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BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to medical devices and in particular a multi-pole
electrode catheter and method for endocardial mapping and ablation. A
single catheter is capable both of mapping the atrial and ventricular
heart chambers, as well as ablating foci or bypass tracts that cause
dysrhythmias.
2. Description of the Pior Art
In the treatment of cardiac dysrhythmias, nonsurgical procedures such as
management with drugs are favored. However, some dysrhythmias of the heart
are not treatable with drugs. In addition, some patients of advanced age
or illness may not tolerate invasive surgery to excise tachycardias which
cause dysrhythmias.
Endocardial mapping is a technique that typically involves percutaneously
introducing an electrode catheter into the patient. The electrode catheter
is passed through a blood vessel, the aorta and and thence into an
endocardial site such as the atrium or ventricle of the heart. A
tachycardia is induced and a continuous, simultaneous recording made with
a multichannel recorder while the electrode catheter is moved to different
endocardial positions. When a tachardial foci is located as indicated in
an electrocardiogram recording, it is marked by means of a fluoroscopic
image.
Under earlier techniques, the mapping catheter would be withdrawn and
replaced by an ablation catheter. The ablation catheter contained one or
more electrodes for delivering a controlled burst of energy, of the order
of 100 joules or so, to the foci. The foci would be -ablated and the
patient monitored for a period of time to ensure that there would be no
reoccurence of the dysrhythmia. This removal of the mapping catheter was
both time consuming as well as subject to inherent inaccuracies. This is
because the location of the tachardial foci could not always be precisely
relocated by using the fluoroscope.
As a result, catheters have been developed for the location and ablation of
such tachycardias that perform both the mapping and ablation functions
with the same catheter. One such mapping and ablation catheter is a
hexipolar catheter made by the United States Catheter and Instrument
Corporation. This prior art device has a series of six electrode rings in
alternating 2 and 5 mm distances along an elongated woven Dacron surface.
Bipolar electrograms are used to determine the site for ablation.
Problems with this and other prior art devices are manifest. First, the
area of mapping is fairly large and imprecise. That is, the foci can only
be found within about 10-12 cm.sup.2 and at best only about 2-3 cm of the
site.
Corollary to this is that the area ablated must be unduly large since the
site of the foci is only known to this precision. The prior art electrode
catheters also deliver the ablative charge over a wider than necessary
area. This causes tissue and cell damage beyond the foci.
SUMMARY OF THE INVENTION
The invention is directed to an endocardial electrode catheter and method
for performing both mapping and ablation functions in the same device. The
catheter is in the form of a hollow tube having a plurality of side
electrodes equally spaced around the distal end thereof. A further,
central electrode is fixed to the distal end on the catheter axis. A like
plurality of conductor wires pass through the hollow tube and are
connected to leads which may be attached to a multichannel EKG machine for
taking bipolar and unipolar electrograms. In an alternate embodiment, the
wires pass through longitudinal bores within the tube wall.
A cable is contained within the tube and is fixed at its distal end to the
central electrode. It is also connected to a lead which is, in turn,
connected to the EKG machine. The cable passes through and is affixed to a
hollow, elongated rod. The rod, in turn, passes through an end cap of a
main body. An actuator knob on the proximal end of the rod allows the
cable to be selectively retracted.
A plurality of slits intermediate the side electrodes allows the central
electrode to be retracted vis-a-vis the side electrodes as the limbs
intermediate and defined by the slits expand radially outwardly. The four
side electrodes lie in the same plane and equally spaced from adjacent
electrodes. The side electrodes are at the apexes of a square pattern with
the central electrode in the center of the square.
A conduit leading to a chamber formed within the main body allows
medicament to be conducted through the tube and out through the slits to
the endocardial site of the distal end of the catheter.
To accomplish the method of mapping, the leads are connected to a
multi-channel EKG machine. The distal end of the catheter is introduced
into an endocardial site and recordings are made. The catheter is moved to
different endocardial sites until a discontinuity shows on the EKG
reading. Before each move, the side electrodes are returned to their fully
retracted mode. They are moved to their fully expanded mode when a new
site is reached.
To accomplish ablation, the method further provides that electrical energy
is then discharged through some or all of the leads and out of the
respective electrodes. The electrical, radio frequency, or laser energy
ablates the tachycardial foci which was found through mapping. If
necessary, further ablation can be accomplished.
DESCRIPTION OF THE DRAWINGS
FIG. 1 is a front elevation view of a human heart in partial cross-section
illustrating the distal end of the inventive catheter touching an
endocardial surface, namely a ventricle wall;
FIG. 2 is a front elevation view of the catheter;
FIG. 3 is a partial cross-sectional elevational view of a portion of the
catheter of FIG. 2, partially in cross-section to show details thereof;
FIG. 4A is an isometric view of the distal end of the catheter in the fully
retracted mode;
FIG. 4B is a view of the same with the distal end of the catheter in the
fully expanded mode;
FIG. 4C is a partial cross-sectional view taken along lines 4 C--4 C in
FIG. 4A;
FIG. 5 is an enlarged partial cross-sectional view of an alternate
embodiment of the catheter shown in FIG. 4A; and
FIGS. 6A-6E are diagrams of EKG readings using the catheter.
DESCRIPTION OF THE PREFERRRED EMBODIMENT
As shown in FIG. 1, the endocardial catheter of the instant invention is
shown placed within a heart ventricle 12. As shown, the catheter is placed
within the left ventricle, although it could as easily be placed within
the right ventricle 14 or any other endocardial chambers or sites. For
purposes of orientation the left ventricle is shown divided into four
quadrants by dotted lines. These four quadrants are: right upper 2, right
lower 4, left upper 6, and left lower 8.
Turning to FIG. 2, there is shown the inventive catheter 10 having a distal
end 16 and a proximal end 18 at the opposite end thereof.
As shown in FIGS. 4A and 4B, the distal end 16 of the catheter is comprised
of a generally hollow flexible tube portion 20 of a diameter small enough
to be passed through the blood vessels and into the heart. As shown in
these figures and in FIG. 3, tube 20 has an inner bore 22 of a lesser
diameter than its outer diameter through which four electrically
conductive wires shown generally at 24 pass. A centrally disposed cable 26
also shares the inner bore 22 of tube 20 with the plurality of wires 24
for a purpose to be hereinafter described. Tube 20 may be made of a
flexible material such as plastic or Dacron. The distal end of tube 20 is
fitted within a larger elongated tube 28. Tube 28 serves as a transition
conduit between tube 20 and main body 30.
Main body 30 is made up of a series of components which form an interior
chamber 32. Main body 30 consists of a necked-down hollow, generally
frustoconical proximal end portion 34 and a generally cylindrical, hollow
distal end portion 36 which are fitted within a cylindrical middle portion
38. Portions 34 and 36 are fitted within cylindrical middle portion 38 so
as to leave a gap 40. This gap allows a side conduit 42 which is fixed to
middle portion 38 at a perpendicular angle to the axis defined by the
catheter to access the interior chamber 32 by way of an interior inlet
bore 44. A flexible plastic conduit 46 is fitted over side conduit 42 for
a purpose to be hereinafter described.
A cap 48 is threadedly fitted over the end 50 of distal end portion 36 by
means of threads 51 so as to close off chamber 32. The various parts of
main body 30 are conveniently made of plastic material.
Slidingly fitted within a centrally disposed hole 52 in end cap 48 is a
tubular metal rod 54. Cable 26 is fitted within a proximal end 56 of rod
54. The distal end 58 of rod 54 has fixed thereon an actuator knob 60
through which exits the end 62 of cable 26. Insulation 64 around cable end
62 is provided where cable 62 exits activator knob 60. Insulation 66 is
also provided where the plurality of wires 24 exit through a hole 68 in
the side of proximal end portion 34. A plastic potting compound 70 seals
the point of egress so that leakage out of chamber 32 is prevented.
Similarly, a potting compound 72 is placed on the distal end of actuator
knob 60 to seal insulation 64.
As shown in FIG. 2, the interior wires terminate in a plurality of
electrode leads 74 (in this case, four). The cable terminates in a fifth
electrode lead 76. A standard catheter fitting 78 on the end of conduit 46
permits connection with a medicament source (not shown). In this manner,
medicament may be transferred through conduit 46 and into chamber 32, as
best seen in FIG. 3.
As seen in FIG. 4A, the proximal end of catheter 16 is in its fully
retracted position or mode. Because the electrode material has a "set" or
"memory" it will normally return to this retracted position. In FIG. 4B,
the proximal end of the catheter 16 is in its fully extended position or
mode. Four electrodes 2, 3, 4 and 5 are mounted through and equally spaced
around tube 20. These are of relatively small diameter compared with the
centrally disposed electrode 1, which is fitted within the end 90 of
distal end 16. The electrodes themselves may be made conveniently of a
highly conductive material, such as gold or platinum. A plurality of
longitudinally directed slits 92 are cut through 20 from a point adjacent
to the end 90 thereof to a distance of approximately 1 millimeter away
from said distal end. The slits define and form intermediate limbs 91
therebetween. The outer diameter of the tube itself may conveniently be
about 2.34 millimeters.
In an example of operation, the catheter 10 is percutaneously introduced
into a patient and directed through a blood vessel (not shown) and into
the aorta 96, as best seen in FIG. 1. The distal end 16 is then positioned
against an endocardial wall of, for example, the left ventricle 12.
At this point, actuator knob 60 is manually retracted to the position 60'
as shown in FIG. 2. This causes the proximal end 16 of the catheter to be
expanded so that the electrodes are at a first distance from each other
equal to the tube outer diameter to its operative mode, as best shown in
FIG. 4B. In this position, the plurality of side eectrodes 2, 3, 4 and 5,
are positioned equidistant from central electrode 1 and at a second
distance which is greater than the first distance. The distance between
adjacent side electrodes is conveniently about one centimeter. In this
manner, an area of about one square centimeter of the endocardial wall is
covered with central electrode 1 at the center of the square centimeter.
As may be seen, side electrodes 2, 3, 4 and 5 are located on the upper
half of the limbs formed by slits 92 so that the electrodes are presented
in a proximal direction. Each side electrode is connected to a respective
one of the electrically conductive wires, which are in turn connected to a
respective one of the leads 74. The central electrode 1 is similarly
connected through cable 26 to electrode lead 76.
Because the tip of the catheter is radio-opaque, it will be visualized by
fluoroscopy. In this manner, it can be determined when the catheter tip is
in contact with the endocardium. Alternatively, or at the same time, the
electrocardiogram will indicate contact with the endocardium.
In an alternate embodiment shown in FIG. 5, the wires 24' pass thrmugh
longitudinal bores 94 corresponding with each side electrode. In this
manner, the wires are insulated from contact with each other and with
cable 26'.
The method of operation of the inventive device will now be described as
follows. The catheter is first used in mapping. Three surface
electrocardiograms I, AVF and V.sub.1, representing three planes (right to
left, superior-inferior, anterior-posterior) are continuously monitored
and the earliest deflection on any of these cardioelectrograms serves as a
reference point (FIG. 6A). The catheter has five electrodes, the central
electrode (number 1) and four electrodes, one on each limb (numbered
clockwise 2, 3, 4, 5) as aforementioned. These -five electrodes are
attached to a multichannel recorder and the following combinations are
recorded in bipolar and unipolar fashion. The bipolar electrode
combinations are 2-4, 3-5, 5-2; 2-3, 3-4, 4-5, 5-2; 1-2, 1-3, 1-4, 1-5;
and unipolar electrode combination are 1-L (limb), 2-L, 3-L, 4-L, 5-L
(FIGS. 6A-6E).
The first electrode in any lead configuration serves as a positive
electrode. The switching from one lead combination to another is
accomplished by a solid state computerized selector box (not shown). The
catheter is inserted through the leg artery (right femoral) and advanced
to the aortic arch and then to the left ventrical utilizing fluoroscopic
guidance. The ventricle or other heart chamber is arbitrarily divided into
four quadrants, rights-superior and inferior, and left 1-superior and
inferior quadrants.
The catheter is positioned in the right upper quadrant, limbs are deployed,
tachycardia induced, and recordings obtained (FIG. 6A). Catheter limbs are
retracted and the catheter moved to the lower quadrant (FIG. 6B), in this
way all four quadrants are mapped. The catheter is repositioned in the
quadrant that demonstrates earliest intracardiac ECG with reference to
earliest rapid detection on the surface ECG (FIG. 6B). Further
manipulations of the catheter in that quadrant are undertaken so that
intracardiac electrogram is very early as compared to the surface
electrocardiogram and the unipolar intracardiac electrogram with one or
more of its five electrodes documents earlier recording as compared with
the surface electrocardiogram. These orthogonal and unipolar intracardiac
electrograms from the catheter can assist in location of the site of
origin of ventricular tachycardia by earliest intracardiac electrogram
(with reference to surface electrocardiogram) and by amplitude and
direction of intracardiac electrogram (FIGS. 6A-6E).
With specific reference to FIG. 6A, the ECG trace is shown with the
catheter deployed in the right upper quadrant. A perpendicular dotted line
is drawn from the earliest surface ECG, which in this case is lead I.
As may be seen, the intracardiac electrogram appears later in time than the
surface ECG. As shown, the 2-4 trace is latest of the three traces (+100
milliseconds), 2-4, 3-5 and 5-2. The measurement point selected is the
point of first rapid deflection. The time in milliseconds from the
perpendicular to the first rapid deflection is indicated and juxtaposed
with each trace.
FIG. 6B shows the ECG trace with the catheter moved to the right lower
quadrant. Again, a perpendicular dotted line is drawn from the earliest
surface ECG which again proves to be lead I. In this example, all three
traces of the intracardiac electrogram are early. All are almost equally
early, which indicated that the catheter is close to the site of the
ventricular tachycardia.
FIG. 6C shows the ECG trace in the same right lower quadrant as FIG. 6B
above. However, the lead sequence has been changed as shown to record the
earliest activity. The catheter has not been moved from its position from
which the FIG. 6B traces were taken.
As shown, 5-2 lead trace is slightly earlier than the remaining 2-3, 3-4,
and 4-5 traces. This indicates that the site is closer to lead 5-2 than to
the others.
Turning to FIG. 6D, the catheter still has not been moved. Rather, readings
are taken between the center electrode 1, and each of the remaining
peripheral electrodes. Since 1-5 is earliest, this indicates that the site
is closest to electrode 5.
Finally, FIG. 6E is a unipolar (the previous graphs 6A through D were all
bipolar) intracardiac ECG trace, again at the same location. Again, lead
5-L is the earliest, confirming that the site closest to electrode 5 is
the earliest.
Further, construction of intracardiac vector loops form various coordinates
of the catheter can facilitate finer catheter motion to precisely localize
(within 1 sq. cm) the site of origin of ventricular tachycardia.
Once the earliest site is determined, ventricular tachycardia is terminated
by standard methods (overdrive pacing or cardioversion). The catheter is
held at the same site. A back plate providing a contact surface (not
shown) is conveniently positioned beneath the patient to complete the
circuit. The earliest site of origin is ablated by discharging energy
(Electrical, Radiofrequency or Laser) through the catheter. For example,
25 to 100 Joules of energy can be delivered through one or more of the
side electrodes. If only the central electrode is used, up to 300 Joules
of energy can be used. The energy could be delivered through all five
electrodes and back plate, central and back plate, four peripheral
electrodes and central electrode or between two limb electrodes.
Alternatively, the back plate can be eliminated and current passed into one
and out through one or more of the electrodes. An important feature of the
instant -invention is that the foci may be located with greater precision
and the burning or ablation also directed with similar precision. Also,
medicament may be passed through the open slits 92 and into the area of
mapping and ablation.
After ablation has been completed, a time period is allowed to pass, such
as for example ten minutes. The dysrhythmia is attempted to be
reintroduced. If it is not introduced, the catheter is collapsed and
removed from the patient. If dysrhythmia occurs, ablation is repeated, and
so on. The patient is then watched or monitored for twenty-four to
forty-eight hours to see if dysrhythmia occurs.
While the invention has been described in conjunction with a preferred
embodiment thereof, it will be understood that the description is intended
to illustrate and not limit the scope of the invention, which is to be
defined by the scope of the appended claims.
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