Patent Document

BACKGROUND 
     Bio-electric stimulation apparatus has been developed for applying current pulses to a patient through electrodes located on opposite sides of the head of the patient. The current pulses at selected frequencies are applied to cause reaction with the central nervous system of the patient. Such devices, referred to as transcranial electrostimulation (TCES) or cranial electrostimulators (CES) have been used for a variety of non-invasive procedures, such as producing analgesic effects, reducing or controlling migraine headaches, and other applications of treatment and electro-anesthesia. 
     Earliest prototypes of transcranial electrostimulation devices originated in Russia. These original designs, although successfully employed for several different treatment modalities, had a severe drawback with regard to the comfort of the wearer or patient. In some cases, these earlier cranial electrostimulation devices even subjected the wearer to pain. It has been discovered that the reason for the discomfort of these earlier designs was a result of the use of direct current as part of the overall operation of the devices. The direct current was used to break down or lower skin resistance to allow the treatment alternating current signals to penetrate the brain and nervous systems to cause the desired effect established by the placement of the electrodes on the head of the patient. 
     In these earlier types of machines, the wearer received a combination of direct current and alternating current electrical waveform packages through a series of electrodes affixed to the head with straps. Typically, two electrodes comprising a cathode or negative pole of the DC based circuit would be placed approximately three inches apart to the left and right of the center of the forehead. Two other electrodes, comprising the anode of positive pole of the DC based circuit, were placed on the rear of the skull on the post mandibular area behind and below each ear. 
     With this DC current based design, the wearer was required to place a thick pad between any electrode and the skin. Typically, the pad was comprised of several layers of unbleached and uncolored cotton flannel, or an equivalent product. For best results, the fabric pads were soaked with water to provide a conductive path between the electrodes and the skin of the wearer. Without the presence of the pads (which were only required because of the presence of the DC current), such devices could either burn the skin of the wearer, or cause relatively intense pain before a usable level of the treatment modality of the currents at the AC frequency could be reached. 
     Although various types of treatment were employed by such earlier transcranial electrostimulation devices, the devices typically needed to be employed for an average time of thirty minutes per treatment period. Without the presence of the relatively thick cumbersome pads, the DC based design was unusable. With the presence of the thick padding, the DC design was bearable to the wearer, but rarely provided the wearer with a pleasant experience. 
     Three Russian patents which utilize such devices for different treatment methods comprise Russian patent Nos. 1489719; 1507404; and 1522500. In all of these patents, a combination of direct current and rectangular impulse current, with a frequency of between 70 and 80 Hertz, was employed at current amperages which were increased from a relatively low level to a higher or maximum level over the course of each treatment session. 
     An additional and potentially harmful drawback of the DC based designs was that of iontophoresis. A characteristic of a DC circuit application of this type is that molecular sized parts of metal, toxins and other undesirable impurities can be caused to migrate in the direction of current flow through the skin and into the bloodstream of the wearer of such DC based CES devices. Consequently, care had to be taken to ensure that no substance was present other than water used to create good electrical contact with the pad to the skin of the wearer. Since practically all CES treatment modalities require repeated treatments, the potential for iontophoresis being a harmful factor was escalated. 
     Transcranial electrostimulation (CES or TCES) originally was used in the 1960&#39;s to induce sleep; These early devices typically used less than 1.5 mA at 100 Hz. The Liss U.S. Pat. No. 4,627,438 employed higher frequencies modulated by a lower frequency squarewave to produce recurring pulse bursts. The repetition frequency of the device of Liss is determined by the modulation frequency; but the pulse bursts are of a uniform amplitude within each repetition cycle. The device of the Liss patent is specifically directed to utilization in conjunction with the treatment of migraine headaches. The low frequency or modulating signal is asymmetrical, utilizing a 3:1 duty cycle, “on” three-fourths of the time and “off” one fourth of the recurring period. This results in bursts of the high frequency signal separated by the off time when no signal is applied, following the re-application of the bursts of the high frequency signal. Some patient discomfort may be present in such an “on/off” system operation over the period of time of application of the pulse during a treatment interval. 
     A number of other United States patents, all directed to dual frequency systems which utilize high frequency signals modulated by a low frequency modulation carrier, operating in the general nature of the device of the Liss U.S. Pat. No. 4,627,438, exist. Typical of these patents are the patents to Limoge U.S. Pat. No. 3,835,833; Nawracaj U.S. Pat. No. 4,071,033; Kastrubin U.S. Pat. No. 4,140,133; Morawetz U.S. Pat. No. 4,922,908 and Giordani U.S. Pat. No. 5,131,389. All of these patents employ a uniform amplitude high frequency signal, which is modulated at the lower frequency of the modulation carrier. 
     A variation on the systems of the patents discussed above is disclosed in the Haimovich U.S. Pat. No. 5,540,736. The device of this patent employs two different current generators for providing electrical currents delivered to two electrode pairs operating across different portions of the head of the patient. This allows independent control of the current generators to administer independent regulated electrical current across each of the pairs to adjust for different impedances caused by the physiological and anatomical differences between different sides of a patient&#39;s mid brain portion, the quality of the conducting medium, and other factors. In all other respects, the system disclosed in this patent is similar to the operation of the system disclosed in the Liss patent discussed above. 
     Russian patent publication No. 2139111 is directed to a method for treating narcomania, which is a treatment also used in others of the CES patents described above for alcohol and narcotic addiction. In this patent, transcranial electrical stimulation is accomplished by means of packets of current with a duration of four milliseconds, at a modulation frequency of 100 Hz. Within each of the packets, the high frequency signals have a uniform frequency and current amplitude. 
     It is desirable to provide a transcranial electrostimulation apparatus and method which overcomes the disadvantages of the prior art, and which has increased effectiveness and increased user comfort. 
     SUMMARY OF THE INVENTION 
     It is an object of this invention to provide an improved transcranial electrostimulation apparatus and method. 
     It is an additional object of this invention to provide an improved transcranial electrostimulation apparatus and method which does not employ direct current components. 
     It is another object of this invention to provide an improved transcranial electrostimulation apparatus and method employing only alternating current components. 
     It is a further object of this invention to provide an improved transcranial electrostimulation apparatus and method utilizing packets or groups of high frequency pulses which vary amplitude within each of the packets in a uniform manner and in which the packets are repeated at a lower modulation frequency for application to electrodes for effecting transcranial electrostimulation. 
     In accordance with a preferred embodiment of the invention, a transcranial electrostimulation apparatus includes a first generator of bipolar pulses at a first predetermined frequency. A source of modulating control signals at a second frequency, which is less than the first predetermined frequency, is employed in conjunction with an amplitude control circuit receiving the pulses of the first predetermined frequency to produce bipolar pulses at the first predetermined frequency, which vary in amplitude in an asymmetrical pattern at the frequency of the modulating control signals. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWING 
         FIG. 1  is a diagrammatic drawing illustrating the overall principles of operation of the system in accordance with a preferred embodiment of the invention; 
         FIG. 2  is a waveform of a typical signal pattern of a preferred embodiment of the invention; and 
         FIG. 3  is a block diagram of a system for producing the signals shown in FIG.  2 . 
     
    
    
     DETAILED DESCRIPTION 
     Reference now should be made to the drawings which illustrate a preferred embodiment of the invention and its operation.  FIG. 1  is a diagrammatic representation of the salient operating features of circuitry implementations which produce a unique triple waveform asymmetry useful for various transcranial electrostimulation applications. The unique waveform which is described in detail in conjunction with  FIG. 2  produces little to no discomfort to the user of the device. 
     As illustrated in  FIG. 1 , the basic high frequency current signals are produced by a high frequency generator  10 , which may employ a frequency control  12  and a pulse duration control  14  to establish the basic frequency and to provide the desired asymmetry between the positive and negative portions of each of the pulses produced by the generator  10 . Typically, the generator  10  may include a crystal oscillator operating at 1,000 to 1,200 kHz, which then is divided down to the desired operating frequency of the alternating current pulses applied to the transcranial stimulation electrodes. Typically, the division ratio may be a 1:4 ratio to produce signals which then are modulated by a low frequency generator  16 . 
     As illustrated in the diagrammatic representation of  FIG. 1 , the output of the low frequency generator  16  may be established by means of a conventional frequency control  18 , a pulse duration control  20 , and a modulation depth control  22  to produce a composite modulated output signal at  24 , which comprises the pulses from the output of the high frequency generator  10  modulated by the low frequency generator  16 . The output  24  then is provided with an amplitude control  26  to establish the amplitude of the pulse train supplied through the system to a power amplifier  28 . The current at the power amplifier  28  may be varied in accordance with the treatment modality to be used by the system; and this current is measured by an ammeter  34 . The power amplifier  28  then supplies appropriate transcranial alternating current pulses to a pair, or multiple pairs, of electrode outputs, illustrated as a single pair  30  and  32  in FIG.  1 . 
     The operation of a preferred embodiment of the invention, for producing a waveform having triple asymmetry in order to produce effective transcranial electrostimulation, now should be considered in conjunction with the waveform of FIG.  2  and the block diagram of the system shown in FIG.  3 . The block diagram of the system shown in  FIG. 3  is typical of a manner of implementation of the various circuit functions required to produce the waveform of  FIG. 2 ; but other arrangements for producing the signal waveform also may be utilized. 
     In  FIG. 3 , a crystal oscillator  50  is employed to provide the basic alternating current operating signals utilized for both the high frequency pulses and the modulating pulses illustrated in  FIG. 1  as being produced by the high frequency generator  10  and the low frequency generator  16 . Typically, the oscillator  50  may have an operating frequency in the order of 1,000 kHz to 1,200 kHz (although other frequencies may be used). The output of this oscillator is supplied to a divider  52 , which may comprise multiple division stages, to produce the lower modulating frequency (illustrated in  FIG. 1  as being generated by the low frequency generator  16 ). The output signals from the oscillator  50  also are supplied through a divider  54  to produce the operating signal waveform shown as the squarewave signal in the waveform of  FIG. 2 , after being shaped by a pulse shaper  56 , to achieve the generally squarewave configuration of FIG.  2 . In the example given, these pulses occur at an alternating current rate of 100 KHz; although they could be at higher or lower frequencies in accordance with particular applications of the system. 
     The pulses from the output of the divider  54  also are supplied to a counter  60 , which may be of any suitable type such as a cascade counter or a ring counter, for producing outputs on leads  64  and  66  utilized in controlling the amplitude of the pulses from the pulse shaper  56 . The counter  60  is reset by the output of the divider  52 , applied over the lead  62 , to reset the counter for each cycle of operation of the divider  52 . In the present example, the output of the divider  52  (comprising the low frequency modulation control signal) is selected to be 77.5 Hz, since this repetition frequency has been found to be highly effective in conjunction with transcranial electrostimulation devices. Repetitive frequencies which are in the range of 70 Hz to 85 Hz have been found to be effective, but a frequency of 77.5 Hz has been empirically ascertained as a general ideal operating frequency for producing the maximum efficacy of the system. 
     The modulating or reset frequency, applied over the lead  62 , could as well be supplied by a second independent crystal oscillator, operating at a lower initial frequency than the oscillator  50 , if desired. If two different signal sources are employed, synchronization between the two should be effected to cause the various pulse transitions of the signals to be correlated with one another in order to produce the signal waveform of FIG.  2 . The system shown in  FIG. 3 , however, is one effective way of accomplishing this. 
     Assume, for the present example, that the counter  60  has been reset to its initial or “zero” count. The system then operates to supply output pulses at the high frequency of the divided down signal from the divider  54  to the counter input, which advances one count for each of the applied pulses. In the waveform shown in  FIG. 2 , the initial pulses (the first four in  FIG. 2 ) cause the counter outputs on  64  and  66  to be such that, as these outputs are applied to the amplitude control  68 , a maximum amplitude (which may be adjusted if desired) is produced. This is illustrated in the left-hand portion of the waveform signal of FIG.  2 . When pulse No.  4  in the group or packet is applied, a signal is obtained from one or both of the outputs  64  and  66  of the counter  60  and applied to the amplitude control circuit  68  to switch it to a lower amplitude, as illustrated for the right-hand portion of the signal shown in FIG.  2 . 
     This causes the output of the amplitude control circuit  68  as applied to a regulator amplifier  58 , to produce the signal waveforms in the asymmetrical pattern shown in  FIG. 2 , wherein the left-hand one-fourth ( 42 ) of each of the signal bursts is at a high amplitude; and the right-hand portion ( 44 ) comprising the remainder of the pulses is at a lower amplitude. The ratio is such that one-fourth (the initial amplitude) is at the high amplitude range, and that the remainder three-fourths is at the low amplitude range. This is the first level of asymmetry of the applied signals. 
     The regulator amplifier  58  also operates on the squarewave shaped pulses from the pulse shaper  56  to cause a second asymmetry in the positive and negative going aspects of the signal. As shown in  FIG. 2 , the negative going amplitude is one-fourth of the total excursion of the signal; and the positive going portion is three-fourths of the total excursion. This is true of both the maximum amplitude pulse  42  burst at the beginning of each of the burst groups or packets, and the lower amplitude portion  44  at the end of each of the burst groups or packets. 
     Finally, the third asymmetry is produced within the thirteen milisecond squarewave burst envelope illustrated as  40  in FIG.  2 . This is the result of the operation of the divider signal on the lead  62  comprising the reset operation for the counter  60 . 
     The composite asymmetrical signal illustrated in  FIG. 2  then is provided by the output of the regular amplifier  58  to a power amplifier  70 . The amplification may be adjusted to change the amount of current applied by the system (while maintaining the relative waveform shapes and patterns shown in  FIG. 2 ) in accordance with the treatment modality to be utilized by users of the system. The ammeter  74  is employed to measure the magnitude of the current supplied by the system. It may be a simple analog ammeter, or it may be a digital ammeter providing separate readings of the maximum amplitude and minimum amplitude portions of the signal which is shown in FIG.  2 . 
     The output of the amplifier  70  may be applied through a polarity switch  72  which allows the polarity of the signals applied to the spaced electrodes to be reversed, if desired. The polarity switch  72  supplies the signals across a pair of spaced output electrodes  76  and  78  which may in the form of pairs of split anodes and split cathodes, or which may be a single “anode” and “cathode” pair. Since no direct current components are present, the electrode paths connected to the outputs  76  and  78  are not really anodes and cathodes; but, depending upon the treatment which is being effected, it may be desirable to apply the positive going portions of the pulses to one or the other of these electrodes and the negative going portions to the other to achieve specific results. 
     It should be noted that in the system which is shown and described, there-are no direct current components. It also should be noted that although the system essentially is illustrating 70 kHz to 120 kHz tone bursts in each of the burst envelopes  40  shown in  FIG. 2 , other frequencies could be employed. As noted, the 77.5 Hz waveform, derived through the timing cycle, is used to complete each burst envelope including first pulses of a relatively high amplitude, followed by a series of pulses of a relatively low amplitude, in accordance with the signal pattern shown in FIG.  2 . The frequency of pulse comprising the asymmetrical tone burst is approximately 1150 to 1450 times the repetition frequency of the burst envelopes. 
     In the system which is disclosed, an individual squarewave pulse of 0.01 Ms is utilized with 0.0075 Ms in the negative portion of the pulse and 0.0025 Ms in the positive portion of each of the pulses. The general asymmetrical waveform which is described above in conjunction with  FIG. 2  has been found to be effective when it is centered around three-to-one ratios throughout the system operation. These ratios of course may be varied, in accordance with corresponding variations of other ratios of the system; but it has been found that the asymmetrical relationship which is disclosed replaces the formerly necessary, but unpleasant, DC portion of the operating protocol of earlier systems. 
     The DC current employed in some of the prior art devices was designed to provide a path penetrating the natural capacitive resistance of human skin. The DC current reduced the resistance to approximately 300 to 400 Ohms. The cost, however, was a high level of discomfort for the user of the device. It has been found that the utilization of the unique asymmetrical signal produced by the system shown in FIG.  3  and illustrated in the waveform of  FIG. 2  effectively lowers the capacitive resistance of the epidermal layer to something on the order of 100 Ohms. Since less resistance is presented to the integrated 77.5 Hz modulating frequency, lower current levels are capable of achieving the same desired result which previously required much higher current levels. The lower current levels translate into a greater level of comfort for the patient or user of the device. 
     The foregoing description of the preferred embodiment of the invention is to be considered as illustrative and not as limiting. Various changes and modifications will occur to those skilled in the art for performing substantially the same function, in substantially the same way, to achieve substantially the same result without departing from the true scope of the invention as defined in the appended claims.

Technology Category: 1