"Defibrillation Electrode"
BACKGROUND OF THE INVENTION
This invention relates to an electrode and a method for stimulating tissue in medical applications, and more particularly to an implantable cardiac defibrillation electrode together with associated electronics and a method for performing cardiac defibrillation.
Electrodes implanted in the body for electrical stimulation are well known. More specifically, electrodes implanted on or about the heart have been used to reverse (i.e., defibrillate or cardiovert) certain life-threatening cardiac arrhythmias, by applying electrical energy to the heart via these electrodes to return the heart to normal sinus rhythm. The amount of energy delivered to the heart during defibrillation (or cardioversion) depends on the placement of the electrodes on or about the heart and the ability of the electrodes to distribute the energy uniformly through the heart.
Prior devices for efficiently delivering defibrillation waveforms from electrodes to heart tissue also are known. See for example, commonly assigned U.S. Patent No. 4,768,512. In this prior device, a truncated exponential defibrillation pulse is chopped into a plurality of consecutive pulse segments and delivered to the heart via an electrode pair. Such high frequency waveforms compensate for the various frequency-dependent impedances throughout the heart tissue to distribute energy more effectively.
The present invention is based upon the recognition that the high energy delivered to a fibrillating heart during defibrillation causes an ionic current to develop at the electrpdes. The conversion from an electric current to an ionic current produces gas at the electrode-tissue interface which acts as an insulator between the electrode and the tissue to which the defibrillating energy is being delivered. As a result, the amount of electrical energy actually delivered to the tissue from the electrode is reduced, and therefore, some of the defibrillating electric field developed between the electrodes never effectively reaches the heart. Accordingly, there is a need to increase the ability of defibrillation electrodes to deliver energy to a fibrillating heart.
By increasing the efficiency of the transfer of energy from the electrodes to the heart, the amount of energy required at the input of the electrodes can be reduced. As a result, the size of the unit containing the defibrillation/cardioversion circuitry can be reduced, or the life of the unit can be correspondingly increased.
SUMMARY OF THE INVENTION
It is a primary object of this invention to meet the above requirements by providing a defibrillation electrode, a discharge circuit and a pulse discharge technique which reduces the concentration of gas produced by electrolysis at the electrode- tissue interface, thus increasing the efficiency of the energy
transfer between implanted electrodes and the heart tissue receiving a defibrillating pulse.
It is a further object of this invention to increase the amount of energy transferred from the defibrillation electrode to the heart, and thus lower the required input energy to the electrode.
It is yet a further object of this invention to provide a defibrillation electrode and technique which reduces the required input energy to the electrodes and therefore either reduces the size or increases the life of the implanted unit containing the defibrillation electronic circuitry.
It is a further object of the present invention to provide a defibrillation electrode and technique for altering the shock vector about the heart for involving new muscle masses of the heart in the defibrillation episode.
In one embodiment, the defibrillation electrode discharge system of the present invention comprises an electrode having a plurality of separate, discrete conductive surfaces, each of which receives assigned pulses or time samples of a defibrillating waveform. The pulses are taken in succession until the waveform is exhausted, thus creating a "gatling" discharge. Time intervals are provided between successive pulses on any given segment to allow for the natural decay of the gas generated by electrolysis at the electrode-tissue interface. Therefore, the amount of gas
1 present at the electrode-tissue interface is minimized. The interface impedance is thereby lowered, thus increasing the amount of energy delivered from the electrode to the tissue.
BRIEF DESCRIPTION OF THE DRAWINGS
Figure la is a pictorial representation of the voltage- time relationship of a defibrillation pulse.
Figure lb is a pictorial representation showing the relationship between time and the concentration of gas generated by ionic current resulting from the defibrillation pulse shown in Figure la.
Figure 2 is a perspective view of a defibrillation electrode having plural electrically conductive surfaces insulated from each other, in accordance with one embodiment of the present invention.
Figure 3 is a cross-sectional view taken through line 3- 3 of Figure 2.
Figure 4 is a schematic block diagram of the electronic circuit for performing the gatling discharge technique in accordance with the present invention.
Figure 5a is a plot of a single defibrillation pulse partitioned into discrete pulse segments in accordance with the teachings of the present invention.
Figure 5b is a plot of the concentration of gas generated by electrolysis during the defibrillation pulse shown in Figure 5a.
if Figure 6 illustrates a defibrillation electrode having an array of conductive surfaces connected so as to define two segmented discharge surfaces on the electrode.
Figure 7 shows the voltage-time relationship of a segmented pulsing technique applied to the electrode illustrated in Figure 6.
Figure 8 is a cross-sectional view showing a defibrillation electrode of another embodiment, in unassembled form, having stacked electrically conductive mesh screens.
Figure 9 is a plan view of a defibrillation electrode having separate alternating conductive wires wound around a catheter for use with the defibrillating pulsing technique illustrated in Figure 5a.
Figure 10 is a schematic diagram illustrating the gatling discharge technique used in a multiple lead arrangement.
DETAILED DESCRIPTION OF THE DRAWINGS
Referring first to Figure la, a defibrillation pulse 10 is schematically shown having an amplitude A and a pulse width T. (Although the pulse 10 is depicted as a constant amplitude pulse, such a shape is for illustrative purposes only; the pulse 10 may be, for example an exponentially decaying, a bi-phasic, etc., waveform) . Due to the high energy contained within the defibrillating pulse 10, ionic currents are generated at the electrode-tissue interfaces which cause the formation of gas between the defibrillation electrodes and the adjacent tissue. An
illustrative plot of the gas formed due to the discharge of defibrillation pulse 10 is shown in Figure lb. As illustrated, the gas concentration increases exponentially during the discharge of the high energy defibrillation pulse. At the termination of the pulse, time T, the gas concentration decays exponentially to zero. It is known that the concentration of gas between the electrode and the adjacent tissue acts as an insulator which lowers the efficiency with which energy from a defibrillation electrode is delivered to the heart.
Referring now to Figures 2 and 3, a defibrillation electrode 18 is shown in accordance with one embodiment of the present invention. Electrode 18 comprises an active discharge surface region 15 comprised of discrete electrically conductive segments 20, 22, 24, and 26 in the form of spaced concentric rings. Each conductive segment is electrically isolated from the other conductive segment by insulator 28. Insulator 28 also isolates the conductive surfaces at their peripheral outer edges as well as their back surfaces.
The electrically conductive segments 20, 22, 24, and 26 are made, for example, of platinum iridium screen. Insulator 28 consists of silicon rubber sheets reinforced with woven dacron. The sheets, with such configuration, are laminated about the conductive segments to electrically isolate and support the conductive segments.
The conductive segments 20, 22, 24, and 26 are electrically connected to an implanted defibrillator/cardioverter unit 25 via insulated lead 27 of silicon rubber. (Only a single electrode 18 is shown; at least two electrodes are p aced on or about the heart, as is well known in the art.) The lead 27 contains conductors 17, 19, 21, and 23, which connect conductive segments 20, 22, 24, and 26, respectively, to unit 25. The conductors 17, 19, 21, and 23 are, for example, Drawn Brased Strands (DBS) of silver and stainless steel. These conductors are electrically insulated and connect only their respective conductive segment to the defibrillator/cardioverter unit 25.
Referring to Figure 4, the discharge circuitry 29 of the defibrillator 25 is schematically illustrated. The discharge circuitry 29 comprises a timing/sequence generator 31 for controlling the discharge of capacitor 33 via electronic switches 35a-d and electronic polarity switches 37a-d. The capacitor 33 is charged by a charging circuit 39. The output terminals, labeled A, B, C, and D, are connected to the discrete electrode segments of electrode 18 via conductors 17, 19, 21, and 23.
The circuit 29 divides the defibrillation voltage shock stored by capacitor 33 into a series of pulses so that each pulse may be directed to or inhibited from any one or a combination of preselected electrode segments. The timing/sequence generator triggers the switches 35a-d to convey a predetermined portion of the voltage shock to the corresponding electrode segment. In addition, the polarity of the conveyed voltage shock portion can
9 be altered by triggering the appropriate one of polarity switches 37a-d. While not shown, an arrhythmia detector is typically included within the pulse generator 25.
In operation, electrode 18 is implanted on or about the heart in conjunction with at least one other opposing electrode of the same or different construction. Connection to the pulse generator 25 is made, so that, for example, conductive segment 20 receives pulse segment A, conductive segment 22 receives pulse segment B, conductive segment 24 receives pulse segment C, and conductive segment 26 receives pulse segment D. This gatling discharge continues sequentially until the entire envelope, or pulse block 30 of the discharge pulse has reached the electrodes. The duty cycle, or pulse duration, however, may vary throughout the sequence allowing programmability for specific waveforms by storing data for controlling the timing/sequence generator 31. Further, as illustrated in phantom at C, any pulse segment can be reversed in polarity.
Moreover, by introducing a duty cycle, the amount of energy consumption is reduced. Referring to Figure 5A, during the off periods between pulse segments, no energy is expended. As such, the height of the leading edge of a preceding pulse segment equals the height of the trailing edge of a subsequent pulse segment. Consequently, by lowering the duty cycle of pulsed shocks, the trailing edge voltage increases as well as the amount of energy remaining in the capacitor 33. This may allow for either
a reduction in capacitor size, or a lowering of the leading edge voltages. Either approach reduces energy consumption without degrading efficiency.
Four conductive surface segments have been shown for illustrative purposes. However, more or less surface segments can be utilized to define the electrode, without departing from the spirit of the invention. The number of conductors of lead 27 and the number of defibrillator/cardioverter terminals would also change accordingly.
By having each conductive segment with its own conductor, all or only a portion of the conductive segments can be activated with the needs of the electrode. Further, by having only a portion of the segments activated at one time, the spatial distribution of the defibrillation energy can be optimized.
As a result of this σat inσ discharge technique, the formation of gas at the electrode-tissue interface is reduced as shown by plot 40 in Figure 5b. Because the formation of gas is a product of the charge delivered by a pulse of high energy applied to the electrode, the reduction of time that this high energy pulse is present results both in a reduction in the amount of gas produced, and in the decay, or absorption, of the gas already produced.
For example, as seen in Figures 2, 5a, and 5b, the first conductive surface to receive energy is segment 20 (receiving pulse segment 32) . During the presence of pulse segment A, gas will begin to form at the electrode-tissue interface of the entire
electrode 18 as shown by curve portion 14'. However, at the termination of pulse segment A, the gas concentration begins to decay exponentially as described above in conjunction with Figure lb as shown in Figure 5b by curve portion 16' . - It is important to note that the formation of gas due to pulse segment A occurs primarily around the periphery of conductive segment 20. Further, the concentration of gas surrounding any particular conductive segment is illustrated by curve 14". The gas concentration around a particular segment reaches a peak then decays until that particular segment receives another voltage shock. The accumulated gas formed from each electrode surface, and hence at the overall electrode, does not reach as high a level as would have been reached by a single pulse discharge at a single conductive surface. As noted above, the overall effect of applying the pulsing technique shown in Figure 5a to defibrillation electrode 18 results in a reduction in the accumulation of gas produced at the electrode-tissue interface. In this regard, it should be noted that the representation of Figure 5b is an average, in that each of the four conductive segments receives one discharge pulse segment out of every four pulse segments delivered. Therefore, by reducing the presence of insulating gas, the efficiency with which energy is delivered from electrode 18 to the heart tissue is increased overall. The total amount of gas formed is a function of the amount of charge delivered. By reducing gas accumulation, the amount of surface masking is reduced and the interface impedance is lowered.
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The gatling discharge technique described above effectively defibrillates the heart by altering the shock vector applied to the heart. By changing the orientation of the shock vector, new muscle masses are involved. However, the voltage gradients of the same muscle mass is not affected by the changing shock vector.
Figures 6 and 7 illustrate another embodiment of the present invention. Defibrillation electrode 42 is provided with an active discharge surface region 43 comprised of conductive segments 44 and 46, formed of conductive mesh screens, of generally equal size and shape. The conductive segments 44 and 46 are insulated from one another by insulator 28, and are electrically connected together in two groups. Typically, electrode 42 has a cross section similar to that of electrode 18 shown in Figure 3, with insulator 28 covering the entire rear and perimeter surfaces of the electrode. Conductors 47 and 49 connect together conductive segments 44 and 46, respectively. Conductors .51 and 53 are provided to connect the two groups of conductive segments to the defibrillator unit 25, similar to the connections illustrated in Figure 2.
In operation, a pulse block 50, as shown in Figure 7, similar to pulse block 30 of Figure 5a is applied by defibrillator unit 25 to electrode 42. Two groups of conductive segments, labeled "1" and "2" for illustrative purposes and corresponding to conductive surfaces 44 and 46, are positioned throughout electrode 42 and receive pulses 52 and 54, respectively. As a result, the
lλ overall effect of reducing the amount of gas formed at the electrode-tissue interface is achieved as illustrated in Figure 5b and previously described. The number of distinct conductive segments, in a group, as well as the number of groups of conductive surfaces on electrode 42, can be increased for effecting specific discharge shapes and distributions.
Figure .8 illustrates still another embodiment of the present invention comprising defibrillation electrode 56 having a similar construction to electrode 18 shown in Figures l and 2 but differing in a few details. Specifically, defibrillation electrode 56 is provided with stacked electrically conductive mesh screens 58 and 60. Insulation 62 provides a non-conductive backing for non-active surfaces of .electrode 56. A mask 64 is provided with apertures 65 exposing the electrically conductive screens 58 and 60 on the active discharge surface 63 of electrode 56. A dacron mesh or other porous insulator 69 is provided between screens 58 and 60. Conductors 66 and 67 connect screens 58 and 60 to the defibrillator unit 25. Mask 64 and insulation 62 are laminated together, enclosing screens 58 and 60.
In use, electrode 56 receives a pulse block similar to that illustrated in Figure 7. Screens 58 and 60 are energized alternately, so that as described above, the gas generated about the heart surface is reduced, lowering the required energy for effecting defibrillation or cardioversion. Furthermore, while only two conductive screens are shown, additional screens can be used, each receiving an assigned discrete pulse segment.
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Figure 9 illustrates a defibrillation electrode of yet another embodiment of this invention. Electrode 72 comprises a cardiac catheter 74 having four separate electrically conductive discharge wires or coils 76, 78, 80, and 82 wound around and extending the length of distal portion 70 of the catheter. Conductors 75, 77, 79, and 81 connect conductive wires 76, 78,80 and 82, respectively, to the defibrillator unit 25. Alternatively, the discharge wires may extend the length of the catheter and connect to the defibrillator unit without the need of conductors 75, 77, 79, and 81. The conductive wires are wound so that spaces are provided between adjacent wires along the length of the catheter 74. Insulation 83 is provided along the surface of distal portion 70 to insulate the conductive discharge wires from one another.
In use, electrode 72 is implanted in the vena cava region of the heart, and is energized by a pulse block such as that illustrated in Figure 5a at 30, and achieves the advantages described above by the gatling discharge technique.
The specific types of waveform, or waveform shape, is not a necessary feature of the present invention. It is envisioned that any type of waveform or pulse block can be employed, just so long as it is segmented to effect the gatling discharge described hereinabove. Specifically, a pulse block of any shape can be time- sampled to derive discrete pulse segments to be delivered to discrete conductive segments on an electrode. Furthermore, as illustrated in Figure 10, the gatling discharge technique of the
present invention can be applied to a multiple lead arrangement. Specifically, separate electrodes can be implanted about the heart to receive discrete pulse segments for changing the shock vector applied to the heart. One configuration may include a catheter 90 having a distal electrode 92 and implanted within the right ventricle. In addition, two subcutaneous patch electrodes 94 and 96 are provided, one being implanted over the sternum and one being implanted under the left arm.
In this configuration, a defibrillation pulse is segmented into three discrete segments and conveyed to the electrodes 92, 94, and 96 to effect gatling discharge between the electrodes. Typically, in this multi-electrode arrangement, the polarity of the pulse segments is kept the same to avoid affecting the voltage gradients of any particular muscle mass.
It should be understood that the above description is intended by way of example only and is not intended to limit the present invention in any way except as set forth in the following claims.