AU662598B2 - Local application microprocessor based nerve and muscle stimulator - Google Patents

Description

42830 HKS:PFB 662598 P/00/011 Regulation 3.2

AUSTRALIA

Patents Act 1990 COMPLETE SPECIFICATION FOR A STANDARD PATENT

ORIGINAL

4 4( rt( C C- _g Name of Applicant: ELECTRO SCIENCE TECHNOLOGIES, INC.

Actual Inventor: PAUL T.KOLEN Address for Service: COLLISON CO.,117 King William Street, Adelaide, S.A. 5000 Invention Title: LOCAL APPLICATION MICROPROCESSOR BASED NERVE AND MUSCLE STIMULATOR The following statement is a full description of this invention, including the best method of performing it known to us: I- S S- A- FIELD OF THE INVENTION This invention is directed to a TENS-type therapeutic device, in general, and to a microprocessor controlled TENS-type system, in particular.

BACKGROUND OF THE INVENTION The use of electrical energy for the control of pain is well known. Although the specific physiological explanations underlying electrically derived pain control are not fully understood, the effects are quite real and provide a non-drug, non-surgical and non-psychiatric method of pain control which can be applied to a wide variety of painful conditions.

15 Transcutaneous electroneural stimulation (TENS) is a proven and accepted means of providing relief from many tr, kinds of acute and chronic pain symptoms. It is an attractive alternative to pharmaceuticals since it has no addictive properties. In addition, there are no known side effects to properly applied TENS therapy.

Several theories have been developed to explain the \neurophysiological mechanisms through which TENS can affect pain perception. The earliest accepted explanation is the gate control theory, first postulated by Melzack and Wall I 25 in 1965 (Melzack, R. Wall P. "Pain mechanisms: a new t theory," Science, Vol. 150, pp. 971-979, 1965). This theory used data from animal experiments to predict that stimulation of afferent nerves could inhibit transmission from both noxious and non-not.ious inputs. However, subsequent research with commercially available stimulators has demonstrated that TENS efficacy cannot be explained by gate control theory alone (Schmidt R. "Presynaptic inhibition in the vertebrate central nervous system," Ercebn. Physicol., Vol. 63 pp. 20-86, 1971).

2 More recent studies (Eriksson, M. B. Sjolund, B.

H. and Nielzen, "Long term results of peripheral conditioning stimulation as an analgesic measure in chronic pain, Pain, Vol. 6, pp. 335-347, 1979) have shown that TENS efficacy can be greatly enhanced for some patients by supplementing new stimulation techniques when unsatisfactory results are obtained with conventional stimulation. One popular technique incorporates experience from Chinese electroacupuncture. The dis. overy that the effects of this technique, as well as those from acupuncture, can be reversed with an opioid antagonist, e.g. naloxone hydrochloride (Sjolund, B. H. and Eriksson, M. B. "The influence of naloxone on analgesia produced by peripheral conditioning stimulation, Brain Res., Vol.

173, pp. 295-301, 1979, and Mayer, D. Price, D. and Rafii, "Antagonism of acupuncture analgesia in man by the narcotic atagonic naloxone", Brain Res., Vol. 121, pp.

s e 368-372, 1977) suggested the possibility of an endogenous opiate system responsible for pain control.

Since 1975, several endogenous, morphine-like peptides have been isolated (Hughes, J. et al, "Identification of two related pentapeptides from the brain Swith potent opiate agonist activity", Nature, Vol. 258, p.

577, 1975), including endorphins which have been found in numerous locations within the central nervous system (Matsukura, S. et al, "The regional distribution of immunoreactive beta-endorphin in the monkey brain", Brain Res., Vol. 159, p. 228, 1978).

The above results have led some researchers 30 (Eriksson, M. B. Sjolund, B. and Nielzen, "Long term results of peripheral conditioning stimulation as an analgesic measure in chronic pain", Pain, Vol. 6, pp. 335- 347, 1979) to the conclusion that more than one neurophysiological mechanism is involved in modulating through transcutaneous stimulation. This theory is (atskua, e al "he eginalditriutin o *Inum EE

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B' i. r i r 4 4444 3 supported by clinical studies (Mannerheimer, J. S. and Lampe, G. "Clinical transcutaneous electrical nerve stimulation", F. A. Davis Company, Philadelphia, pp. 345-348, 1984) that demonstrate the different characteristics shown in Table 1 for conventional and acupuncture-like TENS.

TABLE 1 Characteristics of TENS Modes Characteristic Conventional Acupuncture- Simultaneous like bimodal Intensity low high combined Rate high low combined Relief Onset rapid slow rapid Relief Duration short long long Accommodation likely unlikely slight accommodation likely Naloxone no yes reduced effects Reversible Effects The listed properties for simultaneous bimodal stimulation combined stimulation modes) use different stimulation mechanisms and suggest that the effects are additive. The validity of this assumption has been demonstrated in case studies (Mannheimer, J. S. et al. above), but more comprehensive research is needed.

Researchers have found that relevant electrical signal characteristics which must be examined in attempting to treat a painful sensation include the signal waveform, pulse repetition frequency, pulse duration, pulse amplitude and pulse modulation characteristics.

4 SUMMARY OF THE INVENTION The invention is directed to the application of improved TENS system technology in which one preferred embodiment employs miniature electronic circuit components to provide a device that can be integrated into a variety of application-specific forms that will be operated at specific treatment sites on the human body. A TENS pulse technique has been developed which reduces the power and the peak voltage requirements at the treatment site. This reduces or eliminates the unpleasant burning of the skin under the electrodes typically experienced when using most currently available TENS units.

The invention in one preferred embodiment uses commercially available electronic components. Low-profile, surface-mount components can be used in all units integrated into hermetically sealed treatment packages associated with the invention. A rechargeable, dry electrolytic battery can be installed in the package to obtain at least eight hours of operation from a single charge. All 15 external control signals, including ON/OFF, are preferably keypad entered and ee.i put into effect by interaction with a single microprocessor central processing unit (CPU). The CPU i; preferably programmed with application-specific waveform generating routines. Most treatment locations require a custom porgram. Inputs from the user can be interfaced to the CPU where preprogrammed instructions are carried out.

I

As an optional feature to the basic unit, preprogrammed routines are stored in a memory, for example, an EEPROM, can be altered or replaced as required by interfacing a personal computer or other dedicated controller via an on-board serial interface. Eight tactile membrane switches can be accessed by the I 25 user to cause changes in the operation of the unit. The switches are configured as follows: Two switches to increase/decrease fixed intensity; Two switches to increase/decrease fixed modulation frequency; i One switch to active/de-activate modulation frequency dither; One switch to activate/de-active intensity dither; and iiA 5 Two switches to turn ON/OFF the power to the unit.

I Additional switches can be added to increase program features. Each operation of a switch will cause a single incremental change in the selected parameter. If the switch remains closed there will be no further changes in the parameters. This is a oreferred safety feature of the unit which prevents the application of a full power signal to the electrodes in the unlikely event a switch were to remain activated.

Alternatively, the invention also relates to the use of a unique pulse train generated from signals developed by a CPU. The high frequency carrier is selected to match the TENS output circuitry to the electrode/tissue load at the treatment site. It has been noted that low frequency pulse modulation of a high frequency carrier signal penetrates the surface of the skin more easily due to capacitive coupling than the direct application of the low frequency modulating frequency, per se. As a consequence, a lower amplitude pulse can produce the equivalent effect at the treatment site. Because the energy from the modulated pulse is not dissipated in the skin, the presence thereof has virtually no effect on the skin. This reduces or eliminates irritating and annoying sensations on the skin while effecting treatment, as desired. The inherent power efficiency of this technique results in a longer battery life as an added benefit.

In one preferred embodiment, an electronic package containing all components can be mounted within a sealed unit made of neoprene, Lycra Spandex, or other flexible material. The battery which powers the unit can be installed within the sealed unit and charged using an external charger. The TENS unit is not intended to be used when the charger is connected to the battery. The 25 electronic circuitry is, preferably, constructed on a flexible printed circuit board (PCB). This PCB can be shaped into a form that complies with the requirement for the site specific treatment device.

Thus, in one preferred embodiment, the device consists of the electronic package, electrodes and any appurtenances required to attach the unit to the treatment area. The overall unit is made so that it can be worn comfortably for an extended period during normal human activity.

wc c~ C C C C C C i ~~111- -6 BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram of a preferrcd embodiment of the stimulator of this invention, FIGS. 2A and 2B are logic flow charts that describe the functional sequencing of the invention, FIG. 3 is a graphic representation of the microprocessor generated driver waveforms produced by the invention, FIG. 4 illustrates a model of the output circuitry, FIG. 5 shows the electrical models of the stimulator waveform, t 10 FIG. 6 is a graphic representation of the electrode/tissue current/voltage relationship, FIGS. 7, 8 and 9 are graphic representations of the output waveforms associated with under-saturated, critically saturated and over-saturated transformer operation.

f, 15 DETAILED DESCRIPTION OF THE INVENTION Referring now to FIG. 1, there is shown a partially block, partially schematic j i diagram of a TENS unit 10 according to a preferred embodiment of the C C invention. The data processing functions of the invention are performed by a microcomputer or CPU 1 which is preferably ;i 7 a single integrated circuit data processing chip. In a preferred embodiment, the CPU 1 includes a memory 12. The memory 12 can take the form of an electrically erasable, programmable, read-only memory such as external EEPROM While not limited thereto, the CPU 1 is preferably a stand alone, high performance single-chip micro-controller fabricated in +5 volt advanced CMOS technology so as to provide low power ,onsuiuption along with high speed operation. In the preferred embodiment, CPU 1 is an 68HC11E9 device which is available from several manufacturers and supplies the hardware features, architectural enhancements and instructions that are necessary for this invention. External EEPROM 20 is used by the CPU 1 for storage of the waveform generation programs and interface/"house-keeping" routines required by CPU 1. In some instances, it is possible to use static random access memory (SRA" as the external memory.

All operations of the preferred embodiment of the invention are carried out through interaction with CPU 1.

20 As noted above, CPU 1 is preferably of the CMOS-type that is characterized by having an internal control processor unit (CPU), internal oscillator and timing circuits, 256 .t bytes of internal RAM, 64 Kbyte bus expansion control, five programmable I/O parallel ports for address, data bus and I- 25 I/O pins, two 16-bit timer event counters and a programmable serial port with a full duplex universal asynchronous receiver and transmitter (UART) and synchronous shifter. These components are not delineated i in detail herein.

30 The unit 10 is powered by a rechargeable nickelcadmium battery 2. Typically, this battery is of a sealed construction and can be encapsulated within a hermetic housing (not shown) of the stimulator package. An external i battery charger, which is not part of the invention itself, is used to "re-charge" the battery.

I!

-8 The battery charger is connected to the circuit in any suitable fashion such as, for example, via jack 24.

The jack 24 is connected to the battery 2 via diode 23.

Diode 23 is connected in series with battery 2 during the charge cycle and is used to prevent damage due to incorrect charging polarity. The charging current is controlled via feedback circuitry in the charging unit.

Battery 2, which can be composed of two standard rechargeable nickel-cadmium cells, provides 2.4 volts to a solid state power switch 14, which produces a regulated volt output. In particular, an RC circuit comprising resistor 46 and capacitor 42 is connected across the battery. The anode of battery 2 is connected to the source electrode of MOS switch 43. The gate electrode of MOS switch 43 is connected to the junction of resistor 46 and capacitor 42. The gate electrode is also connected to an output terminal 44 of CPU 1 (described infra). Switch 261 i (a break before make, momentary push button switch) is connected across capacitor 42. The drain electrode of MOS 20 switch 43 is connected to the center tap of electrode isolation transformer 40 and to the common terminal of inductor 16 and resistor 17. AC-DC converter 18 operates as a voltage booster and maintains the required 5 volt "signal level at the output thereof by using an internal 25 oscillator and solid state switch to switch inductor 16 in and out of the circuit. That is, when Vcc falls below the I preset 5 volt value, an error comparator in the converter 18 gates on a 45 kHz oscillator which toggles the internal N-channel MOSFET ON/OFF.

30 When MOS gate 43 is ON, the switch closures in converter 18 during alternate half cycles connect the input voltage from the battery 2 directly across the inductor 16.

This causes the inductor 16 to alternately charge from the input battery voltage and discharge at a higher voltage due to the collapse of the residual magnetic field at the 4 i 9 inductor 16. The voltage is discharged into filter capacitor 21. In order to maintain a constant voltage across capacitor 21 and load resistor 47, switching pulses are skipped in proportion to the number of switching cycles necesary to maintain the level of the output voltage at the preset level of 5 volts. One example of the converter 18 is a model MAX 631 manufactured by Maxim.

The other terminal of inductor 16 is connected to the input of DC-DC converter 18. The other terminal of resistor 17 is connected to ground via resistor 19. The common junction of resistors 17 and 19 is connected to another input of AC-DC converter 18.

Resistors 17 and 19 form a voltage divider which sets the threshold for activating low battery indicator signal (LBI) at converter 18. The LBI signal is sent to the CPU 1. When a low battery signal is received, the oC power MOS gate 42 is released by the I/O pin 44 via Isoftware command. This causes the power to be removed from the circuit resulting in total shutdown until the batteries 20 are recharged. This operation prevents the possibility of anomalous operation of the stimulator due to low battery voltage. The output of the converter 18 is about 5 volts regulated to stably operate the CPU 1 and the support circuitry of the stimulator.

Switch 26J (similar to switch 261) is connected P H between an LBO terminal on converter 18 and ground or other I. suitable reference voltage. Switch 26J provides an OFF control for the power switch.

The solid state power switch 14 controls the o 30 activation of the system. For example, when the system is to be turned switch 261 is momentarily closed, thereby discharging capacitor 42 uo ground. This drives the gate electrode of MOS switch 43 to ground, thus turning the MOS switch ON. When the MOS switch 43 is ON, voltage i is applied to the converter 18 which produces +5V and turns ii 1 ,r i.

-1 0 on the CPU 1. Once the CPU 1 is ON, the "initialize programl" drives the output pin low. With the output pin 44 low, the MOS switch 43 gate electrode is held low via resistor 45 even after switch 261 has been released.

Resistor 46 and capacitor 42 form an RC time constant long enough to prevent the MOS switch 43 gate electrode from being pulled to +2.4V via resistor 46 even if the switch 261 is released before the CPU 1 can hold the gate electrode low. The device is now actively held ON via the CPU 1.

Conversely, the power switch is turned "OFF" by momentarily closing switch 26J. Switch 26J is connected in parallel with the open drain output, the LBO of the converter 18. Resistor 47 pulls the LBO high unless a low battery level or switch 26J pulls the LBO to ground. If LBO is detected low by the CPU 1, output pin 44 is set high via software, pulling the gate of the MOS switch 43 to IThis causes the MOS switch 43 to turn OFF and remove the I battery voltage from the power supply 14. This turns OFF t 20 the entire system. Resistor 46 keeps the MOS switch 43 gate electrode at +2.4V and OFF even when the CPU 1 is t-kf.

The system can be restarted only by pressing switch 26J.

No power is consumed when the system is OFF because terminal 44 is a high impedance when the CPU 1 is OFF.

Capacitors 27A and 27B are ceramic bypass capacitors j which prevent transients from being conducted to other i parts of the stimulator circuitry. In particular, capacitor 27A filters high frequency transients from the input power source to the CPU 1. Capacitor 27B provides 30 the same function for lower frequencies that may be present S" on the power circuit due to switching transients from the converter 18 or interaction of the CPU 1 on the power circuit.

The CPU 1 is programmed to provide all the necessary functions for operator interface and output signal a I I -I I 1 '3 11 interfaces. Additionally, external communications with the controller are provided via serial communications link 8 that can be accessed for clinical and special application programming.

Typically, the user controller 20 of the TENS unit includes any suitable devices, such as tactile membrane switches, that can be located either inside the sealed package or remotely, as required for application specific packages.

All user interfaces and input/output functions are effected through the five parallel I/O ports and the serial port interface. In this embodiment, controller comprises ten switches, typically in the form of a single 2 x 5 tactile membrane switch keypad. The keypad is used to control the operation of the unit 10 by providing a means of adjusting parameters through interaction of the switches with the user. These switches are configured as follows: frtU 4 44 r 4 S 4...i 26A Increase Fixed Intensity 26C Increase Fixed Modulation Frequency 26B Decrease Fixed Intensity 26D Decrease Fixed Modulation Frequency C'f LC CC 4 4 44CC 26E Toggle ON/OFF Frequency 26F Toggle ON/OFF Dither Intensity Dither 26G Toggle ON/OFF Program 1 26H Toggle ON/OFF Dither Program 2 Dither 261 ON Switch 26J OFF Switch Frequency reference for oscillator 22 and associated timing circuits is provided by a piezoelectric crystal mounted external to CPU 10. Frequency control crystal together with capacitors 29A and 29B form the external circuitry for the precision oscillator 22 which provides a stable frequency source for the operation of the timing and i P/00/008 s.29(1) r 3.1(2) Mar 93 -12control functions of the CPU 1. The stable frequency source assures that frequency dependent functions, such as pulse width timing (PWT), will be consistent. The oscillator 22 functions as an integral part of the CPU 1.

Capacitors 29a and 29b are selected to assure stable frequency operation at the desired frequency.

Memory 12 in the form of electrically erasable programmable random memory (EEPROM) or static random access memory (SRAM) can be used as external memory for the CPU 1.

Internal EEPROM as on the 68HC11 is the preferred memory for the purpose of this invention since program information recorded in the memory is retained during power off conditions and can be altered as needed. On the other hand, external EEPROM allows a larger program to be stored at the expense of more external circuitry.

Bi-phase signals are generated at terminals 30A and of the CPU 1 and supplied to modulator switch 35. The up-down signal is supplied to U/D terminal 32 and digitally "controlled potentiometer 34. The level of the U/D signal 20 at the terminal 32 determines whether the potentiometer 34 will be increased or decreased. For example, high voltage level signals (+Vcc) at terminal 32 allow the potentiometer I 34 to be incremented for an increase in resistance value.

I Thus, the potentiometer 34 is incremented one step at each transition of the increase signal INC (at terminal 33) from a high to a low level signal, e.g. from +Vcc to ground.

Conversely, by changing signal U/D from high to low, e.g. from +Vcc to ground, the potentiometer 34 is S 'incremented to a lower resistance value by each high to low 30 transition of signal INC at terminal 33. The signal CS is supplied to a chip select pin of the potentiometer 34 to I enable the potentiometer 34. When the potentiometer 34 is i i enabled, it is operative to store the current position i setting in an internal non-volatile memory (NOVRAM), not shown, within the potentiometer 34. I L n: I LI 11 LIOOU.

I I :~-l~ll 13 Capacitors 37a and 37b form a filter to eliminate switching transiernis that may be induced on the +Vcc power circuit and that would be sent into the input of the modulator switch and power drivers.

The voltage at output terminal 38 (VW) is controlled by the position of the digitally programmed potentiometer 34 and is supplied to the modulator switch 35. Modulator switch 35 is a conventional CMOS transmission gate and provides a switching path which alternatively supplies first or second voltage levels to the gate electrodes of a set of power drivers 39A and 39B. More particularly, the switch 35 supplies a low (or ground) level signal to the power drivers 39A and 39B when the switch is electrically connected to the ground (or other reference) terminals.

Alternatively, the switch 35 supplies a different (usually high) level signal to the power drivers 39A and 39B when 'L the switch is electrically connected to the VW output 38 of potentiometer 34.

SThe position of switch 35 is controlled by the signals Q1 and Q2 from output lines 30A and 30B which are l produced by the CPU 1. The voltage signal from switch determines the amplitude and pulse width of the output signal supplied to the isolation transformer 40 by power drivers 39A and 39B. That is, battery 2 is connected to 25 supply a positive voltage to the center tap 42 of the i primary winding of transformer 40. The power drivers 39A and 39B are, typically, enhancement N-channel MOSFETS. The I (tc control voltages, Vgs, and the corresponding drain current, irt IId, of the power drivers 39A and 39B are controlled by the voltage VW at terminal 38 which is switched through the switch Amplitude controller 24, which includes digitally controlled potentiometer 34, is used to control the n amplitude of the signals produced by the CPU 1. In one embodiment, the controller 24 is a Xicor X9C503 which has *I 14 100 discrete, stepresistance values and provides a sufficiently high resolution for this application.

The modulator switch 35 is a CD4053 analog transmission gate 28. The CPU 1 supplies digital control signals to switch 35 on line DC. Signals from the amplitude controller 24 are thus switched through the transmission gate 11 in proper sequence and to the power drivers 39A and 39B and there used to drive the isolation transformer 40. The isolation (or matching) transformer operates to supply the push-pull waveform generated by the power drivers 39A and 39B to the electrodes 41A and 41B.

The transformer 40 also provides a step-up in the level of the pulse voltage being sent to the electrodes, if desired.

It should be noted that electrodes 41A and 41B can vary in size and shape for each application.

Electrodes 41A. and 41B are made from conducting rubber material and can be provided in appropriate size and shape for specific application configurations. These electrodes are connected to the output terminals of the t 20 secondary winding of transformer 40. Electrodes 41A and t c C 41B are adapted to be applied to the body of the user in i I: order to effect the proposed treatment.

Thus, in operation, the power switch 14 is turned ON (as described supra) to connect the battery 2 to the 25 circuit in order to provide the appropriate power. The switches 26A through 26J are selectively activated to provide control signals to the CPU 1 (as described infra).

The CPU 1 produces output signals which cause potentiometer 34 to increase or decrease incrementally. The potentiometer 34 supplies a selected voltage level to switch 35. The switch 35 passes signals therethrough as a i function of the Q1 and Q2 signals from CPU 1. The voltage i level passed by switch 35 is applied to the power drivers 39A and 39B to control the signals therethrough and thus through the primary winding of transformer 40. The tIt t*,

'CC

CC"r

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c 15 transformer 40 applies (via the secondary winding) the signals to the electrodes 41A and 41B. The electrodes provide the stimulation to the user to effect the desired treatment.

The user can control the treatment by selectively operating the individual switches 26A through 26H of controller 20. As the switches are operated, the input to CPU 1 is changed whereupon the outputs therefrom are changed, as well. As a result, the signals at the electrodes 41A and 41B can be selectively controlled.

Due to the push-pull nature of the transformer drivers 39A and 39B, the AC voltage and current waveforms applied to the tissue are perfectly symmetrical in time and amplitude. This is important, as waveforms that are net DC but not time symmetric will not result in net zero ion transfer. This is due to lighter ions carrying most of the current in the fast portion of the current pulse and light/heavy ions carrying the current in a slow pulse.

Figures 2A and 2B are flow charts which illustrate 20 various functions performed by the CPU 1 during the operation of the present invention. In particular, referring concurrently to Figures 2A and 2B, there is shown the operation of the TENS unit 10. When power is initially applied to the CPU 1 at step 50, certain values are entered automatically so that no waveform will be produced by the stimulator. The next steps involve selection and initialization of various hardware and software options to be used to define certain ports as input or output, initialize output logic states, clear all working internal 30 RAM bytes, define internal processor configurations and enable interrupts.

Thus, after the initialization of the processor at step 50, the program initiates the OFF cyqcle and, at steps 51 and 52, the driver ports Q1 and Q2 are,'set LOW. Ports Q1 and Q2 correspond to terminals 30A and 30B on CPU 1 of ii

I

r r C 'r I Iii 16 Figure 1. The low level signals at ports Ql and Q2 will inhibit any driver signals to the CMOS transmission gate electrodes by switch 35 during the OFF period.

Once the system is fully initialized, the program directs the system to steps 55 and 56, which set complementary ports Ql and Q2, HIGH and LOW, respectively.

This begins the ON duration (ONDUR) or stimulation generation subroutine during which a biphasic electrical stimulation is applied to the tissue via the step-up transformer 40 and electrodes 41A and 41B. The states of ports Ql1 and Q2 are continuously reversed at steps 57 and 58 in a complementary manner for the duration of the operation until ONDUR 0.

At step 59, DECREMENT ONDUR, the high duration counter is decremented. If the ONDUR counter has not reached zero, the program will jump back to step 55 and go through the subroutine comprising steps 55 through 59 until the ONDUR counter has reached 0.

1 When ONDUR 0 is detected in step 60, the system S i 20 jumps to step 54 and resets Q1 and Q2 low. Then it jumps I to the subroutine represented by step 61 and begins to S: sequentially read the values in the controller 20 as i supplied at input terminals 0 through 7 of CPU 1. Thus, the CPU 1 determines if any of the eight switches 26A S' 25 through 26B has been pressed.

For example, if key 0 (which corresponds to switch 26A) is closed (or actuated), step 62 of the program will cause the JUMP Flag to be asserted. As a result, the system initiates the subroutine for increasing the 30 intensity of the output signal at the electrodes 41A and 41B. In this subroutine, step 63 of the subroutine operates to check for keypress release. It should be noted that the "check for keypress release" function in each subroutine ,automatically puts ports Ql and Q2 in a low l state, ther'aby effectively removing the stimulation signals 17 until the key in question is released. Once released, the ports are reactivated and the program continues. If the key 0 is closed at this time, the system will go to step 64 and operate to increment the counter in potentiometer 34.

In carrying out this operation, the U/D terminal 32 of CPU 1 in Figure 1 is set high e. the signal U +Vcc) and supplied to the digitally controlled potentiometer 34. The system then checks (at step 65) for the maximum value at the output of the digital potentiometer 34. If the potentiometer is not at the maximum level as determined by a software counter, a predetermined number of pulses is supplied from the CPU 1 counter to the digitally controlled potentiometer 34 (at step 66) to increase the resistance thereof which effects an increase in amplitude of the output signal in accordance with the number of pulses.

Typically, in this embodiment, there are 50 discrete steps available to the user.

The CPU 1 then returns o the main program and, at step 67, samples port 1 of CPU 1 to detect whether key 1 (switch 25B) has been pressed. If key 1 is pressed, the system initiates the decrease intensity subroutine. In this subroutine, the system checks for key press release at step 68 and then, at step 69, operates to decrement the resistive potentiometer 34. This step sets U/D terminal 32 t4 25 to the low level, i.e. D ground. This low level signal is supplied to the digitally controlled potentiometer 34.

At step 70, the system checks for the minimum value at the output of the potentiometer 34 via the software counter.

If the system is not at the minimum value, step 71 of the subroutine causes a number of pulses to be supplied to digital potentiometer 34, which will decrement the rc potentiometer 34 and decrement the output signal intensity.

The system continues with the main program at step II 72 and checks to see if the "key 2 pressed condition exists. If key 2 is pressed, the program will initiate the

U¢

18increase fixed modulation frequency subroutine.

At step 73 of the subroutine, the system checks for keypress release. At step 74, the system operates to increment an array of values which are loaded into ONDUR to increase the fixed modulation frequency of the output signal. Typically, this is a "look-up table" routine which loads predetermined values into ONDUR to generate the designated modulation frequency such that a fixed number of pulses per second are generated. Typically, this value will range from 2 pulses per second to no pulses per second.

Once these steps are complete, the subroutine returns to the main program which, at step 75, determines if key 3 is pressed. If yes, the system operates the fixed modulation frequency decrease subroutine at steps 76 and 77. (This is similar to but the inverse of the frequency increase subroutine of steps 73 and 74. The program continues to step 78 to determine if key 1 :I I 4 has been pressed and, at step 79, determines if the key press has been released. If key 4 is pressed, the system ell, will toggle the frequency dither flag from ON to OFF or OFF c to ON, depending on the current state at step 80. At step 81, the intensity dither flag is reset to prevent both frequency dither and intensity dither from being active 25 simultaneously.

t t t The system is returned to the main program at step i 82 to determine if key 5 is pressed. When key 5 is pressed, the program will run the intensity dither toggle subroutine. In this case, the system checks for keypress 30 release (of key 5) at step 83 and toggles the intensity dither flag at step 84. At step 85, the maximum dither u intensity is set to the current user set intensity and the i frequency dither flag is reset. This prevents both intensity and frequency dither from bejLiu active simultaneously., 4 4, i 1 1 ,T 19 The subroutine then returns to the main program and checks to see if key 6 has been pressed at step 86. When key 6 is actuated, the program will execute a user program 1 subroutine. This subroutine operates to check for keypress release at step 87, resets both the frequency and intensity flags at step 88, and loads the variables from memory to execute user program 1 at step 89.

When key 7 is actuated (see step 90), the action is identical to the key 6 actuated subroutine except that the variables from memory are to execute a second program 2.

That is, the keypress release of key 7 is checked at step 91; resets both the frequency and intensity dither flags at step 92; and loads the program 2 operating variable from memory in step 93.

Next, the LBO state is tested in step 94. If LBO is low, the program is terminated by step After the "key check" steps have been completed (and I LBO is not equal to the system proceeds to the j frequency dither subroutine at step 96, which is shown in 20 Figure 2B. This subroutine begins by checking the ,frequency dither flag set condition at step 97. If the °S frequency dither flag is not set, the subroutine goes immediately to the amplitude modulation subroutine i described infra. If the flag is set, the subroutine checks i S 25 to see if Dither Direction DOWN at step 98. If yes, the I subroutine goes to step 99 and checks if ONDUR is at minimum array value. If yes, the system goes to step 100 i to set Dither Direction UP. If no, the subroutine decrements the ONDUR array reducing the frequency at step 101 3 However, if Dither Direction UP at step 98, the subroutine goes to step 102 to check if ONDUR is at maximum array value. If yes, the system goes to step 103 to set Dither Direction DOWN. If no, the subroutine increments the ONDUR array, increasing the frequency at step 104.

I L I r I C Ir I II

I

When the system enters the amplitude modulation subroutine noted above, it also checks to see if the intensity dither flag is set at step 105. If no, the subroutine will exit at terminal J (step 150) and return to the primary program as shown in Figure 2A.

If step 105 is yes, the subroutine will check to see if Dither Direction DOWN at step 106. If yes, the subroutine will check if intensity is at the minimum value at step 107. If yes, the system goes to step 108 to set Dither Direction UP and then returns to the main program at step 150 (see also Figure 2A).

On the other hand, if step 107 indicates that the intensity is not at the minimum, the subroutine decreases the intensity at step 109 and returns to the main program at step 150.

In similar fashion, if the condition Dither Direction UP "NO" indication) is detected at step 4 106, the subroutine goes to step 110 to check if the Sintensity is at the maximum level set by the user of the device. If yes, the system goes to step 111 to set Dither .c Direction UP. If no, the routine increases the intensity at step 112 and then returns to the main program at step 150.

As noted, terminal J (or step 150) is the start C 25 point for the main program to set port Ql LOW wherein the S sequence begins again. The main program and the several subroutines continue during operation of the stimulator until LBO 0 or the OFF button 26J is operated *As noted supra, the switches 26A and 26B are 30 complementary switches as are switches 26C and 26D. Thus, j normally only one of each of these "sets" of switches will be operated at any time. For example, the output signal will be "increasing" or "decreasing". Thus, the appropriate action will be to "increment" or "decrement"' the system. In like fashion, the "key pressed" detection i i 1 1 U n *1 21 ij steps are paired in sets. Consequently, it is considered typical that if "key 0 pressed" is detected, "key 1 pressed" will not be detected. Thus, alternate subroutines will be activated and the complementary subroutine will be skipped. For example, if the increment" subroutine is activated because key 0 is pressed, it is expected that the "decrement" subroutine will not be activated because key 1 is not pressed. Thus, the system will jump directly from step 67 to step 72. The inverse operation is, of course, equally applicable.

Referring now to Figure 3, there is shown a graphic representation of the output waveforms generated as the result of the program interaction in the ,PU 1 in Figure 1.

The carrier waveforms, A and A' in Figure 3 are bi-phase, complementary pulse signals 118 and 119 generated by a software subroutine within the CPU 1. Every time this subroutine is called, four cycles of the carrier frequency t are applied to ports Q1 and Q2 in a complementary fashion.

c! This carrier frequency (fc) is preset in software to a 20 specific predetermined frequency which is fixed, but load I t; dependent. That is, the frequency is largely determined by rthe size and placement of the electrodes 41A and 41B in FI Figure 1. Thus, as the electrode size and/or tissue varies, the load presented to the transformer secondary S 25 also varies. To allow maximum power transfer to the tissue C load, the carrier frequency is adjusted such that Z, ZL at that In a preferred embodiment, the carrier frequency is 1-2 KHz.

The modulation frequency subroutine of waveform 120 30 is user variable (typically from about 2 Hz to 100 Hz) and rl, is selected by keys 26C and 26D shown in Figure 1 and in l accordance with the operation of steps 72 and 75 shown in Figure 2A. The f, routine is "ANDED" with the fm routine in software. The pulse width of fm is fixed to 4f1 with the resulting duty cycle or ON/OFF being variable, 1 1 1 1

L

~J

i I~r- ill I i -22 The activation/de-activation of the frequency or intensity dither is controlled by keys 26E and 26F shown in Figure 1 and the program operation of steps 78 and 82 shown in Figure 2A. When the user presses key 26E or 26F (as detected at the steps 78 or 82), the dither function is either activated or de-activated. The duty cycle determines how many of the carrier pulses 121 are driven onto the electrodes during one fm period. This is an important parameter as it determines the average duration of the stimulating pulse and, together with the MOSFET gate voltage, determines the total energy transferred through the electrodes to the treatment site. In other words, WBI the modulation frequency signal 120 is ON, the waveforms A and A' pass through the gates 38A and 39B as waveforms B and respectively. These waveforms are shown as signals 121 and 122, respectively. Convr-sely, when the modulation frequency signal 120 is OFF, the waveforms A and A' are blocked and the signals B and B' remain at a prescribed r level, e.g. ground. The amplitude of the drive pulses S 20 signals 121 and 122) delivered to drivers 39A and 39B, respectively, is variable from Vmin (for example 2.1V) to Vmax (for example 4.75V) to thereby control the intensity of the stimulation. The amplitude of the signals 121 and 122 is, of course, controlled by the voltage level I S[ 25 of the signal VW supplied by the potentiometer 34 as shown in Figure 1. Thus, in this embodiment, fifty (50) discrete i steps are provided.

t It has been determined that the electrical load ii presented to the stimulator pulse is primarily capacitive. I This capacitive effect is primarily the result of the high l resistance exhibited by the surface of the skin. 'i 41 Referring now to Figure 4, there is shown a circuit model of this invention as affected by human skin. In particular, the MOSFET drivers 39B and 39B receive the 35 signals B and respectively, from the switch 35 as shown l 4 r 23 in Figure 1. The MOSFETS drive the opposite ends of the primary winding of the transformer 40. The primary winding is a grounded center tapped 20 winding. The opposite ends of the secondary winding (which is a 1:N ratio relative to the primary winding where N is greater than 1) is connected Sto the electrodes 41A and 41B, respectively. The electrodes are placed on the skin of the user. The intermediate body portion (or "tissue load") of the usar is schematically represented as the tissue load 400 between the electrodes. The tissue load 400 includes skin, muscle, nerve fibers and the like and is represented by the electrical analog comprising resistors Rs and Rt as well as capacitors Cs.

It is known that human skin exhibits a relatively high resistance to the flow of DC electrical current.

Conversely, the subcutaneous tissue layers forming the i muscles and nerve fibers of the body exhibit a relatively ai -low resistance to the flow of either DC or AC electrical current. Thus, in this system, the electrodes 41A and 41B C 29 appear as plates of a capacitor having a lossy interelectrode dielectric 400 which represents the tissue load.

i Isolation/step-up transformer 40 (see also Figure 1) is preferably electrically matched to the electrode/tissue E load at the F. in order to realize an efficient transfer of 25 electrical impulse energy to the inner tissue and nerve sites of the body. In the electrical model shown in Figure 4, Rs is the skin bilayer resistance, Cs is the skin bilayer capacitance and Rt is the extracellular tissue S ,..resistance. For typical body applications, Rt is i approximately 100 ohms, but the electrical resistance of the tissue is dominated by Rs, which is on the order of 10K i| ohms. Clearly, the values :of Rs and Cs are determined by the electrode area and interface characteristics with te skin.

Referring now to Figure 5 there is shown the 0 I 1 1 l 1 1 24 primary-referenced equivalent load model for the system shown in Figure 1. This model represents the operation of the transformer 40 in this invention. The secondary DC resistance Rsec, the tissue resistance Rt, and the electrode/tissue capacitance Cs are "reflected" to the primary side of the transformer by the appropriate use of the turns ratio N. Because of the relatively low values of Rs and Rt, as well as the relatively large turns ratio (N) of the step-up transformer, the respective transformed values will be small compared to the value of primary DC resistance Rp. Consequently, these transformed values can be neglected in the analysis. Similarly, the values of leakage inductance LL and stray capacitance CD are also small and are also neglected. These assumptions lead to the simplified primary load model wherein the components within the dashed outline 501 are effectively deleted from consideration. Thus, it can be easily seen that the model reduces to a simple RC network comprising the primary DC E S- resistance Rp and the reflected tissue capacitance N 2 C,/2.

c 20 This network is driven by a step voltage G of half period f/2, where f. is the carrier frequency. This reactive load determines the time it takes the primary to reach saturation. Thus, it determines, in large part, the total number of primary TURNS together with the range of 25 obtainable carrier frequencies.

It is known that nerve stimulation is effected by the flow of current through the extracellular tissue S resistance Rt, not by the voltage impressed across the 1 i 3 electrodes 41A and 41B. The maximum current flow in/out of the capacitor defined by the electrodes and, thus, through *Rt, is at the maximum rate of charge of the voltage across the capacitor. This condition is illustrated in Figure 6 together with timing relation to the microcontroller driver signals B and It can be seen from the diagram that the carrier frequency fe must be adjusted to allow maximum 1 1 1 I k;: '6- 25 i ~r i: a rr i i a r Icrt r~rr rrir rrrr irr~ Ir r I c rr ~rer r r rr r tr cr r I r r r rari r a r a r re a a r saturation of the transformer core prior to the complementary reversal of B and Thus, the maximum core saturation in transformer 40, coupled with the current reversal in the primary coil, creates a maximum rate of change in the secondary voltage Vsec and a corresponding maximum stimulation current Isec through the tissue load Rt. The selection of the optimum carrier frequency is highly dependent on the selected matching transformer and electrode geometry which controls Cs, as noted supra.

The secondary TURNS are determined to match the secondary impedance to the load impedance by an iterative process between the selection fe the number of primary TURNS and the TURNS ratio.

Referring now concurrently to Figures 7, 8 and 9, there are shown waveforms of under-saturated, critically saturated, and over-saturated operation of the matching transformer, respectively. In particular, Figure 7 illustrates the maximum secondary load current Ismax attainable from optimum core saturation. The optimum 20 saturation is the result of tuning F, to the OPTIMUM transformer/electrode/tissue load saturation period yielding maximum power transfer to the tissue load 400 for a given transformer configuration. Critical saturation operation is highly dependent on electrode/tissue 25 capacitance and therefore, requires f. to be tuned to each electrode geometry as described above. In this case, fc is selected to be 535 Hz.

Figures 8 and 9 represent the operation of the identical circuit for which operation is illustrated in 30 Figure 8 but with fc adjusted above (913 Hz) and below (468 Hz) the optimum value, respectively. It can be seen in Figure 8 that the peak and average secondary current is well below that obtained in Figure 7. In Figure 9 it is apparent that the transformer core became saturated with the primary current Ip limited by the DC series resistance i'" t

I'

l c-.

r I II

;LI

i 1II1I~- 1~ 1~- lil -26 and the same reduction in secondary current amplitude.

This invention develops a unique frequency and amplitude modulated pulse train. Because of the frequency modulation of the pulses, the stimulating signal can more easily penetrate the skin thus requiring a lower voltage to produce the same effect to the nerve and muscle tissue as most presently developed conventional stimulators. Also unique in this invention is the development of applicationspecific packages that can be worn and operated thereby permitting treatment during normal human activity.

Conventional stimulators now in use are not easily *adapted to this type of application and this invention offers a definite advantage gained from this type of application. A very real advantage is that a person can realize the benefits of TENS treatment while engaged in .etr lc normal day to day activity. The invention is developed from electronic components that are readily available from i several manufacturers. This assures that the invention can be manufactured and become useful.

Thus, this invention provides a TENS unit employing a unique output waveform. The unit can be worn by persons undergoing treatment during normal daily or sports related activities. The unique output waveform reduces the power i and voltage level requirements of the signal being applied I to the treatment area thus significantly reducing or •ini icnl eu igo eliminating the uncomfortable burning sensation normally associated with most conventional TENS applications. The unit can be packaged such that all power sources, electronics, user interface electrodes and application 30 devices (such as wraps or specialty garments) can be contained in a single composite form. This form is, typically, application-specific and designed for a particular treatment locations, back, neck, leg, knee, ankle, hip, and the like. All active circuitry and i power sources can be contained in a single hermetically I: I 27 sealed package designed to provide a maximum of safety and to facilitate ease of operation.

The above description shall not be construed as limiting the ways in which this invention may be practiced but shall be inclusive of many other variations that do not depart from the broad interest and intent of the invention.

Thus, there is shown and described a unique design and concept of a transcutaneous electric nerve stimulation (TENS) device. The particular configuration shown and described herein relates to electronic stimulators. While this description is directed to a particular embodiment, it is understood that those skilled in the art may conceive modifications and/or variations to the specific embodiments shown and described herein. Any such modifications or variations which fall within the purview of this description are intended to be included therein as well.

S' It is understood that the description herein is intended to S be illustrative only and is not intended to be limitative.

Rather, the scope of the invention described herein is limited only by the claims appended hereto.

C c H 1 i

Claims (2)

1. 9. The electrical stimulation device according to claim 1, further comprising a low battery detect circuit for indicating to the pulse generating means that the stimulation device is at low battery power. The electrical stimulation device according to claim 2, wherein the driver means comprises two FET switching transistors and the at least one electrode comprises two electrodes, wherein the switching transistors apply the pulse train alternately to the two electrodes.
2. 11. A method of applying a stimulation signal to living tissue comprising the steps of; generating a pulse train including a frequency and an amplitude component; applying the pulse train to an electrode positioned in contact with the living tissue; modifying the frequency and amplitude components of the pulse 1 5 train such that the impedance of the electrode is matched to the impedance of the tissue. Dated this 29th day of June 1995 ELECTRO SCIENCE TECHNOLOGIES, INC By their Patent Attorneys COLLISON CO C C I tC t C t C t c i t t i 1 ABSTRACT A transcutaneous electroneural stimulation (TENS) device employing microprocessor control of carrier pulse frequency, modulation pulse frequency, intensity, and frequency/amplitude modulation factors has been developed. The microprocessor monitors battery status and keypad- entered commands that select the various TENS modalities, and generates the driver signals to produce the output waveform. The microprocessor is programmed to calculate all stimulation parameters, which are stored in nonvolatile memory to provide concise and predictable programmed functions which can be updated as required. By selecting a desired program, the system may be programmed for either pain relief or the reduction of edema in the application area. The output pulse train employs a pulse modulation 60e0 scheme which is carrier frequency tuned for location- specific applications by matching the carrier frequency to the electrode/tissue load. By pulse modulating the high frequency carrier and matching the carrier frequency to the electrode/tissue load, more efficient energy transfer is realized, and the unpleasant burning sensation associated with most TENS stimulation units is virtually eliminated. t tt* &t(t It, (jI C CI I