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Claims  |
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What is claimed is:
1. A flexible, planar patch electrode for cardiac defibrillation
comprising:
a planar wire mesh having a contact side and an opposite insulation side,
the wire mesh having a base region with a plurality of protrusions
extending therefrom in a generally longitudinal direction, and with each
adjacent pair of protrusions being separated by a generally longitudinally
extending slot extending outward from the base region;
an electrically insulated lead having a conductor conductively secured to
the base region of the patch and centrally located thereon relative to a
lateral direction perpendicular to the longitudinal direction;
a flexible layer of insulation secured to the insulation side of the wire
mesh and covering any noninsulated portion of the wire mesh; and
an electrically insulated radiopaque marker disposed about the periphery of
the wire mesh.
2. A patch electrode according to claim 1, wherein the wire mesh comprises
titanium wire.
3. A patch electrode according to claim 1, wherein the contact side of the
wire mesh has a surface area in the range of 2 to 4 square inches.
4. A patch electrode according to claim 1, wherein the contact side of the
wire mesh has a surface area of substantially 3 square inches.
5. A patch electrode according to claim 1, wherein the wire mesh has a
periphery and the layer of insulation has a periphery that extends beyond
the periphery of the wire mesh to assure complete electrical isolation of
the noncontact side of the wire mesh.
6. A patch electrode according to claim 1, wherein the lead is secured to
the wire mesh in an orientation extending generally parallel to but on the
opposite direction of the protrusions.
7. A patch electrode according to claim 1, wherein each protrusion has a
rectangular shape.
8. A patch electrode according to claim 1, wherein there are exactly two
protrusions extending from the base region.
9. A patch electrode according to claim 1, wherein there are exactly three
protrusions extending from the base region.
10. The patch electrode according to claim 1, wherein the planar wire mesh
further comprises a network of spaced-apart electrically conductive wire
strands extending from the base region longitudinally along the
protrusions, the spaced-apart electric wire strands oriented to provide a
uniform electric field longitudinally along the mesh.
11. A flexible, planar patch electrode for cardiac defibrillation
comprising:
a planar foraminous screen having a periphery shaped to define a base
region and a plurality of protrusions extending in a longitudinal
direction from the base region with each pair of adjacent protrusions
being separated by a longitudinally extending slot, the screen having a
contact side for making physical electrically conductive contact with a
heart and an opposite noncontact side;
an insulated lead having a conductor with a noninsulated end secured to the
base region of the screen midway between the sides thereof to provide good
electrical communication with the screen at a location that minimizes
electrical resistance in a path through the screen from the conductor to
the laterally outermost protrusions, the conductor extending from the
secured end in a direction opposite the protrusions;
a layer of insulation secured to the noncontact side of the screen and
covering the noninsulated end of the lead conductor, the layer of
insulation having a periphery similar in shape to the periphery of the
screen but extending beyond he periphery of the screen to assure
electrical isolation on the noncontact side of the screen; and
an electrically insulated radiopaque marker threaded about the periphery of
the planar foraminous screen.
12. A flexible, planar patch electrode according to claim 11, wherein the
contact side of the screen has a surface area in the range of 2-4 square
inches.
13. A flexible, planar patch electrode according to claim 12, wherein the
foraminous screen comprises titanium wire.
14. A flexible, planar patch electrode according to claim 12, wherein the
foraminous screen comprises carbon.
15. A flexible, planar patch electrode according to claim 12, wherein the
surface of the patch is covered with a non-toxic biocompatible material
selected from the group consisting of metal carbide, metal nitride and
metal oxide.
16. A flexible, planar patch electrode according to claim 12, wherein the
layer of insulation comprises a Dacron reinforced Silastic sheet.
17. The flexible, planar patch electrode according to claim 11, wherein the
planar patch electrode further comprises a network of spaced-apart
electrically conductive wire strands extending from the base region
longitudinally along the protrusions, the spaced-apart electric wire
strands oriented to provide a uniform electric field longitudinally along
the patch.
18. A single flexible, planar cardiac defibrillation electrode providing
substantial area contact with a heart surface without significantly
interfering with heart operation and without interfering with features on
the surface of the heart comprising:
a wire mesh planar screen having a contact size and a noncontact side, an
insulated lead a electrically connected at one end to the noncontact side
of the planar screen and a layer of insulation covering the noncontact
side of the planar screen and any noninsulated portion of the one end of
the lead, the electrode having a base region connected to the lead and a
plurality of protrusions each separated from an adjacent protrusion by an
intermediate slot extending in a longitudinal direction from the base
region to enable the base region and protrusions to be shaped into
conformal contact with a surface of a heart while allowing any surface
feature to be located within an intermediate slot to obtain a substantial
surface contact area in the range of 2 to 4 square inches while avoiding
significant interference with any motion of the contacted heart surface or
features on the contacted heart surface; the wire mesh planar screen
having a plurality of spaced-apart orthogonally oriented mesh strands
wherein one of the strands are oriented in a direction parallel to the
longitudinal direction of the protrusions so that other ones of the
strands are oriented in a direction orthogonal to the longitudinal
direction for generating a substantially uniform electric field in the
protrusions essentially parallel to the longitudinal direction.
19. A single flexible, planar patch electrode for cardiac defibrillation
comprising:
a planar wire mesh having a contact side and an opposite insulation side,
the wire mesh having a base region with a plurality of protrusions
extending therefrom in a generally longitudinal direction, and with each
adjacent pair of protrusions being separated by a generally longitudinally
extending slot extending outward from the base region, the planar wire
mesh having a plurality of spaced-apart orthogonally oriented mesh strands
wherein ones of the strands are oriented in a direction parallel to the
longitudinal direction of the protrusions so that other ones of the
strands are oriented in a direction orthogonal to the longitudinal
direction for generating a substantially uniform electric field in the
protrusions essentially parallel to the longitudinal direction;
an electrically insulated lead having a conductor conductively secured to
the base region of the patch and centrally located thereon relative to a
lateral direction perpendicular to the longitudinal direction; and
a flexible layer of insulation secured to the insulation side of the wire
mesh and covering any in an insulated portion of the wire mesh. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
Heart fibrillation is a high frequency arrhythmia of one or more chambers
of the heart. It results in a loss of proper heart pumping action and a
corresponding loss of blood circulation.
It is known that fibrillation can be arrested by passing an electric
current of sufficient strength through the fibrillating heart. The
electric field causes a depolarization of the heart muscle or myocardium.
If this depolarization extends to a sufficient amount of the heart tissue,
defibrillation can be achieved.
If the fibrillation occurs in a clinical environment, such as a hospital
where defibrillation equipment is usually readily available, a pair of
disc shaped paddles can be placed upon the chest of the patient. When
sufficient electrical energy is applied to the paddles, the required
electrical field can be established in the heart. However, this
presupposes that fibrillation is detected in time and that the necessary
equipment is close at hand.
An alternative solution is to attach a set of electrodes directly to the
heart. This would typically be done when access to the heart is provided
by open heart surgery or some other surgical procedure. Because the
electrodes are attached directly to the heart, the electrical energy
required to accomplish defibrillation is much less than the energy
required for paddles placed externally on the chest at a substantial
distance from the heart.
For people prone to fibrillation symptoms, then it thus becomes practical
to implant in the body of a patient a defibrillator that continuously
monitors heart activity and automatically and immediately establishes a
depolarizing electrical field upon detection of fibrillation.
When the depolarizing electrical field is supplied by an implanted battery,
the field must be generated with the expenditure of a minimum amount of
electrical energy in order to optimize battery life. Even small energy
losses can be important when the energy must be supplied by an implanted
battery. It thus becomes difficult to satisfy conflicting demands of
physiological factors and electrical energy consumption factors.
From the physiological point of view it is desirable to minimize
interference with the operation of the heart. A point contact connected by
an extremely flexible wire would be an ideal electrode from the
physiological perspective. However, such an arrangement would be less than
optimum from the electrical point of view, since it would not provide a
uniform electric field in the heart desirable for effective
depolarization.
In order to accomplish defibrillation it is necessary to establish a
minimum strength depolarizing electrical field throughout a substantial
portion of the myocardium. As one would expect, the depolarizing
electrical field strength from a small electrode is a maximum at the
electrode and decreases as a function of distance from the electrode. From
the electrical point of view it is thus desirable to have a large
electrode contacting a substantial surface area of the myocardium.
Although the large surface area electrode is ideal from the electrical
point of view, it is physiologically unsatisfactory because it imposes a
physical restraint upon the heart. The heart must beat continuously about
60 beats per minute and even the slightest interference becomes
significant after millions of repetitions. If a heart is of a condition to
be in danger of fibrillation to start with, any interference with heart
activity becomes even more significant. A compromise is thus generally
made between the point contact that is physiologically desirable and the
large surface area electrode that is electrically desirable.
U.S. Pat. No. 4,827,932 to Ideker et al. teaches a set of large surface
area flat patch electrodes in FIGS. 6a, 6b and 6c which are intended to
cover as much of the ventricular surface area of the heart as is possible
without inducing large current flows directly between pairs of adjacent
electrodes through vascular passages. In the arrangement of FIG. 6b the
patch is partially bifurcated to form two projections that may be
conformably wrapped about the heart. A laterally connected lead gives rise
to a high current density in a base region as current flows past the
bifurcation toward the projection farthest from the lead connection point.
With such a configuration, the electrical losses which result from the
non-uniform current densities can be substantial relative to the available
energy from an implanted battery. In addition, the large patch size
necessarily imposes a significant restriction upon the expansion and
contraction of the heart muscle.
U.S. Pat. No. 4,030,509 to Heilman et al. teaches various arrangements of
patch electrodes including a large, contoured electrode for placement at
the base of the heart. U.S. Pat. No. 4,291,707 and Des. 273,514 to Heilman
et al. teach various arrangements of relatively inflexible flat planar
electrodes. Such arrangements do not readily provide substantial contact
area without perceptibly impeding the pumping action of the heart.
SUMMARY OF THE INVENTION
A flexible, planar patch electrode for cardiac defibrillation in accordance
with the invention is fabricated from a sheet of a conductive mesh with a
layer of Dacron-reinforced Silastic sheeting secured to the noncontact
side to provide insulation. The electrode has a generally rectangular base
portion with two or more protrusions separated by slots extending
longitudinally from the base portion.
A tantalum coil within silicone tubing preferably extends about the
periphery of the mesh to make the electrode more readily visible on X-ray
photographs. The insulation layer extends a short distance beyond the
periphery of the titanium mesh to ensure good insulation of the mesh and
to provide a peripheral surface through which sutures may be passed to
secure the electrode to a heart. Silastic sheeting is sufficiently soft to
permit passage of a suture needle therethrough, but may optionally have
preformed suture apertures in the periphery thereof.
A lead is conductively secured to the base portion of the electrode as by
welding or crimping with the point of attachment being centrally located
between the sides of the base. The central placement minimizes current
density past the slots separating the individual protrusions to
correspondingly minimize resistive electrical losses in the patch.
BRIEF DESCRIPTION OF THE DRAWINGS
A better understanding of the invention may be had from a consideration of
the following Detailed Description, taken in conjunction with the
accompanying drawings in which:
FIG. 1 is a plan view, partly broken away, taken from the contact side, of
a titanium mesh patch electrode for cardiac defibrillation in accordance
with the invention;
FIG. 2 is a plan view, partly broken away, taken from the contact side, of
an alternative arrangement of a titanium mesh patch electrode in
accordance with the invention;
FIG. 3 is a plan view of a mesh patch electrode for cardiac defibrillation
in accordance with the invention; and
FIG. 4 is a plan view of a patch electrode for cardiac defibrillation
illustrating the creation of unacceptable field concentrations which are
avoided by the invention.
DETAILED DESCRIPTION
Referring now to FIG. 1, a planar, highly flexible patch electrode 10 for
cardiac defibrillation in accordance with the invention includes a layer
of foraminous mesh 12 having a layer of insulating material 14 such as
Dacron reinforced Silastic sheeting bonded thereto. A radiopaque marker 16
is formed by interweaving about the periphery of the mesh 12 a tantalum
coil that is disposed within an electrically insulating sealed silicone
tube. The mesh 12 is a flexible planar screen formed preferably of
titanium wire. Other materials appropriate for the screen are carbon,
metal carbide, metal nitride, and metal oxide. Furthermore, the patch may
be completely surface-coated by the carbon and the metal compounds noted.
The metals of course should be non-toxic, biocompatible, which is well
known in the art.
The electrode preferably has a conductive mesh surface area in the range of
2-4 square inches to provide substantial spatial distribution of an
applied electric field without being so large as to lose flexibility or
otherwise interfere with the normal beating of a heart to which it is
attached. An area of substantially 3 square inches is preferred.
The electrode 10 is shaped to provide a generally rectangular base area 20
having two elongated protrusions 22, 24 extending longitudinally
therefrom. The protrusions 22, 24 have a generally rectangular shape with
rounded corners and are separated by an intermediate slot 26. The use of a
plurality of protrusions 22, 24, together with the inherently flexible
nature of the insulated titanium mesh patch enable the electrode -0 to be
readily shaped to match the contours of a section of a heart to which it
is attached. The protrusions may also have a gently curved shape to better
match the anatomy of the heart. After being secured, the low mass patch
electrode 10 can continue to flex as necessary to remain in conformity
with the beating heart while offering minimal interference with the normal
motion of the heart surface.
The slot 26 enables the electrode 10 to be adaptively located on the
surface of the heart so as to straddle or otherwise avoid large blood
vessels or other features that might cause a degradation of optimal heart
activity, or pose a risk during defibrillation.
The periphery 30 of the thin insulating layer 14 is sufficiently soft and
pliant that a needle may be used to pass sutures (not shown) therethrough
to secure the electrode to the myocardium in a conventional manner.
Alternatively, preformed holes or tabs (not shown) may be disposed about
the periphery 30 of insulating layer 14 to make it even easier to suture
the lead to the myocardium.
A conductive lead 32 is surrounded by an insulating tube 34 and
conventionally secured as by welding or crimping to the noncontact side of
the mesh 12 at a position that is centrally located laterally within the
base region. The insulation tube 34 extends to beneath the insulating
layer 14 so that the noncontact side of the electrode 10 remains fully
electrically insulated to protect surrounding tissue. The conductive lead
32 extends beyond insulating tube 34 to enable conductive securement to
the foraminous layer 12.
The central location of the weld within the base region helps to minimize
current density and hence resistive losses in the patch. In the double
protrusion version of FIG. 1 the current divides at the weld point to pass
to the two separate protrusions. This contrasts with prior art contact
arrangements wherein all of the current for one of the protrusions must
pass a constricted region opposite a slot. By the orientation of the mesh
so that its filaments are parallel to and perpendicular to the main
dimensions of the patch, the mesh strands perpendicular to the protrusions
will carry zero, or very low currents. Hence, the cutting of these
finger-like protrusions will not substantially increase the total
resistance of the patch.
The titanium mesh 12 may be conventionally fabricated of relatively fine,
flexible strands with a density of about 20-50 strands per inch. The mesh
thus forms a relatively fine foraminous screen that provides a high
density of electrical contact points while retaining good flexibility to
permit conformal shaping to the heart and minimize interference with heart
activity after attachment.
FIG. 2 illustrates an alternative arrangement of a flexible planar patch
electrode 50. Electrode 50 has a construction similar to that of electrode
10. However, the shape is somewhat modified to provide three protrusions
in place of the two protrusions 22, 24 of electrode 10.
Electrode 50 has a generally rectangular base region 52 with three
generally rectangular protrusions 54, 56, 58 extending longitudinally
therefrom. The protrusions 54, 56, 58 are separated by two longitudinally
extending intermediate slots 60, 62.
The additional protrusion and intermediate slot provide additional
flexibility in locating and securing the electrode 50 relative to the
surface of a heart. A lead 72 insulated by tube 74 is conductively secured
to the titanium mesh centrally within the base region 52. The slots 60, 62
impose area restrictions on the passage of current from lead 72 to the
protrusions 54 and 58. However, only the current for a single one of three
protrusions must pass through the narrowed or restricted regions, both
current densities and resistive losses in these regions are thus
minimized.
As shown in FIG. 1, the mesh strands that are essentially orthogonal to
conductive lead 32 may be contoured in an arcuate fashion, resulting in
the mesh having strands substantially parallel to the length of the
respective protrusions and strands substantially orthogonal to the width
of the respective protrusions. This will be described in further detail
with reference to FIG. 3. The mesh as shown in FIG. 2, on the other hand,
is uniform throughout, and the shape of the patch may be obtained, for
example, by following the contour of a template placed over the mesh so as
to establish the final patch shape.
As previously noted, the present invention contemplates, but is not limited
to, that the mesh 12 has orthogonally-oriented adjacent strands so that
each mesh element is at least rectangular in form and preferably square,
with each opposite side of the mesh element being, of course, of equal
dimension.
More specifically and as shown in detail in FIG. 3, mesh element 78 is
bounded by vertical mesh lines 80 and 82 and horizontal mesh lines 84 and
86. As further noted in FIG. 3, the strands or mesh lines 80, 82, etc.,
extend longitudinally between the patch end which includes electrode 88 to
the tips 90' and 92' of the fingers 90 and 92 respectively.
From FIG. 3, it is observed that strands 80, 82, etc., are oriented
essentially parallel to the length of the patch, whereas strands 84, 86,
etc., are orthogonal to strands 80 and 82, and to the length of the patch
10.
With an electric potential V applied to conductive lead 88 which is
electrically coupled to the mesh strands an electric field perpendicular
to such mesh strands, develops in the patch. The electric field identified
as E in FIG. 3 illustrates the orthogonal nature of the field. With a
uniform electric field distribution, resistive losses due to varying
densities and fringing effects are minimized. The foregoing will be
appreciated by inspection of FIG. 3 and FIG. 4. As noted from FIG. 3, the
electric field E is substantially uniform throughout the mesh 12 and is
maintained uniform in each of the fingers 90 and 92.
Accordingly, the design of the mesh of the present invention avoids the
creation of the field concentrations at 94, which characterize the
unacceptable designs, such as shown in FIG. 4. As noted, the present
invention avoids the resistive losses arising out of the creation of
non-uniform electric field patterns.
While there have been shown and described various alternative arrangements
of a flexible, planar patch electrode for cardiac defibrillation in
accordance with the invention for the purpose of enabling a person of
ordinary skill in the art to make and use the invention, it should be
appreciated that the invention is not limited thereto. Accordingly, any
modifications, variations or equivalent arrangement within the scope of
the attached claims should be considered to be within the scope of the
invention.
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Description |
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