention is shown in Figure 5. The complex waveforms shown in Figure 5 are the result of combining the three different types of signal waveforms shown in Figure 2C. The signals are synchronized in the manner shown in Figure 4, and their amplitude varies periodically in the manner shown in Figure 11. It was discovered that the signal waveforms shown in Figure 5 have the most pronounced electro-analgesic effect as well as the most pronounced positive effects on edema in the manner previously described in this invention.

After the electrodes are placed as in Figure 8 or 9, the operator starts the treatment and adjusts the pulse duration tp, pause duration tpp, frequency and amplitude of the output signal using the user interface 2. The frequency set by the operator is achieved by the central processing unit 1 which properly adjusts tpau and automatically calculates the necessary adjustments.

The central processing unit 1 is arranged to gradually configure the output of the electrical signal 10 to prevent the operator from unintentionally changing the output parameters suddenly. Processor 1 contains a limiter that limits the amount of changes. In one embodiment, the limiter contains a threshold value, for example "1 MJ in 10 seconds", which will effectively limit the energy increase to 1 MJ every 10 seconds, even if the operator enters a higher increase through the user interface.

In practice, the signal waveform adjusts the operator in such a way as to create mild sensations on the treated part of the body, but pleasant for the patient. Once the optimal parameters are determined, the measurement of the time duration of the treatment starts automatically and at the end of the time period set by the operator, the central processing unit 1 turns off the output 10.

Treatments usually last between 5 and 20 minutes, and the positive effects of the device are immediate and obvious, although sometimes several treatments are needed to achieve a long-term effect.

During the duration of the treatment, the central processing unit 1 continuously measures and calculates the percentage variation of the electrical parameters of the output 10. If any of the monitored values varies more than 5 to 10% from the value set by the operator, the central processing unit 1 immediately shuts down the device to ensure safety and patient comfort.

The central processing unit 1 also constantly calculates the output energy of the device and if it exceeds the pre-programmed absolute value, it immediately shuts down the output 10 to ensure the safety and comfort of the patient.

The central processing unit 1 also constantly checks its own reliability and if an error is detected, it immediately shuts down the output 10 to ensure the safety and comfort of the patient. When the described operating procedure of the innovative device was followed and the absolute limit of the energy absorption rate was not exceeded, no side effects and discomfort were ever recorded.

An example of the device according to this invention is shown schematically in Figure 6. The operation of the device is monitored and controlled by the digital central processing unit 1. In the event that any of the monitored parameters exceeds a pre-programmed value, the central processing unit 1 shuts down the device.

However, the operation of the device is not limited to digital control and can be achieved by any other method of electronic control. The central processing unit 1 used in the preferred embodiment of the device is a microcontroller or FPGA, but any suitable programmable digital electronic device can be used instead. Interaction with the operator is achieved by means of a user interface 2 which can be either in the form of an electronic indicator with a suitable input device such as a keyboard, touch screen, rotary digital encoder or in the form of a graphical user interface on a personal computer connected to the central processing unit 1 by means of a digital data link 77 ,78.

The device uses a low-voltage DC power supply 4 that includes a battery or a suitable isolated switching power supply adequately protected against electric shock. The output voltage (Upsu) and current (Ipsu) of the power supply 4 is usually between 12 and 24 V but is not limited to this value. The output values of the power supply 4 are constantly monitored by the central processing unit 1 via lines 71,72. The voltage regulator 5 is controlled by the central processing unit 1, which also constantly monitors, via lines 73,74, the output voltage (Ureg) of the voltage regulator 5 and the current (Ireg). The voltage regulator 5 uses a direct current (DC/DC) switching power supply topology due to its efficiency, compact size and the possibility of direct digital control by pulse width modulation (PWM) enabled by the central processing unit 1, but any other adequate voltage regulation topology can be used. . The supplied voltage is at least 50 V, preferably 100 V.

Processor 1 is connected via control lines 61,62,63,64 to voltage regulator 5, ascending flyback or push-pull converter 22, electronic switches 24,25.

The step-up converter 22 is powered via the voltage regulator 5, and its switching on is controlled by the central processing unit 1. The output voltage of the step-up converter 22 is regulated by means of the regulation of the output voltage of the voltage regulator 5 and by means of the regulation of the switching on of the step-up converter 22. Electrical isolation between the primary and secondary of the blocking converter transformer adds additional safety to the treated patient as it electrically isolates the primary part of the circuit and its power supply. The output capacitor 23 is charged by the output voltage of the upconverter and its voltage (Ucap) is continuously monitored by the central processing unit 1 via line 75 using an electrically isolated connection preferably optically coupled, but not limited to that method.

The amplitude of the current of the output signal between the output electrodes 3 is proportional to the voltage of the charged output capacitor 23. Regulation of the output current is therefore achieved by regulating the voltage to which the output capacitor 23 is charged. The capacity of the output capacitor 23 must have an adequately high value to ensure that as it discharges at a desired time such as tp shown in Figure 1, its voltage does not drop significantly to maintain the output current amplitude at the desired value, to produce the output signal waveforms shown, for example, in Figure 2. Output Capacitor Capacitance 23 it should also have a suitably low value to ensure adequate regulation of the output signal amplitude by the regulating output voltage of the voltage generator 5 and the switching regulation of the boost converter 22.

In this embodiment, the discharge of the output capacitor 23 and the change of the polarity of the output signal are realized by means of two electronic switches 24 and 25, each of which consists of two semiconductor switching elements such as MOSFETs, but any adequately fast switching element can also be used. The electronic switches 24 and 25 are controlled by the central processing unit 1 via optically isolated connections or by using a pulse signal transformer.

With proper control, an electrical signal can be obtained from processor 1 as shown in Figure 11 using the described setup.

The amplitude of the electric current of the electric pulses produced by the discharge of the output capacitor 23 through the electronic switches 24 and 25 is then measured in the current measuring circuit 26. The current measuring circuit 26 contains a microcontroller that converts the values measured on the series "shunt" resistance and sends them in digital form to the central processing unit. 1 via optically isolated connections. The alternating current measurement circuit uses a small current transformer to provide electrical isolation of the device output from the rest of the device.

If the output electrical pulses are divided into a series of shorter consecutive electrical pulses as shown in Figure 2B, the inductance of the electrical lines of electrode 3 will act as a choke, thus producing a final output signal that will exhibit a higher frequency of amplitude oscillation as shown in Figure 2C .

If the charging voltage of the output capacitor 23 is appropriately increased and decreased at periodic intervals, the amplitude of the waveform of the output electrical signal will form the periodic envelope shown in Figure 11. It should be noted that the security of the device is maintained by the central processing unit 1, which constantly monitors a series of electrical parameters of the device and in case that any measured value differs from the programmed value, the central processing unit immediately turns off the upconverter 22 and turns off the electronic switches 24 and 25.

Another embodiment of the electro-analgesia and edema treatment device according to the present invention is schematically illustrated in Figure 7. The operation of the device is monitored and controlled by the central processing unit 1. In the event that any of the monitored parameters exceeds a pre-programmed value, the central processing unit 1 shuts down the entire device. However, the operation of the device is not limited to digital control and can be achieved by any other method of electronic control. The central processing unit 1 used in the preferred embodiment of the device is a single microcontroller or FPGA, but any other suitable digital processing device can be used instead. Operator interaction is achieved using user interface 2.

The device is powered by direct current 4 of low voltage. The voltage regulator 5 is controlled by the central processing unit 1.

In this embodiment, the output of the current generator 5 is amplitude modulated by the modulator 8 (AM) controlled by the central processing unit 1, which is thus capable of regulating the modulation depth. The modulating signal is a white noise signal produced by the white noise source 9. The white noise source 9 has a bandwidth of 0 to 50 MHz and includes, but is not limited to, a white noise producing diode. The output voltage of voltage regulator 5 modulated by a white noise signal is shown in Figure 3B.

The modulated signal is transferred to the primary of the step-up transformer 7 by means of the H-bridge switch 6 controlled by the central processing unit 1. The H-bridge electronic switch 6 consists of four switching transistors, preferably MOSFETs, although bipolar junction transistors can also be used . The H-bridge switch 6 and the step-up transformer are arranged according to the push-pull converter topology, but the same topology can be realized with two switching transistors and a transformer with a split primary winding.

The core of the output transformer 7 is usually made of ferrite, but is not limited to that material. Although the core materials of the output transformer 7 will attenuate the white noise component of the input signal, the signal at the secondary of the output transformer 7 still contains a certain percentage of the original white noise component as shown in Figure 3C.

The central processing unit 1 constantly monitors, via lines 76, the input current Iin and the output current Iout of the output transformer 7 and accordingly adjusts the output voltage of the voltage regulator 5 in order to achieve the set values and keep them stable.

Electric pulses from the secondary of the output transformer 7, here poles 81, 82, are finally applied to the patient's body by means of two metal electrodes of low electrical resistance 3. Poles 81, 82 are the output element of the device according to the invention.

Figure 7 also shows control lines 68,69 and line 79 which supplies power to Iin processor 1.

In Figure 6, the current generator 85 is indicated as a combination of elements 4,5,22-26. Another embodiment is a current generator 86 that includes other elements, for example the elements illustrated in Figure 7.

It must be noted that the previously described device designs serve as an illustration of the device's functional characteristics. Numerous modifications and adaptations thereof will be readily apparent to those skilled in the art without departing from the spirit and content of this invention.

Claims (17)

1. Device for treating an organism including procedures such as electro-analgesia treatment and/or edema treatment (100), the device (100) comprises - at least one pair of electrodes, each of which has a contact surface for contact with the organism - a current generator adjusted to give an electrical signal as an output to the positive pole and the negative pole, whereby a pair of electrodes is connected to the poles, so that in use the electrical signal is delivered to the contact surfaces and is transmitted to the organism, - the processor (1) set to manage the electrical signal, wherein the electrical signal is characterized by a period (T) from 1ms to 10s, wherein the electrical signal contains within one period at least one positive and one negative peak value that has the duration of the positive peak value, i.e. the duration negative peak values, wherein the peak durations are less than 9 µs, the peak current is 45 mA, and the total electrical signal power is less than 75 mW. 2. Device (100) according to claim 1, characterized in that the duration of the peak value is shorter than 6 µs, preferably shorter than 3 µs. 3. Device (100) according to claim 1 or 2, characterized in that the peak value of the voltage is at least 50 V and the peak current is at least 65 mA, and the peak value has an energy of at most 1.5 mJ. 4. Device (100) according to claim 3, characterized in that the peak value of the voltage is at least 90 V and the peak current strength is at least 95 mA, and the peak value has an energy of at most 1 mJ. 5. Device (100) according to any of the preceding patent claims, characterized in that the peak values are separated by at least the peak value separation time tpp, wherein the peak value separation time tpp is shorter than the peak value duration. 6. Device (100) according to any of the preceding patent claims, characterized in that the device contains several pairs of electrodes (13,14,15,16,17,18), and each electrode has a contact surface for contact with the organism. 7. Device (100) according to claim 6, characterized in that the output electrical signals on each pair of electrodes are of similar periods and that the electrical signals of each pair of electrodes are phase-shifted. 8. Device (100) according to claim 7, characterized in that it contains three pairs of electrodes. 9. The device (100) according to any of the previous patent claims, characterized in that it contains a user interface (2) connected to a processor (1), wherein the user interface (2) contains an input device for adjusting the energy of the electrical signal, wherein the processor contains limiter for limiting the increase in electrical signal energy to a limit value. 10. The device (100) according to any preceding patent claim, characterized in that it contains a user interface connected to a processor, wherein the user interface contains an input device for adjusting the duration of the peak value or the highest amplitude of the electrical signal current, wherein the processor (1) contains a converter to allow the peak energy to remain essentially the same independent of adjusting the peak duration or peak current amplitude. 11. Device (100) according to any preceding patent claim, characterized in that at least one peak value of the electrical signal is modulated by means of a modulation signal. 12. Device (100) according to claim 11, characterized in that the modulation signal is a periodic signal. 13. Device (100) according to claim 11, characterized in that the modulation signal is a signal with noise. 14. Device (100) according to any one of patent claims 11-13, characterized in that it further contains at least one modulator (8). 15. The device (100) according to any preceding patent claim, characterized in that it further comprises at least one electronic switch (24,25) controlled by the processor (1). 16. Device (100) according to any preceding patent claim, further comprising at least one output capacitor (23). 17. Device (100) according to any preceding claim, further comprising at least one up-converter (22).