APPARATUS AND METHODS FOR STIMULATING REVASCULARIZATION AND/OR TISSUE GROWTH
Field Of The Invention
The present invention relates to apparatus and methods for stimulating revascularization and tissue growth in an interior region of an organ or vessel, such as the heart. More particularly, the present invention provides a device that enables a clinician to stimulate a healing response, or deposit a bioactive agent at, a series of sites within in interior region of an organ or vessel to stimulate revascularization.
Background Of The Invention
A leading cause of death in the United States today is coronary artery disease, in which atherosclerotic plaque causes blockages in the coronary
arteries, resulting in ischemia of the heart (i.e., inadequate blood flow to the myocardium) . The disease manifests itself as chest pain or angina. In 1996, approximately 7 million people suffered from angina in the United States- Coronary artery bypass grafting (CABG) , in which the patient's chest is surgically opened and an obstructed artery replaced with a native artery harvested elsewhere, has been the conventional treatment for coronary artery disease for the last thirty years. Such surgery creates significant trauma to the patient, requires long recuperation times, and causes a great deal of morbidity and mortality. In addition, experience has shown that the graft becomes obstructed with time, requiring further surgery.
More recently, catheter-based therapies such as percutaneous transluminal coronary angioplasty (PTCA) and atherectomy have been developed. In PTCA, a mechanical dilatation device is disposed across an obstruction in the patient's artery and then dilated to compress the plaque lining the artery to restore patency to the vessel. Atherectomy involves using an end effector, such as a mechanical cutting device (or laser) to cut (or ablate) a passage through the blockage. Such methods have drawbacks, however, ranging from re-blockage of dilated vessels with angioplasty to catastrophic rupture or dissection of the vessel during atherectomy. Moreover, these methods may only be used for that fraction of the patient population where the blockages are few and are easily accessible. Neither technique is suitable for the treatment of diffuse atherosclerosis.
A more recent technique which holds promise for treating a larger percentage of the patient population, including those patients suffering from diffuse atherosclerosis, is referred to as transmyocardial revascularization (TMR) . In this method, a series of channels are formed in the left ventricular wall of the heart. Typically, between 15 and 30 channels about 1 mm in diameter and up to 3.0 cm deep are formed with a laser in the wall of the left ventricle to perfuse the heart muscle with blood coming directly from the inside of the left ventricle, rather than traveling through the coronary arteries. Some researchers believe that the resulting channels improve perfusion of the myocardium with oxygenated blood. Apparatus and methods have been proposed to create such channels both percutaneously and intraoperatively (i.e., with the chest opened).
U.S. Patent No. 5,389,096 to Aita et al . describes a catheter-based laser apparatus for use in percutaneously forming channels extending from the endocardium into the myocardium. The catheter includes a plurality of control lines for directing the tip of the catheter. As the laser ablates the tissue during the channel forming process, the surrounding tissue necroses, resulting in fibroid scar tissue surrounding the channels. U.S. Patent No. 5,380,316 to Aita et al . describes an intraoperative laser-based system for performing TMR.
U.S. Patent No. 5,591,159 to Taheri describes mechanical apparatus for performing TMR comprising a catheter having an end effector formed from a plurality of spring-loaded needles. The catheter first is positioned percutaneously within the left ventricle. A plunger is then released so that the needles are thrust
into the endocardium. The needles core out small channels that extend into the myocardium as they are withdrawn. The patent suggests that the needles may be withdrawn and advanced repetitively at different locations under fluoroscopic guidance. The patent does not appear to address how tissue is ejected from the needles between the tissue-cutting steps.
Although it is generally agreed that TMR benefits many patients, researchers do not agree upon the precise mechanism by which TMR provides therapeutic benefits. One theory proposes that TMR channels remain patent for long periods of time, and provide a path by which oxygenated blood perfuses the myocardium. However, relatively recent histological studies indicate that TMR channels may close within a short time following the procedure. For example, Fleischer et al . , in "One-Month Histologic Response Of Transmyocardial Laser Channels With Molecular Intervention," Ann. Soc. Thoracic Surg., 62:1051-58 (1996), evaluated histologic changes associated with laser TMR in a 1-month nonische ic porcine model, and was unable to demonstrate channel patency 28 days after TMR.
Other researchers have observed that in laser-based TMR patients, there appears to be enhanced vascularization of the tissue on the margins of the scar tissue resulting from the laser channel-forming process. It has therefore been hypothesized that the act of causing trauma to portions of the myocardium may invoke a regenerative process, that enhances the development of neovascularization and endothelialization in the tissue.
To investigate these alternative theories, researchers have studied the use of gene therapy in promoting blood vessel growth in the tissue surrounding laser TMR channels. In one study, researchers intraoperatively administered a single dose of vascular endothelial growth factor (VEGF) at the time of laser TMR. Although the study showed no significant increase in myocardial vascularity, the researchers hypothesized that a longer duration of VEGF residence may be necessary to stimulate angiogenesis.
In view of the foregoing, it would be desirable to provide apparatus and methods for stimulating revascularization and tissue growth in an interior region of an organ or vessel, such as the heart, by stimulating native revascularization and tissue growth mechanisms.
It would also be desirable to provide apparatus and methods for stimulating revascularization and tissue growth by controlling the placement and size of tissue treatment sites, thereby resulting in a controlled degree of scar tissue formation.
It would be still further desirable to provide apparatus and methods for stimulating revascularization and tissue growth by depositing a controlled amount of a bioactive agent, such as an angiogenic growth factor, at the treatment sites.
Summary Of The Invention
In view of the foregoing, it is an object of this invention to provide apparatus and methods for stimulating revascularization and tissue growth in an interior region of an organ or vessel, such as the heart, by stimulating native revascularization and tissue growth mechanisms.
It is another object of the present invention to provide apparatus and methods for stimulating revascularization and tissue growth by controlling the placement and size of tissue treatment sites, thereby resulting in a controlled degree of scar tissue formation.
It is a still further object of this invention to provide apparatus and methods for stimulating revascularization and tissue growth by depositing a controlled amount of a bioactive agent, such as a drug or an angiogenic growth factor, at the treatment sites.
These and other objects of the present invention are accomplished by providing apparatus having a directable end region carrying an end effector that induces trauma at a treatment site to stimulate revascularization. The apparatus may optionally include electrodes for depositing RF energy to form a controlled degree of scar tissue formation, means for depositing a controlled amount of a bioactive agent at the treatment site, or both.
Apparatus constructed in accordance with the present invention comprises a catheter having a longitudinal axis, an end region that is deflectable relative to the longitudinal axis, and a tissue piercing end effector. The end effector may optionally include an RF electrode for causing a controlled degree of necrosis at a treatment site, the capability to deposit a controlled amount of a bioactive agent at the treatment site, or both.
Methods of using the apparatus of the present invention to stimulate revascularization and/or tissue growth are also provided.
Brief Description Of The Drawings
Further features of the invention, its nature and various advantages will be more apparent from the accompanying drawings and the following detailed description of the preferred embodiments, in which:
FIG. 1 is a view of an illustrative embodiment of apparatus constructed in accordance with the present invention;
FIG. 2 is a perspective view of an end region and end effector of the apparatus of FIG. 1;
FIG. 3 is schematic view of an illustrative arrangement for driving the end effector of FIG. 1 ;
FIG. 4 is a partial side view of the end effector of the apparatus of FIG. 1; FIG. 5 is a schematic view of an alternative illustrative arrangement for driving an end effector adapted to deliver a bioactive agent;
FIG. 6 is a partial side view of the end effector of the apparatus of FIG. 5; FIGS. 7A to 7C are views illustrating operation of the apparatus of FIG. 1;
FIG. 8 is a schematic view of another alternative arrangement for driving the end effector of the apparatus of FIG. 1; FIG. 9 is a schematic view of a yet another further alternative arrangement for driving an end effector constructed in accordance with the present invention;
FIGS. 10A and 10B are, respectively, partial side sectional views illustrating operation of another end effector of the present invention;
FIGS. 11A and 11B are, respectively, a partial side sectional view and cross-sectional view of a further alternative embodiment of an end effector of
the present invention; and
FIGS. 12A to 12D are views illustrating operation of the end effector of FIGS. 11 to deposit a pellet of a bioactive agent at a treatment site.
Detailed Description Of The Invention
The present invention relates generally to apparatus and methods for treating a plurality of tissue sites within a vessel or organ to stimulate tissue growth and revascularization. The apparatus of the present invention comprises a catheter having an end region that may be selectively articulated to a position at an angle relative to the longitudinal axis of the catheter, including a position substantially orthogonal to the longitudinal axis. The end region carries a tissue piercing end effector to induce trauma to stimulate native tissue repair and revascularization mechanisms. The end effector may optionally include an RF electrode to cause a controlled degree of necrosis, means for depositing a controlled amount of a bioactive agent at the treatment site, or both. The deflectable end region of the catheter provides precise control over the location of the end region, and thus, the end effector. Referring to FIG. 1, illustrative apparatus
20 constructed in accordance with the present invention is described. Apparatus 20 comprises catheter 21 having deflectable end region 22, end effector 23 and handle 24, cable 25 and controller 26. Apparatus 20 is coupled via cable 25 to controller 26. End effector 23, described in greater detail hereinbelow, pierces myocardial tissue, with or without coring, to attain a treatment goal .
End region 22 includes one or more control wires 27 disposed for sliding movement within catheter 21, such as described in U.S. Patent Nos. 5,389,073 and 5,330,466 to Imran, which are incorporated herein by reference. Application of a predetermined proximal force on control wire 27 (indicated by arrow A), deflects end region 23 a predetermined amount (shown in dotted lines in FIG. 2) . Accordingly, end region 23 may be moved between a transit position, parallel to longitudinal axis 28 of catheter 21 and a working position (as shown) substantially orthogonal to longitudinal axis 28.
In a preferred embodiment, wherein the end effector comprises a flexible wire having a sharpened tip, controller 26 includes a hydraulic or pneumatic piston, valve assembly and control logic for extending and retracting the end effector beyond the distal endface of end region 23 responsive to commands input at handle assembly 24 or a footpedal (not shown) . Controller 26 optionally may further contain RF generator circuitry for energizing electrodes disposed on the end effector to cause a controlled degree of necrosis at the treatment site. Alternatively, or in addition, controller 26 may include a source of a bioactive agent, and means for delivering controlled amounts of the bioactive agent to the treatment site.
Referring now to FIG. 3, end effector 23 and controller 26 of a first embodiment are described. In FIG. 4, most of catheter 21 and handle 24 have been omitted for clarity. End effector 23 comprises tissue piercing cone 41 having optional first and second RF electrodes 42a and 42b, respectively. End effector preferably comprises a rigid material that retains a sharp tip, such as stainless steel. Drive shaft 43,
which extends through cable 25 of FIG. 1, is coupled to end effector 23 via flexible coupling 44 at its distal end, and to piston 45 at its proximal end. Drive shaft 43 is disposed for reciprocation in end region 22 responsive to movement of piston 45. Drive shaft 43 may comprise a single or braided plastic or metal alloy wire, while flexible coupling 44 comprises a sturdy but flexible plastic or metal alloy.
Piston 45 is enclosed within cylinder 46 for proximal and distal movement. High pressure source 47 is connected to valve 48 and pressure lines 49a and 49b; low pressure source 50 is connected to valve 51 and pressure lines 52a and 52b. Pressure lines 49a and 52a communicate with proximal volume 53a of cylinder 46, whereas pressure lines 49b and 52b communicate with distal volume 53b of cylinder 46. Valves 48 and 51 are synchronized so that when high pressure source 47 is coupled to pressure line 49a (but not 49b) , low pressure source 50 is coupled to line 52b (but not 52a) , thus driving piston 45 in the distal direction.
Likewise, when valve 48 couples high pressure source 47 to pressure line 49b (but not 49a) , and valve 51 couples low pressure source 50 to line 52a (but not 52b), piston 45 is driven in the proximal direction. Valves 48 and 51 are coupled by wiring (not shown) to control logic 54, which actuates the valves responsive to control commands received from handle assembly 26 or a footpedal (not shown) . Cylinder 46 may employ any suitable medium for moving piston 45, and may be either pneumatic or hydraulic.
Controller 26 optionally includes RF generator circuitry 55 which generates a high frequency (e.g., greater than 100 MHZ) voltage signal. RF generator circuitry 55 is coupled via suitable bushings
and conductors (not shown) to electrodes 42a and 42b. Electrodes 42a and 42b may be arranged to conduct current through tissue located in contact them, in a bipolar mode, or may conduct current through the tissue and to a ground plate (not shown) in a monopolar mode. In embodiments of controller 26 where RF generator circuitry 55 is provided, control logic 54 may be programmed to energize electrodes 42a and 42b when piston 45 has attained its maximum distal stroke. Control logic 54 may energize electrodes 42a and 42b for a user selected interval to provide a controlled degree of necrosis in the tissue surrounding the treatment site created by end effector 23.
Referring now also to FIG. 6, when piston 45 is driven in the distal direction, end effector 23 extends beyond the distal endface of catheter 21 and pierces and extends into tissue T. End effector 23 thereby induces trauma to tissue T in the form of needle track N. If electrodes 42a and 42b and RF generator circuitry 55 are provided, control logic 55 may energize the electrodes to cause necrosis of tissue T in a region R surrounding the end effector. Control logic 54 then reverses the orientation of valves 48 and 51, thus causing end effector 23 to be retracted from tissue T and into end region 22.
Applicants expect that the trauma caused by needle track N will stimulate naturally occurring mechanisms to repair the wound at the treatment site. It is further expected that by generating a matrix of treatment sites, a network of small vessels may become established in the tissue as it heals. In addition, by providing a controlled degree of necrosis, a preselected degree of scar tissue may be induced, thus mimicking the conditions observed to induce
revascularization at the margins of laser-formed TMR channels.
With respect to FIGS. 5 and 6, an alternative embodiment of the end effector and controller of the present invention is described. Once again, catheter 21 (except for end region 22) and handle 24 have been omitted from FIG. 5 for clarity. End effector 60 comprises non-coring tissue piercing cone 61 affixed to drive shaft 62. Drive shaft 62 includes lumen 63, and extends through cable 25 of FIG. 1. Drive shaft 62 is coupled to piston 64 at its proximal end, and is disposed for reciprocation in the guide tube (not shown) responsive to movement of piston 64. Drive shaft 62 preferably comprises a thin-walled but flexible plastic or metal alloy tube. End effector 60 may optionally include electrodes 65a and 65b for applying an RF voltage potential to the tissue to cause a controlled degree of necrosis, as described hereinabove with respect to the embodiment of FIGS. 3 and 4.
Piston 64 is enclosed within a cylinder in controller 66 for proximal and distal movement. High pressure source 67 is connected to valve 68 and pressure lines 69a and 69b; low pressure source 70 is connected to valve 71 and pressure lines 72a and 72b. Pressure lines 69a and 72a communicate with proximal volume 73a of the cylinder, whereas pressure lines 69b and 72b communicate with distal volume 73b of the cylinder. Valves 68 and 71 are synchronized as described hereinabove with respect to like components of FIG. 4, so as to extend and retract end effector 60 under the control of control logic 74 responsive to control commands received from handle assembly 26.
Drive shaft 62 includes a plurality of outlet ports 75 located adjacent to cone 61 and a plurality of inlet ports 76 disposed in chamber 77. Chamber 77 contains bioactive agent 80 suspended in a biocompatible high viscosity liquid or paste, and is selectively pressurized by pressure source 78. Bioactive agent 80, may comprise a drug or an angiogenic growth factor, for example, vascular endothelial growth factor (VEGF) , fibroblast growth factor, type I (FGF-I) or type II (FGF-II), a gene vector, cardio myocytes, or other suitable agent for stimulating tissue growth and/or revascularization.
Inlet ports 76 and outlet ports 75 communicate with lumen 63. In accordance with one aspect of the present invention, when high pressure source 78 is actuated to pressurize chamber 77, a controlled amount of bioactive agent 80 is injected into inlet ports 76 of lumen 63. This in turn causes an equal amount of bioactive agent 80 to be expelled through outlet ports 75 of end effector 60 into the adjacent tissue. Control logic 74 preferably is programmed to actuate high pressure source 78 when piston 64 has attained its maximum distal stroke. Controller 66 may in addition include an RF generator circuitry similar to RF generator circuitry 55 of the embodiment of FIG. 3 for energizing electrodes 65a and 65b.
With respect to FIG. 6, when piston 64 is driven in the distal direction, end effector 60 extends beyond the distal endface of the catheter and pierces and extends into tissue T. End effector 60 thereby causes trauma to tissue T in the form of needle track N. Once end effector 60 reaches its maximum depth, control logic 74 actuates high pressure source 78,
causing a controlled amount of bioactive agent 80 to be expelled through outlet ports 75 into the tissue.
If the bioactive agent exits the ports with sufficiently high velocity, it is expected that the bioactive agent will form pockets 81 in the tissue. Alternatively, if the bioactive agent exits outlet ports 75 at lower velocity, it is expected that the bioactive agent will form a layer that coats the interior surface of needle track N. Once the bioactive agent has been deposited, control logic 74 reverses the orientation of valves 68 and 71, thus causing end effector 60 to be retracted from tissue T and into the end region of the catheter. If provided, RF electrodes 65a and 65b may be activated to cauterize tissue in the vicinity of needle track N.
As described hereinabove, applicants expect that the trauma caused by needle track N will stimulate the release of naturally tissue regenerative mechanisms to repair the wound at the treatment site. Moreover, the introduction of bioactive agent 80 along needle track N is expected to further stimulate revascularization. By generating a matrix of treatment sites within which a bioactive agent has been deposited, it may be possible to promote the development of a network of small vessels that will perfuse the tissue.
Referring now to FIGS. 7A-7C, operation of apparatus 20 in the context of treating a series of treatment sites to stimulate revascularization in left ventricular myocardium is described. In FIG. 7A, end region 22 of apparatus 20 is shown positioned in a patient' s left ventricular cavity, using techniques which are per se known. Specifically, end region 22 of apparatus 20 is inserted via a femoral artery, and is
maneuvered under fluoroscopic guidance in a retrograde manner up through the descending aorta, through aortic arch 201, and down through ascending aorta 202 and aortic valve 203 into left ventricle 204. As will of course be understood, insertion of apparatus 20 into the left ventricle is with end region 22 in its transit position.
Previously known imaging techniques, such as ultrasound, MRI scan, CT scan, or fluoroscopy, may be used to verify the location of the end region 22 within the heart. Alternatively, means may be provided in end region 22 for emitting an ultrasonic signal which is detectable using an ultrasound imaging system outside of the patient. For example, a piezo-electric transducer may be affixed to the tip of the catheter and tuned to a frequency of a color Doppler ultrasound imaging system so as to appear as a bright orange or yellow spot on the display of the ultrasound system. Yet another way to detect the location of end region 22 is by pinpointing the delay time of an EKG signal at the point of detection, using an electrode disposed in end region 22. By looking at the morphology as well as the temporal characteristics of the EKG signal, the vertical position of the catheter within the heart chamber may be determined.
Referring to FIG. 7B, once end region is located adjacent a desired portion of the endocardial surface, end region 22 is deflected to its working position, for example, by operating control wire 27. In this manner end effector 23 is disposed against a surface of the endocardium to be treated.
Controller 26 is then actuated to cause end effector 23 to pierce and extend into the interior of left ventricular wall 206. When the end effector
reaches its maximum depth, a burst of RF energy may be applied, if desired, to necrose a depth of tissue, an amount of a bioactive agent may be deposited at the treatment site, or both. Controller 26 then withdraws end effector 23 from the tissue.
As shown in FIG. 7C, a series of vertically aligned spaced-apart needle tracks 207 may be formed in left ventricular wall 206 by repositioning end region 22 using control wire 27. End effector 23 is then advanced to form a further needle track 207 in the tissue.
The foregoing methods enable a matrix of channels to be formed illustratively in the left ventricular wall. It will of course be understood that the same steps may be performed in mirror image to produce a series of needle tracks in the septal region. It is believed that the needle tracks may have a beneficial effect if formed anywhere on the walls of the heart chamber, including the septum, apex and left ventricular wall; the above-described apparatus provides this capability.
In addition, a stabilization assembly may be employed, for example, as described in copending, commonly assigned U.S. patent application 08/863,877, filed May 27, 1997, to counteract any reaction forces generated by operation of end effector 23.
In FIG. 8, an alternative arrangement for driving the end effector of the present invention is described. In controller 130 of FIG. 8, the piston and cylinder of controller 26 of FIG. 1 are replaced with a mechanical drive system. As in FIGS. 3 and 4, most of the catheter and handle have been omitted for clarity. End effector 131 comprises non-coring sharpened tip 132 coupled to drive shaft 133. Drive shaft 133 is coupled
at its proximal end to push rod 134. Push rod 134 is biased against eccentric cam 135 by spring 136. Cam 135 is mounted on motor 137, which rotates cam 135 through one revolution responsive to commands from control logic 138. Control logic 138, in turn, actuates motor 137 responsive to commands received, for example, by a button on handle 24 (see FIG. 1) . Thus, controller 130 extends and retracts end effector 131 to create a needle track in the tissue. As will of course be apparent to one of skill in designing catheter-based systems, controller 130 may optionally include either the RF generator circuitry and electrodes of the embodiment of FIG. 3, the bioactive agent delivery system described with respect to the embodiment of FIG. 5, or both. As will be further apparent, the specific drive arrangements described hereinabove are intended to be illustrative, and other mechanisms may be readily employed. For example, the specific configuration of the pressure sources, pressure lines and the valves in FIGS. 3 and 5 are intended to be merely illustrative. Equivalent mechanisms for extending and retracting the end effector may be readily employed within the scope of the present invention. Thus, for example, the end effector may be spring loaded so as to be biased in the extended position and reset after having been extended to form each needle track.
Referring now to FIGS. 9, 10A and 10B, a further alternative embodiment of a drive system and end effector suitable for use in the present invention are described. In apparatus 140 of FIG. 9, it is again to be understood that the handle and most of the catheter have been omitted for clarity. In apparatus 140, a manual drive arrangement has been substituted
for the controller of the previously described embodiments. In particular, end effector 142 comprises tip 143 having aperture 144 coupled to the distal end of drive shaft 145. Proximal end 146 of drive shaft 145 includes actuator ring 147, and proximal end 148 of catheter 141 includes rings 149. As will be apparent, drive shaft 144 may be driven in the distal direction to extend end effector 142 by squeezing actuator ring 147 towards rings 149. With respect to FIG. 10A, drive shaft 145 includes lumen 150 and push wire 151 disposed within lumen 150. Push wire 151 terminates at its proximal end in a plurality of fine wires 152. Wires 152 may comprise, for example, nickel-titanium, and are constructed so that when they extend through aperture 144, the wires diverge (see FIG. 10B) . Push wire 151 extends through lumen 150 of drive shaft 145 and terminates in button 153. By gripping flange 154 provided on proximal end 146 of drive shaft 145, button 153 may be depressed toward flange 154, thereby extending wires 152 through aperture 144.
FIG. 10A shows end effector 142 extended to pierce and extend into tissue T to form needle track N, for example, by squeezing actuator ring 147 towards ring 149. As will of course be understood, this step occurs after the catheter has been disposed within an organ or vessel as described above with respect to FIGS. 7A and 7B. FIG. 10B illustrates that extension and retraction of wires 152 generates a matrix of additional needle tracks N' . Applicant expects that, like the application of RF energy to form a controlled layer of scar tissue, or the deposition of an amount of a bioactive agent, the matrix of needle tracks N' will further stimulate revascularization in the tissue.
With respect to FIGS. 11A and 11B, an alternative embodiment of an end effector is described for depositing a bioactive agent in a pelletized form. In FIGS. 11, it is to be understood that the handle assembly and most of the catheter have been omitted. End effector 160 comprises tube 161 including beveled non-coring tip 162 mounted in distal end 163 of catheter 164. Push rod 165 is disposed for reciprocation in lumen 166 of tube 161. As shown in FIG. 11B, catheter 164 includes lumen 167 in which tube 161 is disposed, and lumen 168 through which bioactive pellets 170, illustratively, spherical beads, are advanced to end effector 160. Lumen 168 includes passageway 169 through which a pellet passes to engage push rod 165 for delivery.
In accordance with one aspect of the present invention, pellets 170 comprise a bioactive agent, as described hereinabove, disposed in a biodegradable binder, such as polycaprolactone or polylactic acid. Pellets 170 are sized to advance through lumen 168 freely and without bunching, so that when push rod is retracted in the proximal direction past the proximal edge of passageway 169, a single pellet 170 passes into lumen 166 of tube 161. While pellets 170 are illustrative spherical, it is to be understood that the bioactive agent may be readily formed into any of a number of other shapes, such as rods, cones, granules, etc., and that the above-described delivery system may be readily adapted to such other pelletized forms. Referring now to FIGS. 12A to 12D, operation of the apparatus of FIGS. 11 is described. Apparatus including end effector 160 first is disposed within an internal organ, such as the left ventricle, as described hereinabove with respect to FIGS. 7A to 7C.
End effector 160 then is oriented so as to be positioned at a desired angle, e.g. perpendicular, to tissue T to be treated. While end effector 160 is being maneuvered into position, push rod 165 is extended so that distal endface 171 extends past the distal edge of passageway 169, thereby confining pellets 170 within lumen 168. End effector 160 is urged in the distal direction to form needle track N, and so that tip 162 penetrates tissue T until catheter 164 abuts against the endocardium (shown in FIG. 12A) . Push rod 165 then is retracted in the proximal direction, so that distal endface 171 is positioned proximally of the proximal edge of passageway 169. This in turn permits a single pellet 170 to advance through passageway 169 into lumen 166, as shown in FIG. 12B. Because pellets 170 are preferably only slightly smaller than the diameter of lumen 166, when a single pellet 170 has advanced into lumen 166, it will block other pellets from passing through passageway 169 into lumen 166. Alternatively, pellets 170 may be sized so that a predetermined number of pellets pass into lumen 166 each time push rod 165 is retracted proximally.
Push rod 165 then is driven in the distal direction, urging pellet 170 to the end of needle track N, as illustrated in FIG. 12C. If RF electrodes are provided on tip 162, such electrodes may be energized to necrose a predetermined thickness of tissue in the vicinity of tip 162. End effector 160 then is withdrawn, leaving pellet 170 within needle track N in tissue T. As described hereinabove, pellet 170 preferably comprises a biodegradable substance that elutes a suitable bioactive agent into the tissue surrounding the pellet over a preselected period of
time. It is expected that by depositing a bioactive substance within tissue T, tissue revascularization and growth may be stimulated, as described hereinabove. End effector 160 then is moved to another location and the foregoing process repeated to seed a plurality of pellets 170.
While preferred illustrative embodiments of the invention are described above, it will be apparent to one skilled in the art that various changes and modifications may be made therein without departing from the invention, and the appended claims are intended to cover all such changes and modifications that fall within the true spirit and scope of the invention.