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BACKGROUND OF THE INVENTION
I. Field of the Invention
This invention relates generally to surgical apparatus and more
specifically to an improved catheter for use in performing transluminal
angioplasty.
II. Discussion of the Prior Art
Background for understanding the surgical application of the instant
invention can be obtained from the "Background of the Invention" set out
in Schjeldahl et al U.S. Pat. No. 4,413,989 and the Simpson et al U.S.
Pat. No. 4,323,071, which background information is incorporated herein by
reference.
It is deemed helpful to the successful use of transluminal angioplasty
procedures if means are provided for precisely locating the site of the
stenotic lesion to be treated so that the expander member on the catheter
can be positioned adjacent that site such that, when the expander member
is inflated, the stenotic lesion will be compressed into the endothelial
tissue of the blood vessel being treated. In the past, it has been the
practice to use X-ray or fluoroscopic observation where a suitable
radiopaque dye is introduced to render the obstruction visible. The
present invention also provides the possibility of determining the
composition of the plaque (the degree of calcification) by the frequency
dependence of the impedance. Hence, by suitable selection of the driving
frequency, the characteristics of the lesion can be determined.
SUMMARY OF THE INVENTION AND OBJECTS
The present invention is directed to a dilating catheter assembly which
incorporates a means whereby the cross-sectional size of a blood vessel
may be measured while routing the catheter through the vascular system to
the site of the stenotic lesion to be treated. By measuring the vessel's
cross-section on either the proximal or distal side of the expander on a
continuous basis, it is possible to precisely position the expander
relative to a constriction to be treated. For example, when performing a
percutaneous transluminal coronary angioplasty, as the catheter is
advanced through the vascular system with the distal end entering a
coronary artery, if a first measurement taken distally of the expander
shows a decrease in vessel cross-section followed by an increase while
that sensed proximally of the expander remains at the larger size, it is
known that the expander is juxtaposed at the location of the stenotic
lesion. Now, a suitable fluid may be introduced through the proximal end
of the catheter to inflate the expander member to a predetermined maximum
size and pressure and thereby press the lesion into the wall of the
coronary artery. Following this step, the catheter can be retracted
slightly and the cross-sectional area measurements can be repeated to
determine the improved patency of the coronary artery.
The catheter itself comprises an elongated tubular member having an
inexpandable, extensible expander (balloon) disposed near it distal end.
As is described in the aforereferenced Simpson et al patent, the wall of
the tubular member may be provided with ports disposed between the
spaced-apart ends of the expander member, which ends are sealingly joined
to the exterior of the tubular member. Thus, by injecting a suitable fluid
into the lumen of the tubular member at its proximal end, the expander can
be inflated. Disposed distally at the distal end of the expander member
are a plurality of electrodes which are spaced longitudinally from one
another. A similar plurality of electrodes are preferably disposed
proximally of the proximal end of the expander member, again in a
predetermined spaced relationship. In practice, it has been found
convenient to affix ring or spot electrodes on the surface of the
catheter, these electrodes being spaced from one another along the
longitudinal axis of the catheter and on either side of the expander. The
individual electrodes are connected by suitable conductors which run the
length of the catheter, either through a lumen of the tubular member or
within its walls so that the ends of the conductors assessible at the
proximal end of the catheter.
The electrical conductors connected to the surface electrode are adapted to
be coupled through conventional means to suitable switching circuitry such
that selected electrode pairs may have an alternating current signal
impressed across them. Other electrode pairs may then be used to make
impedance measurements, which impedance measurements are proportional to
the cross-sectional area of the portion of the vessel disposed between the
two impedance sensing electrodes. By utilizing the angioplasty catheter of
the present invention, the surgeon is provided with instantaneous
indications of the relative size of the lumen of the blood vessel being
treated at the site of the balloon or expander.
It is accordingly a principal object of the present invention to provide a
new and improved catheter assembly for performing percutaneous
transluminal angioplasty.
Another object of the invention is to provide a dilating catheter for
performing percutaneous transluminal angioplasty in which the catheter
includes electrode means for accommodating impedance plethysmography.
Yet another object of the invention is to provide a dilating catheter
assembly which can be readily inserted through the vascular system while
measurements are taken of the cross-sectional size of the blood vessel
being traversed by the catheter.
Still another object of the invention is to provide a dilating catheter
assembly of the above character in which a distensible expander member is
disposed on the catheter near its distal end and where plural electrode
surfaces are exposed on the surface of the catheter assembly on both sides
of the expander member.
Additional objects and features of the invention will appear from the
following description in which the preferred embodiment is set forth in
detail in conjunction with the accompanying drawings in which like
numerals in the several views refer to corresponding parts.
DESCRIPTION OF THE DRAWINGS
FIG. 1 is a side elevation view of the dilating catheter in accordance with
the present invention;
FIG. 2 is a greatly enlarged cross-sectional view of the distal portion of
the catheter of the present invention when positioned in an artery during
percutaneous transluminal angioplasty;
FIG. 3 is a greatly enlarged distal end segment of the dilating catheter of
FIG. 1;
FIG. 4 is a partial cross-sectional view illustrating an alternative way of
routing electrical conductors to the electrode segments on the catheter;
FIG. 5 is an electrical block diagram for obtaining and displaying
information concerning the cross-sectional size of a blood vessel in which
the catheter of the present invention is located; and
FIG. 6 is an electrical schematic diagram of the isolation amplifiers and
the modulators needed to extract the sensed electrical signal proportional
to cross-sectional size of a portion of the blood vessel in which the
catheter of the present invention is inserted.
DESCRIPTION OF THE PREFERRED EMBODIMENT
Referring first to FIG. 1, there is indicated generally by numeral 10 an
improved catheter in accordance with the preferred embodiment of the
invention. While the catheter 10 will be shown and described as a catheter
intended to be used during coronary transluminal angioplasty (CTA), it is
to be understood that a catheter, following the teachings of the present
invention, can be used in examining and treating body organs other than
the heart and, accordingly, the invention is not to be limited to the CTA
application only. The CTA catheter assembly 10 includes an elongated,
flexible, plastic outer tubular member 12 which, for reasons which would
become apparent from the following description, is referred to as the
expander mounting tube. The member 12 has a proximal end 14 and a distal
end 16.
The proximal end 14 of the catheter assembly 10 joins to a coupler 18 of
conventional design, the coupler allowing other tubular members 20, 22 and
24 to communicate with one or more of the lumen contained within the outer
tubular member 12. Depending upon the particular application, suitable
adapters as at 26, 28 and 30 may be employed to connect the CTA catheter
to appropriate fluid sources and/or instrumentation.
The expander mounting tube 12 may typically be a six French catheter but
limitation to such a size is not to be inferred. Also, it may be found
expedient to taper the distal end of the expander mounting tube 12 to
facilitate its entry through an ostium and into a coronary artery.
Surrounding the distal end portion of the expander mounting tube 12 is an
expander 32 which, in FIG. 1, is shown in its extended or inflated
condition. The expander 32 is preferably formed from a suitable synthetic
plastic material, such as biaxially-oriented polypropylene with the
expander being formed in an injection blow molding operation such that it
is substantially inelastic in both the axial and radial directions. The
expander member 32 is suitably bonded to the outer surface of the expander
mounting tube 12 as at 34 and 36 so that the port 38 formed through the
side wall of the expander mounting tube 12 and communicating with its
lumen is spanned by the expander member 32. The introduction of a suitable
fluid through the lumen of the expander mounting tube 12 may flow through
the port 38 so as to inflate the expander member or balloon 32 to its
maximum designed diameter.
Formed proximally of the expander member 32 are a series of spaced,
conductive, surface electrodes 39a, 39b, 39c, etc. Similarly, positioned
on the surface of the expander mounting tube 12 distally of the expander
member 32 are a further plurality of surface electrodes 39d, 39e, and 39f.
While the electrodes 39 are indicated as being surface ring electrodes, it
is not a requirement that such electrodes be a continuous band completely
surrounding the expander mounting tube.
Having described the external characteristics of the preferred embodiment,
consideration will next be given to its internal construction and, in this
regard, the cross-sectional view of FIG. 2 will be referred to. In this
view, the distal end portion of the catheter assembly 10 is illustrated in
a greatly enlarged scale as being located within the lumen of an artery
40, and along the inner walls of this artery is a buildup of plaque as at
42. The expander member 32 is shown in its inflated condition whereby the
stenotic lesion or plaque 42 is in the process of being compressed into
the endothelial layer of the artery 40 as during a typical angioplasty
procedure.
Also revealed in the cross-sectional view of the FIG. 2 is a
coaxially-arranged pressure sensing tube 44, which is located within the
lumen 46 of the expander mounting tube 12 and which extends the full
length of the catheter from the connector assembly or coupler 18 to the
distal tip 16. The outside diameter of the pressure sensing tube 44 is
less than the inside diameter of the expander mounting tube 12 and, as
such, a clearance is provided through which the fluid for expanding the
expander member 32 may flow. The inner lumen 48 of the pressure sensing
tube 44 may be coupled by means of the connector 26 to a suitable
manometer whereby blood pressure distally of the expander member can be
monitored. This same lumen may also be used, when desired, to inject
medicaments and/or radiopaque dye and the like for rendering the stenotic
lesions visible on the screen of a fluoroscope.
The ring electrodes 39a, 39b and 39c are connected by electrical conductors
41 to connector pins of a suitable plug 28 and, similarly, the ring
electrodes 39d, 39e and 39f are connected by electrical conductors 43 to
other pins in the electrical plug 28. In the view of FIG. 2, the
electrical leads or wires 41 and 43 are routed through the lumen 46 of the
expander mounting tube 12 from their associated electrodes to the adaptor
plug 28.
FIG. 4 illustrates an alternative way of routing the electrical wires from
the electrical connector 28 through the lead 22 and the coupler 18 to the
individual electrodes at the distal end of the catheter assembly 10. Here,
rather than being routed longitudinally through the lumen 46, the wires 41
leading to the proximal electrodes and the wires 43 leading to the distal
electrodes may be helically wound and embedded within the walls of the
expander mounting tube 12. The manner in which such a catheter may be
constructed is fully set out in co-pending application Ser. No. 445,240,
filed Nov. 29, 1982, for "CATHETER ASSEMBLY", which is assigned to the
assignee of the instant application.
Irrespective of the method employed, electrical connections are
individually brought out at the proximal end of the catheter from each of
the surface electrodes 39a through 39f. While in FIGS. 2 and 3, only three
such electrodes are shown distally and proximally of the expander member
32, it will be apparent to those skilled in the art that a greater or
fewer number of such surface electrodes may be provided. Furthermore, the
manner in which surface electrodes may be formed on the exterior surface
of the expander mounting tube 12 may be the same as is used in forming a
ring electrode on a bipolar-type pacing lead conventionally used with
heart pacemakers.
Referring again to FIG. 1, the coupler 30 comprises a fluid valve member
which is in fluid communication via the tube 24 to the lumen of the
catheter which communicates via ports 38 with the interior of the expander
member 32. It is by way of the valve member that the connector 28 is an
electrical plug which is adapted to mate with the circuitry yet to be
described for the purpose of conducting impedance plethysmography. The
coupler or connector 26 may be joined or pressure-sensing equipment and/or
selectively to a source of radiopaque dye or other medicaments, the tube
20 joining in the coupler 18 with the pressure sensing tube 44 of the
catheter assembly.
Referring next to FIG. 5, each of the surface electrodes 39a through 39d is
coupled via the connector 28 to a switch means 50. Also coupled as an
input to the switch means is a suitable oscillator 52 for applying a
voltage of a frequency f.sub.0 across two preselected surface electrodes
39a through 39d, all as determined by the setting of the switch means 50.
The particular pair of surface electrodes which are coupled through the
switch means 50 to the oscillator 52 may be referred to as the driving
electrodes. The remaining electrodes which are disposed between the pair
of driving electrodes function as sensing electrodes and are effective to
pick up electric field signals existing at the site of the sensing
electrodes occasioned by the introduction of a current flow in the fluid
(blood) between the spaced-apart driving electrodes.
As will be set out in greater detail below, the impedance presented to the
current is dependent upon the conductivity of the fluid (blood) or tissue
in the local area defined by a cooperating pair of sensing electrodes and
this conductivity is, in turn, dependent upon the cross-sectional area of
the blood vessel at the site of the sensing electrodes and the presence of
any sclerotic tissue. The electrical signals picked up by the sensing
electrodes pass through the switch means 50 to the input of a set of
isolation amplifiers 54, 56 and 58. From there, the signals are fed
through demodulator networsk 60, 62 and 64. The implementation of the
oscillator/driver 52 isolation amplifiers 54 and the demodulator 60 is
shown in FIG. 6 and these circuits will be described in greater detail
hereinbelow.
The output from the demodulators 60-64 are, in turn, fed to a set of
analog-to-digital converters 66, 68, and 70 which function to create a
digital number proportional to the analog signal developed at the output
of the demodulators 60-64. Once so digitized, these values may be applied
as inputs to a suitable microprocessor system 72 where, in accordance with
a program of instructions, can be suitably processed for presentation
either on a video monitor 74 or on a hardcopy printer 76.
Referring now to FIG. 6, the carrier frequency for driving the outer
electrodes 39a and 39f includes a Type 3576 digital band-pass filter
having a crystal 78 connected across appropriate terminals thereof. It
incorporates a tone-generator, a band reject filter, a band-pass filter
and an output driver. A digitized sine wave signal is generated at the
output pin 5 of the device, the sine wave having a frequency equal to that
of the center frequency of the digital filter, e.g. 2,600 Hz. This signal
is applied via conductor 80 and through a coupling capacitor 82 to the
base electrode b of a transistor 84. This transistor has its emitter
electrode e connected through a current-limiting resistor 86 to ground
point 88. A source of potential is adapted to be connected to the terminal
90, which is coupled via a resistive voltage divider, including resistors
92 and 94, to the ground point 88. The base electrode b of the transistor
84 is connected to the common terminal of the resistive voltage divider
and, by properly selecting the ohmic values of these two resistors, the
transistor may be biased for Class-A operation. When so configured, a sine
wave current corresponding in frequency to the signal on line 80 is made
to flow from the positive voltage source terminal 90, through a
light-emitting diode 96 and through the emitter-to-collector path of the
transistor 84 and the current-limiting resistor 86 to ground. Thus, the
light energy given off is sinusoidal in nature and is adapted to a
photo-detector device 98 connected across the input terminals of an
operational amplifier 100 which is configured to function as a linear
amplifier. Specifically, the output from the linear amplifier 100 is
connected to the input or base electrode of a NPN transistor stage 102.
The output from this stage is developed across the resistor 106 connected
in its emitter circuit and is applied to the inverting input of an
adjustable gain amplifier 108. Because of the manner in which the
opto-coupler is configured, the voltage appearing at the emitter electrode
of the transistor 102 is a voltage which is proportional to the current
flowing through the LED device 96. The amplified signal emanating from the
amplifier device 108 is applied through a coupling capacitor 110 and a
resistor 112 to the particular ring electrode selected by the switch means
50 of FIG. 5. The voltage appearing at the terminal point 114 is taken
with reference to the tip electrode of the catheter.
With continued reference to FIG. 6, the terminals 116 and 118 are arranged
to be coupled to the conductors associated with the particular driven ring
electrodes selected by the switch means 50 of FIG. 5. Terminal 116 to
which one of the sensing electrodes is selectively connected is coupled
through a resistor 120 to the non-inverting input of an operational
amplifier 122. Similarly, the terminal 118 which is selectively coupled to
another sensing ring electrode is connected through a coupling resistor
124 to the non-inverting input of an operational amplifier 126. The
operational amplifiers 122 and 126 have their feedback components
connected so as to cause them to function as high-pass filter means.
Specifically, a series connection of a capacitor 128 and a resistor 130 is
connected between the inverting input of the operational amplifier 122 and
the inverting input of the operational amplifier 126. Feedback resistors
132 and 134 are respectively coupled from the output of the operational
amplifiers 122 and 126 back to the outer terminals of the serially
connected components 128 and 130. The component values are selected such
that the high-pass filter has a cut-off frequency of approximately 50 Hz,
which allows the modulated carrier signal to pass through the filter stage
while rejecting the lower frequency artifacts which may be occasioned by
electrocardiographic signals and muscle noise.
The output from the high-pass filter is applied across the inputs of a Type
3656 instrumentation amplifier which has a high input impedance and a
transformer coupled isolation amplifier incorporated therein. This device
provides multi-port isolation of both power and signal and, as such, is
readily suited to biomedical applications because of the resulting
elimination of shock hazards. The output from the amplifier appearing at
terminal point 138 is directly coupled to input pin 1 of the digital
filter network 140. The digital filter network 140 comprises an extremely
high-Q band-pass filter, which is turned or set to pass the modulated
carrier signal while rejecting artifacts such as P-waves, T-waves,
R-waves, etc.
The output from the digital filter 140 is applied via an offset gain stage
142 to the input of a so-called "True RMS Converter". The offset gain
stage 142 is included to merely provide calibration factors for permitting
limited adjustment of signal amplitudes and the like.
The True RMS Converter 144 functions to directly compute the true root mean
square value of any complex waveform containing ac and dc components and
yields an equivalent dc output level. Thus, it will act as a demodulator
circuit for separating the alternating current carrier signal from the
wave which is modulating it. Thus, a signal proportional to the modulation
envelope of the carrier appears on the conductor 146 and is applied to a
low-pass filter stage comprising an operational amplifier 148 having a
feedback capacitor 150 connected between the output from the amplifier and
a junction point 152 formed at the common connection between series
connected resistors 154 and 156. To provide the low-pass characteristics,
a further capacitor 158 is coupled between the non-inverting input of the
operational amplifier 148 and ground point 88.
The low-pass filter network is configured to have a center frequency
f.sub.c equal to approximately 50 Hz and is effective to remove ripple
from the output signal. The resulting low frequency signal passing through
the filter stage is applied to a further operational amplifier which is
configured to function as a buffer or isolation circuit 160.
Providing further low-pass filtering to the signal emanating from the
buffer stage 160 are a series resistor 162 and a shunt capacitor 164. The
signal appearing at terminal 166 is thus directly proportional in
amplitude to the impedance being monitored which, as indicated, is
directly proportional to the size of the blood vessel in which the
selected sensing electrodes find themselves.
Those skilled in the art will recognize that for each pair of sensing
electrodes there will be one such isolation amplifier and demodulator
configuration, i.e., the combination of circuitry shown between the input
terminals 116 and 118 and the output terminal 166.
In implementing the isolation amplifier/demodulator system of FIG. 6, it
has been found that component types and component values as set forth in
the following table have produced an operable embodiment. However, it is
to be understood that the invention is not to be limited to this
particular circuit arrangement or to the component types and values
indicated.
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Component Value/Type
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R 86 510 ohms
R 92 12 K ohms
R 94 6.8 K ohms
R 106 2 K ohms
R 107, 141 100 K ohms variable
R 109, 124, 127, 139, 143
100 K ohms
R 112 200 K ohms
R 120, 124 10 K ohms
R 132, 134, 135, 154, 156
1 megohm
R 145 20 K variable
R 149 10 megohms
R 162 470 ohms
C 82, 110 1.0 microfarads
C 128, 147 0.1 microfarads
C 158 0.001 microfarads
C 164 2.2 microfarads
Opto-coupler MOC 5010
Op Amps (all) TL 064
Instrumentation Amp
Burr-Brown 3656
Digital Filter
S-3526 (Advanced Microsystems, Inc.)
True RMS Converter
AD 536 (Analog Devices, Inc.)
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OPERATION
In carrying out an angioplasty procedure, the catheter of the present
invention is introduced using the Seldinger technique, usually into the
femoral artery and is routed through the vascular system, through a
coronary ostium and into a selected one of the coronary arteries. Once so
located, the circuit of FIG. 6 can be energized and the selector means 50
of FIG. 5 is used to cause an alternating current carrier signal from the
digital filter network 140 to be applied to the base of Class A amplifier
transistor 84. Thus, the light energy emitted by the LED 96 is similarly
controlled in sinusoidal fashion, producing a carrier voltage on the
emitter electrode of the opto-coupler transistor element 102 which is
proportional to the current flowing through the LED. This signal is, in
turn, then adjusted by the network 108 including the variable resistor 107
and the fixed resistor 109, with the resulting sinusoidal signal being
applied between the switch-selected driven ring electrode and the isolated
ground point associated with the tip electrode.
As was explained earlier in the specification, the impedance presented to
the current flowing between the driven electrodes varies in relation to
the inflow and outflow of blood in the coronary artery and also to its
cross-sectional dimensions. This causes the sinusoidal carrier signal to
be modulated and the resulting modulated carrier is developed between
selected pairs of sensing electrodes which are coupled, via the elongated
conductors flowing through the length of the catheter body connected to
the terminal points 116 and 118 of the instrumentation amplifier.
Specifically, the capacitor 128 and resistor 130 when connected as
indicated in FIG. 6 to the operational amplifiers 122 and 126, function as
a high-pass filter. The output of the high-pass filter is applied to the
Burr-Brown Type 3656 transformer coupled isolation amplifier halves 136
and 137.
The initial high-pass filter stage at the input of this isolation amplifier
serves to remove the ECG and DC offset components of the input wave form
which may be superimposed on the modulated carrier by tissue
depolarization and "electrode effects".
The output from the transformer coupled isolation amplifier stage 137 is,
in turn, connected as an input to the digital filter network 140. This
filter network is arranged to function as a high-Q band pass filter having
a very narrow pass band centered about the frequency developed by the
crystal element 78. By setting this frequency at about 2,600 Hz, one is
sure to strip off from the modulated carrier signal any remaining
artifacts due to ECG or electrical noise. The output from the digital
filter network is then increased by properly setting the potentiometer 145
and the variable resistor 141 so that calibration can take place.
To provide the necessary demodulation of the modulated carrier, the
composite wave form is applied to a Type AD 536 True RMS Converter. This
is an integrated circuit chip which functions to convert the rms value of
the applied signal to a dc level. The resulting output signal developed on
conductor 146 effectively comprises the modulating envelope, and it is
applied as an input signal to a low-pass filter whose cutoff is set at
about 15 Hz. The filter includes the operational amplifier 148 and its
associated feedback capacitor 150 an input shunt capacitor 158. The
resulting dc signal is proportional to the cross-sectional size of the
blood vessel in which the selected pair of sensing electrodes are then
positioned. The signal may further be buffered by an operational amplifier
160 to provide appropriate matching to down-stream components such as
analog-to-digital converting circuitry (see FIG. 5).
By monitoring changes in the value of the magnitude of the impedance 1Z1, a
cardiovascular surgeon is in a better position to know the characteristics
of the interior of the artery being treated. Furthermore, he is better
able to locate plaque buildup on the interior walls of the coronary
arteries or other blood vessels being investigated. This aids in properly
positioning the expander member relative to the potential obstruction.
Then, appropriate fluids are introduced through the lumen of the catheter
so as to expand the expander member at the tip thereof, pressing the
stenotic lesion back into the wall of the blood vessel where it tends to
be reabsorbed.
Through proper use of the switching means 50, the physician is able to
monitor dimensional characteristics, both proximally and distally of the
expander member. As already mentioned, this is a great aid in the proper
positioning of the angioplasty catheter.
The invention has been described in considerable detail, in order to comply
with the Patent Statutes and to provide those skilled in the art with
information needed to apply the novel principles, and to construct and use
such specialized components as are required. However, it is to be
understood that the invention can be carried out by specifically different
equipment and devices, and that various modifications, both as to
equipment details and operating procedures can be effected without
departing from the scope of the invention itself.
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