Method and apparatus for treating vein graft lesions

Information

  • Patent Grant
  • 6579298
  • Patent Number
    6,579,298
  • Date Filed
    Tuesday, February 29, 2000
    24 years ago
  • Date Issued
    Tuesday, June 17, 2003
    21 years ago
Abstract
A system for ablating material in vein grafts includes an ablation burr that is rotated by a driveshaft. The ablation burr preferably includes one or more channels, blades or other mechanisms that direct ablated material and liquid proximally and/or outwardly against a vessel wall. Aspiration is used to remove ablated material and liquid from the treatment area. Finally, methods for treating vein grafts and original native arteries are disclosed.
Description




FIELD OF THE INVENTION




The present invention relates to medical devices in general, and in particular to catheter ablation systems for revascularizing occluded vein grafts.




BACKGROUND OF THE INVENTION




One of the most commonly used techniques for treating partially or totally occluded cardiac vessels is cardiac bypass surgery. With this procedure, a surgeon obtains a vessel from another portion of the patient's body and grafts the new vessel to healthy sites in the cardiac vessels in order to direct blood flow around a blockage. One of the most common vessels used in bypass surgery is a portion of the saphenous vein, which is a large superficial vein found in the leg. Such grafts are often referred to as saphenous vein grafts or SVGs.




One of the problems with SVGs is that they also tend to become occluded within three to five years of being grafted onto the heart muscle. For some physiological reason which is not completely understood, the material that occludes such grafts tends to be more loosely organized and brittle than the material that occludes native cardiac arteries. As a consequence, treating occluded SVGs can be more difficult because the occluding material tends to break off and can flow downstream wherein it may cause the onset of a heart attack.




One method of treating vein graft lesions is set forth in U.S. Pat. No. 5,681,336 to Clement et al. and assigned to the assignee of the present invention. The '336 patent, which is herein incorporated by reference, discloses a system of ablating vein graft lesions including proximal and distal balloons that isolate the treatment area. In addition, the system provides for the aspiration of ablated material and/or infusion of liquids to maintain vascular pressure. In the '336 patent, the ablation burrs are designed to abrade a lesion in the vein wherein the abraded material can be aspirated through a catheter that extends into the treatment area.




While it is believed that the system described in the '336 patent works well, additional benefits may be obtained using ablation burrs that are optimized for particle aspiration and removal of the type of blocking material found in saphenous vein grafts.




SUMMARY OF THE INVENTION




To improve the treatment of occluded saphenous vein grafts, the present invention comprises a system for aiding in the aspiration of ablated material from a vessel. The system includes a guide wire which is advanced into a treatment area and an ablation mechanism that is routed over the guide wire. The ablation mechanism includes an ablation burr that is rotated by a driveshaft, and a hollow sheath that extends over the driveshaft. The position of the guide wire and ablation mechanism are controlled by an advancer that moves these elements within a patient's vasculature. Rotation of the driveshaft is controlled by a prime mover, typically an electric motor or air turbine. The guide wire, driveshaft and sheath extend through a Y connector. One port of the Y connector is connected to a vacuum source that draws ablated material into a collection jar. The other port of the Y connector is coupled to the advancer.




According to one aspect of the present invention, an ablation burr is designed to propel ablated material proximally into an aspiration lumen. The ablation burr includes one or more channels on the surface of the burr that direct ablated material and fluid in the vessel to the aspiration lumen as the burr is rotated. In another embodiment of the invention, the one or more channels on the burr direct fluid and ablated material and fluid in the vessel proximally and radially outward to provide a scouring action of the interior vascular wall.




In accordance with another aspect of the invention, an ablation burr has a proximal and distal section with the distal section having a point of maximum diameter where the proximal and distal sections meet. The diameter of the distal section tapers down to a distal tip of the burr such that the distal section is ovoidal in shape. The distal section includes one or more channels that direct ablated material and fluid towards an aspiration lumen and/or toward the interior vascular wall. The proximal section comprises a cylindrical tube of a smaller diameter than the maximum diameter of the burr. The cylindrical tube may include one or more spiral channels that direct ablated material toward an aspiration lumen. In accordance with another aspect of the invention, the distal section has a diameter that decreases linearly from the point of maximum diameter to the distal tip such that the distal section of the burr has a conical configuration.




In accordance with another aspect of the present invention, an ablation burr has a diameter that tapers between the point of maximum diameter and the point where the distal section of the burr joins the proximal section. This tapered section includes a number of channels that direct fluids and ablated material towards the interior vascular wall to provide a scouring action in the vessel.




In accordance with another aspect of the present invention, the atherectomy burr fits within a protective shroud. The atherectomy burr has a relatively flat distal face that is covered with an abrasive material. The burr has one or more tapered blades that extend proximally from the distal face that move the ablated material and liquid proximally as the burr rotates.




In accordance with another aspect of the invention, the ablation burr comprises an auger-type bit that cuts occluding material from the vessel and moves it proximally to an aspiration lumen.




In accordance with another aspect of the present invention, the ablation burr is designed as a hub of cutting blades that fit within a canister. The blades are joined at the center of the burr and extend radially outward from a central axis to the inner wall of the canister. A central lumen extends through the point at which the blades are joined so the burr can be passed over a guide wire. Each of the blades includes a tab that fits into a corresponding slot on the canister to secure the blades in the canister.




In accordance with yet another aspect of the present invention, the ablation burr has a “dumbbell” shape having proximal and distal radially expanded portions. Each of the expanded portions moves liquid and abraded material radially outward as the burr is rotated. An aperture positioned between the distal and proximal radially expanded portions is in an area of low pressure so that the aperture acts as an aspiration port to aspirate material through a driveshaft that rotates the burr.




In accordance with yet another aspect of the present invention, the ablation burr has a bell shape with a large central lumen that is expanded at the distal end. A distal rim of the burr is covered with an abrasive material. The central lumen of the burr allows abraded material to be gathered and directed proximally to an aspiration sheath that is positioned near the proximal end of the burr and in fluid communication with the central lumen.




In accordance with yet another aspect of the present invention, the ablation burr includes a series of radial holes that extend into a center lumen of the burr. A vacuum is applied to the center lumen such that occluding material in the vessels is drawn into one or more holes and is sheared off the vessel wall by rotation of the burr. The ablated material may flow through the holes and into the center lumen of the burr where it is aspirated out a center of a driveshaft or may be drawn over the burr into another aspiration lumen.




In accordance with another aspect of the invention, the plurality of holes are coupled to one or more fittings that mate with corresponding lumens in a catheter sheath. The additional lumens are used to aspirate ablated material drawn into the holes and to provide vacuum pressure.




In accordance with yet another aspect of the present invention, an ablation device comprises an outer shell having an abrasive leading surface and a core that fits within the outer shell. Liquid and material disposed between the core and the inner surface of the shell are propelled proximally by the rotation of the core and shell.




In accordance with yet another aspect of the present invention, the ablation burr is maintained at a fixed distance from the distal end of a sheath by a coupler having a threaded end that mates with threads on the distal end of the sheath. The ablation burr is secured to the coupler via a post having a proximal cap with a diameter that is larger than the diameter of a hole at the distal end of the coupler.




The post also includes a distal shaft to which the ablation burr is secured. In accordance with yet another aspect of the invention, an ablation burr includes one or more holes that eject fluid that pumped through a sealed driveshaft radially outward to scour the internal vessel walls in which the burr is being used.




In accordance with yet another aspect of the present invention, a driveshaft that rotates an ablation burr includes a conically shaped section at its distal end. Fluid entering the space between the conically shaped section of the driveshaft and a surrounding sheath is pushed radially outward and proximally by the rotation of the driveshaft thereby aiding in the aspiration of ablated material and liquid from a vessel.




In accordance with yet another aspect of the invention, an expandable sleeve fits within the sheath surrounding the driveshaft. During an ablation procedure, the sheath is extended from the distal end of the sheath and expands to seal the proximal portion of the treatment site and to aid in the aspiration of material from the vessel.




In accordance with yet another aspect of the invention, a method is disclosed for isolating a treatment area by routing a catheter having an inflatable balloon through a native coronary artery to the point where a bypass vessel is attached to the native artery. The balloon is inflated to seal the bypass artery so that ablation can take place without ablated material being pumped downstream.




Finally, the present invention is a method for treating occluded native arteries by routing a catheter having an inflatable balloon through a bypass vessel and into the native artery in order to seal a treatment area such that the original blockage in the native artery can be ablated.











BRIEF DESCRIPTION OF THE DRAWINGS




The foregoing aspects and many of the attendant advantages of this invention will become more readily. appreciated as the same become better understood by reference to the following detailed description, when taken in conjunction with the accompanying drawings, wherein:





FIG. 1

illustrates a system for treating blockages in vein graft according to a currently preferred embodiment of the invention;





FIGS. 2A-2C

illustration alternative ablation burrs constructed in accordance with various aspects of the present invention;





FIGS. 3A-3B

illustrate alternative ablation burrs having a generally flat distal face and a number of blades that move ablated material proximally when rotated in accordance with another aspect of the present invention;





FIG. 3C

illustrates an alternative ablation burr having a convention ellipsoidal distal portion and blades on a proximal portion that move ablated material and fluid proximally when rotated;





FIG. 4

illustrates an auger-type ablation burr that moves ablated material proximally when rotated in accordance with another aspect of the present invention;





FIGS. 5A-5B

illustrate alternative embodiments of a canister burr in accordance with another aspect of the present invention;





FIG. 6

illustrates a “dumbbell”-shaped burr in accordance with another aspect of the present invention;





FIG. 7

illustrates a “bell”-shaped ablation burr in accordance with yet another aspect of the present invention;





FIGS. 8A-8B

illustrate an ablation burr having multiple suction ports in its outer surface in accordance with yet another aspect of the present invention;





FIGS. 9A-9B

illustrate an ablation burr that directs ablated material and liquids proximally in accordance with another aspect of the present invention;





FIGS. 10A-10B

illustrate a coupler that maintains the distance between an ablation burr and an aspirating sheath catheter in accordance with another aspect of the present invention;





FIG. 11

illustrates an ablation burr having fluid ports that direct an infusion fluid towards an interior vessel wall to aid in material removal;





FIG. 11A

illustrates an embodiment of the invention including an occlusion balloon on the distal end of a sheath that is inflated to seal a treatment and;





FIG. 12

illustrates a driveshaft having a conical section near its distal end to pump ablated material and liquid proximally when rotated in accordance with yet another aspect of the present invention;





FIGS. 13A-13B

illustrate two embodiments of an expandable sleeve that fits within a sheath catheter to seal a proximal end of a treatment site in accordance with another aspect of the present invention;





FIG. 14

illustrates alternative multi-lumen catheter designs that may be used with the aspirating ablation system of present invention;





FIGS. 15A-15B

illustrate alternative methods of sealing a bypass vessel or native coronary vessel prior to ablation treatment.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT





FIG. 1

illustrates a system for treating total or partial occlusions in vein grafts according to one embodiment of the present invention. The system


50


includes an ablation burr


52


that is rotated by a driveshaft


54


. The ablation burr


52


and driveshaft


54


are threaded over a guide wire


56


. The majority of the driveshaft


54


is covered by a sheath


58


. The guide wire


56


, driveshaft


54


and sheath


58


extend through a port in a Y connector


60


to an advancing mechanism


62


. The advancing mechanism


62


is used to advance the driveshaft


54


over the guide wire


56


during treatment of a bypass vein graft. In the presently preferred embodiment of the invention, the driveshaft is rotated by an air turbine (not shown) within the advancer


62


. The speed of the turbine is controlled by pressurized air that is regulated by a controller


65


in order to maintain the speed of rotation of the turbine in a desired range.




The Y connector


60


also has a port coupled to a vacuum tube


62


that is in line with a collection jar


64


. A tube


66


connects the collection jar


64


with a vacuum source


68


. The vacuum source


68


applies suction through the vacuum tube


62


and the tube


66


to the sheath


58


that surrounds the driveshaft


54


in order to aspirate ablated material from a treatment area in the patient's body. A valve


70


that is in line with the vacuum tube


62


provides manual control of the level of aspiration at the treatment site.




In operation, a physician makes an incision in the patient, typically in the femoral artery, and routes the guide wire


56


through the patient's vasculature to a point near the occluded vessel. Next, a guide catheter is routed over the guide wire to a point just proximal to the occlusion. The ablation burr


52


and driveshaft


54


are then routed over the guide wire


56


to the point of the occlusion. In some instances, it may be desirable to isolate the treatment area on either side of the occlusion using distal and proximal balloons as disclosed in the '336 patent referenced above.




Once the treatment area is isolated, the driveshaft is rotated at a relatively high speed as controlled by the controller


65


. The physician advances the ablation burr using the advancer


62


such that the ablation burr


52


passes through the occluding material. Abraded material is collected in the collection jar


64


by the vacuum source


68


.




By viewing the debris collected in the collection jar


64


, the physician can determine whether more or less aspiration is required which can be adjusted using the valve


70


. To prevent possible vessel collapse, fluid aspirated from the treatment site should be balanced with fluid infused to the treatment site. Therefore an infusion catheter may be included with the system to replace an amount of fluid equivalent to the amount that is aspirated. Flow meters on the vacuum lines and the infusion catheters may be provided to aid in balancing the infusion/aspiration rates. In addition, a pressure transducer may be positioned at the treatment site to aid in balancing fluid infusion/aspiration.




Once the ablation burr


52


has passed through the occlusion and the treatment is complete, the ablation burr


52


, driveshaft


54


and guide wire


56


are removed from the patient followed by the guide catheter.





FIGS. 2A-2C

illustrate various embodiments of an ablation burr


52


constructed according to the present invention. Unlike conventional ablation burrs that have a relatively uniform outer surface that is covered with an abrasive material, such as diamond grit, the ablation burrs of the present invention are designed to move ablated material and liquid proximally to an aspiration lumen and/or direct fluid in the vessel radially outward towards the interior vessel wall in order to provide a scouring effect as the burr is rotated. As shown in

FIG. 2A

, the ablation burr


80


includes a distal portion


82


and a proximal portion


84


. The proximal portion


84


is a cylinder of a generally uniform diameter which is less than the maximum diameter of the ablation burr


82


. The distal portion


84


of the burr has a maximum diameter at the point where the distal portion


82


meets the proximal portion


84


. The diameter of the distal portion tapers down gradually to the distal tip of the burr such that the distal portion has an ovoidal shape. The ablation burr


80


includes a central lumen


86


through its longitudinal axis in which the guide wire may be routed.




Unlike conventional burrs, the ablation burr


80


includes one or more channels


88


that are machined into the outer surface of the burr that operate to move ablated material and liquid proximally as the burr is rotated by a driveshaft. These channels


88


may extend along the length of the burr. Alternatively, some channels, such as a channel


90


, may extend along only a portion of the length of the burr. In the embodiment shown, the channel


90


begins at approximately the distal tip of the burr and continues proximally for about one third of the length of the distal portion


82


of the burr. The purpose of the truncated channel


90


is to direct fluid and ablated material radially outward as the ablation burr


80


is rotated. The direction of fluid radially outward has the effect of scouring the internal vessel wall to further remove occluding material from the vessel. The area


91


of the distal portion


82


that is between the channels


88


and


90


is coated with an abrasive material such as a diamond grit. As will be appreciated by those skilled in the art, the ablation burr


80


may have all the channels run the length of the burr, have all the channels extend only a portion of the length of the burr, or contain some combination thereof.





FIG. 2C

shows another alternative embodiment of an ablation burr according to the present invention. Here, the ablation burr


92


includes a distal portion


94


and a proximal portion


96


. The distal portion


94


has a point of maximum diameter


98


which tapers gradually to the distal tip


100


of the burr. The difference between the burr


92


shown in FIG.


2


C and the burr


80


shown in

FIG. 2A

is that instead of the diameter of the burr changing sharply where the distal portion of the burr meets the proximal portion, the diameter decreases gradually in an area


102


that joins the proximal and distal portions of the burr. This area


102


includes one or more channels


104


that operate to direct fluid radially outward as the burr


92


is rotated. Again, the burr may include a number of channels


104


that extend the entire length of the burr or channels


106


that extend a portion of the length of the burr to direct ablated material proximally towards an aspiration lumen and/or radially outwards. An outer surface


108


of the distal portion


94


of the burr is preferably coated with an abrasive material to abrade deposits in the vein graft.





FIG. 2C

shows yet another embodiment of an ablation burr


120


according to the present invention. The ablation burr


120


includes a distal portion


122


and a proximal portion


124


. The proximal portion


124


is a cylinder having a uniform diameter whereas the distal portion


122


has a point of maximum diameter where the distal portion


122


meets the proximal portion


124


. The diameter of the distal portion


122


decreases linearly to the distal tip


128


of the burr thereby providing the distal portion


122


with a generally conical shape. The outer surface


130


of the distal portion of the burr is coated with an abrasive material in order to abrade material in the vessel as the burr


120


is rotated.




As with the burrs shown in

FIGS. 2A and 2B

, the ablation burr


120


includes one or more channels


132


,


134


in the outer surface


130


of the burr. In this embodiment, each of the channels along the outer surface of the burr is relatively straight, however, spiral channels could also be used.





FIGS. 3A-3B

illustrate an alternative ablation burr


140


according to another aspect of the present invention. The ablation burr


140


is designed to remain within a protective shroud or sheath


142


secured to the distal end of the guide catheter


144


. The ablation burr


140


has a distal portion


146


and a proximal portion


148


. The proximal portion


148


comprises a cylinder having a diameter that is smaller than the maximum diameter of the distal portion


146


. The distal portion


146


comprises a disk with a diameter larger than that of the proximal portion and a flat distal surface


150


. The flat distal surface


150


has an abrasive coating thereon that abrades occluding material from the vessel as the ablation burr


140


and guide catheter


144


are advanced through the vessel. Extending proximally from the flat distal surface


150


are one or more blade surfaces


152


. The blade surfaces


152


act as propellers to push liquid and ablated material from the distal surface


150


towards an aspiration lumen which is located near the proximal end of the burr. In the embodiment of the invention shown in

FIG. 3A

, the aspiration lumen is formed between the guide catheter


144


and a sheath


156


that surrounds a driveshaft


158


that rotates the ablation burr


140


.





FIG. 3B

shows an alternative embodiment of the ablation burr shown in FIG.


3


A. The ablation burr


170


includes a proximal portion


172


and a distal portion


174


. The proximal portion


172


is a cylinder having a radius that is smaller than the maximum radius of the ablation burr


170


. The distal portion


174


comprises a disk having a flat distal surface


176


that may include an abrasive material to abrade occluding matter from a vessel as the ablation burr


170


is rotated. The ablation burr


170


includes three serpentine blade surfaces


178


,


180


,


182


that extend from the distal surface


176


to the point where the proximal portion


174


of the burr meets the distal portion


172


of the burr. Each of the blade surfaces


178


,


180


,


182


operates to move ablated material proximally as the ablation burr


70


is rotated by a driveshaft.




The ablation burr


170


may include a central lumen


184


so that the ablation burr can be routed over a guide wire (not shown) if desired.





FIG. 3C

illustrates yet another embodiment of an ablation burr according to the present invention. The ablation burr


185


has an ellipsoidal distal half


186


that is covered with an abrasive material. A proximal section


187


comprises a generally cylindrical section having a diameter less than the diameter of the proximal section


186


. A drive shaft (not shown) is secured to the proximal section


187


to rotate the burr. The proximal section


187


includes a number of blades


188


disposed around the cylindrical section. Each blade has a radius that is less than the radius of the distal section


186


. In operation, the distal section remains outside a surrounding sheath while the blades


188


remain in the sheath and move ablated material and liquid proximally when the burr


185


is rotated by the drive shaft.





FIG. 4

illustrates an alternative embodiment of an ablation burr according to the present invention. The ablation burr


190


has a generally “auger”-shaped configuration with a proximal portion


192


and a distal portion


194


. The proximal portion


192


comprises a cylinder having a maximum diameter that is less than the maximum diameter of the distal portion


194


. The distal portion generally comprises a cylinder having a radius larger than the radius of the proximal portion


192


and a channel


196


that spirals along the length of the distal portion


194


. The channel


196


operates to move ablated material and liquid proximally as the burr


190


is rotated. If desired, at least a portion of the leading surface of the ablation burr


190


is coated with an abrasive material to aid the removal of occluding material from the vessel as the ablation burr


190


is rotated.





FIGS. 5A and 5B

show alternative embodiments of an ablation burr according to the present invention. As shown in

FIG. 5A

, an ablation burr


200


comprises a cylinder


202


having generally smooth sides and a tapered proximal end


204


into which a driveshaft is secured. A blade cluster


206


is fitted within the cylinder


202


. The blade cluster


206


comprises a series of generally flat blades


208


that are equally spaced around and extend radially outward from a central lumen


210


. The proximal end of the blades


208


has a diameter selected to engage the inner wall. of the canister


202


. Each of the blades


208


also include an outwardly extending notch that fits within a corresponding slot


214


on a distal rim of the canister


202


. The distal end of the blades


208


extend outwardly from the distal end of the canister


202


and taper down to the distal end of the blade cluster. With the blade cluster


206


secured in the canister


202


via an adhesive or by welding, the blade cluster


206


divides the interior lumen space of the canister


202


into a series of longitudinally extending sections through with particles may be aspirated. If desired, the outer surface of the blades that extend from the distal end of the canister


202


may include an abrasive material to aid in ablating material from a vessel lumen.





FIG. 5B

shows an alternative embodiment of the ablation burr shown in FIG.


5


A. Again, the ablation burr includes a canister


202


in which a blade cluster


220


is inserted. The blade cluster includes a number of radially extending blades


222


that are equally spaced around a central lumen


224


. The difference between the blades


222


shown in FIG.


5


B and the blades


208


shown in

FIG. 5A

is that the distal end of the blades do not extend as far from the distal end of the canister


202


.





FIG. 6

shows yet another embodiment of an ablation burr according to the present invention. The ablation burr


240


comprises a “dumbbell”-shaped device comprising a distal lobe


242


and a proximal lobe


244


wherein the distal lobe and proximal lobe are joined by a center section


246


. An aspiration port


248


within the center section


246


is in fluid communication with a lumen that extends through the burr


240


and provides a port through which ablated particles can be aspirated. In a current embodiment of the invention, the burr


240


is rotated by a sealed driveshaft


250


connected to the proximal end of the burr. Particles and fluid aspirated into the port


248


are carried in a lumen within the sealed driveshaft to a collection jar that is external to a patient. If desired, a portion of the distal lobe


242


may be coated with an abrasive


252


to aid in ablating material from a vessel lumen. It is believed that when rotated, each of the bulbs


242


,


244


will push liquid radially outward towards a vessel wall thereby creating a region of high pressure. The center section of the burr area


246


between the distal and proximal bulbs forms an area of low pressure such that ablated material and liquid will be drawn into the aspiration port


248


for removal from the vessel.





FIG. 7

illustrates another embodiment of an ablation burr


260


according to the present invention. The ablation burr


260


comprises a “bell”-shaped tube having a large central lumen that expands in diameter at a flared distal end


262


of the burr. A proximal end


264


of the burr comprises a cylinder having a diameter less than the maximum diameter of the distal end


261


of the burr. The proximal end


264


is designed to be coupled to a driveshaft that rotates the burr. The proximal end


264


of the burr is coupled to the distal end by two of more legs


268


. Spaces between the legs


268


expose the lumen in the center of the burr. In operation, the majority of the distal end


261


fits within a surrounding guide catheter


272


. Only the flared distal end


262


of the ablation burr extends from the distal end of the guide catheter. The leading surface of the distal end


262


may be coated with an abrasive or other material to aid in removing matter form the vessel lumen. In operation, when a vacuum source is connected to the maximal end of the burr, aspirated particles are drawn into the flared end and through the interior lumen of the burr where they are carried away by an aspiration lumen.





FIGS. 8A and 8B

show yet another alternative embodiment of an ablation burr according to the present invention. The ablation burr


280


comprises a conventional ellipsoidal shaped burr having a central lumen


282


disposed therein in which the driveshaft is fitted to secure it to the burr. In addition, a guide wire can be routed through the central lumen


282


and out the distal end of the burr. A plurality of holes


284


are positioned around the outer surface of the distal half of the burr. Each hole extends from the outer surface of the burr into the central lumen. When used with a sealed driveshaft to rotate the burr, vacuum is applied and obstructing material is drawn into the holes


284


, while the rotation of the ablation burr causes particles to be sheared off from the vessel wall. The ablated particles may be drawn into the central lumen


282


of the ablation burr


280


and aspirated out the center of the hollow driveshaft. Alternatively, the particles may be aspirated outside of the driveshaft.




An alternative to the embodiment shown in

FIG. 8A

is the ablation burr


290


shown in FIG.


8


B. Again, the ablation burr includes a hollow lumen


292


in which the driveshaft is secured and through which a guide wire can be extended. In this embodiment, the holes


294


on the outside surface of the distal half of the burr extend radially inward to a pair of inner lumens


296


that extend along the length of the burr but are radially displaced from the central lumen


292


. Each of the lumens


296


terminates at a fitting


298


that fits within a corresponding lumen


300


of a connected catheter


302


. Vacuum is applied to the lumens


300


so that aspirated particles are drawn through these lumens instead of the central lumen of the catheter through which the driveshaft extends. Using this embodiment, the catheter


302


rotates with the ablation burr


290


as the burr is used in the vessel.





FIG. 9A

shows yet another alternative embodiment of an ablation burr according to the present invention. The ablation burr


310


comprises an outer shell


312


and an inner core


314


. The outer shell


312


comprises a generally cylindrical proximal section


311


and a distal section


315


which tapers in diameter to form an ovoidal tip. The tapered section may be covered with an abrasive or other material that aids in ablating material from a vessel wall. At the distal end of the burr is an opening


332


that is larger than the diameter of a guide wire (not shown) over which the burr may be routed. The inner core


314


comprises a cylindrical proximal section


316


, and a tapered nose section


318


having a lumen


320


disposed therein, through which a guide wire can be passed. The nose section


318


may also be covered with an abrasive grit on its outer surface. The diameter of the nose section


318


is substantially smaller than the diameter of the proximal section


316


. The nose section


318


is joined to the cylindrical proximal section


316


via a concave transition region


322


having a number of holes


324


disposed around its circumference.




The proximal section


316


of the core is secured to the inner diameter of the proximal section


311


of the shell


312


such that both the core and shell rotate together with a driveshaft that is secured within the inner core.




As shown in

FIG. 9B

, when the burr


310


is rotated by a sealed driveshaft


330


, fluid enters the opening hole


332


at the distal end of the shell. Fluid and ablated material are pushed radially outward when forced between the tapered nose section


318


and the inner wall of the distal section


315


of the outer shell


312


.




The fluid and ablated material are forced through the holes


324


and proximally through a sealed driveshaft


330


.




In some instances, it may be desirable that an ablation burr remain a fixed distance from the distal end of a sheath that surrounds the driveshaft. In that case, a coupler as shown in

FIGS. 10A and 10B

can be used. The coupler


350


comprises a generally cylindrical rod having a threaded proximal end


352


that mates with corresponding threads on the distal end of a sheath


372


or to another securing mechanism. The coupler


352


is generally hollow and includes one or more aspiration ports


354


along its length so that aspirated material can be drawn into the coupler. The coupler has a hole


356


at its distal end with a diameter that is less than the inner diameter of the coupler section


350


.




To secure the ablation burr to the coupler, a post


360


is provided. The post has a lumen therein in which a driveshaft is secured. The post


360


has a shaft


362


having a diameter that will fit through the hole


356


at the distal end of the coupler. A proximal cap end


364


of the post


360


has a diameter that is greater than the diameter of the hole


356


in the distal and of the coupler such that the proximal end of the post forms a bearing surface with the inner surface of the end of the coupler section. When the post


360


is inserted into the coupler, the shaft


362


extends out of the hole


356


and an ablation burr


370


is secured to the shaft


362


. As shown in

FIG. 10A

, the coupler


350


is threaded onto the end of a sheath


380


. Vacuum applied to the sheath


372


draws material in through the aspiration ports


354


and down the passageway extending on the outside of the driveshaft and the inside of the sheath


380


.




In some instances, it may be desirable to infuse liquid into the treatment area. Such liquid may be infused either to maintain vessel pressure or to aid in the removal of material from a vessel wall. In that case, an ablation burr of the type shown in

FIG. 11

may be desirable. The ablation burr


380


includes a central lumen


382


and one or more ports


384


in fluid communication with the central lumen


382


. The ports


384


are directed radially outward and to the rear of the burr. When rotated by a sealed driveshaft, liquid can be pumped through the driveshaft and out the ports


384


. Fluid jets exiting the ports


384


aid in the removal of material


386


disposed on the vessel wall.




To prevent the infused liquid from being forced out the distal end of the burr, the hole at the distal end of the burr is only slightly larger than the diameter of the guide wire that extends through the hole.




To aid in the aspiration of the ablated material


368


, a sheath


390


may surround the driveshaft. The distal end of the driveshaft may include a flared section


392


that expands radially outward to seal the vessel and aid in guiding ablated material into the aspiration lumen. The flared section


392


can be made of flexible polymeric material. Metallic mesh or wires can be used to support the flared section. The flared section


392


is attached to the distal end of the aspirating sheath. This flared section is either folded against the sheath


390


or extended forward of the sheath when pushed through the guiding catheter. It will expand radially once it exits the guiding catheter to aid aspirating. Another design to aid aspirating is to use an occlusion balloon instead of the flared section. As shown in

FIG. 11A

, an occlusion balloon


393


is mounted on the distal tip of the sheath


390


. The balloon


393


can be inflated to block the vessel once the sheath


390


is situated in the vessel.




Another mechanism for aiding in the aspiration of ablated material from a vessel is shown in FIG.


12


. Here, an ablation burr


400


is disposed over a guide wire


402


. The ablation burr


400


is driven by a driveshaft


404


having a conical, tapered section


406


near the distal end of the driveshaft. The conical section


406


expands in diameter from a point near the ablation burr and extending in the proximal direction. At the proximal end of the conical section


406


, the diameter of the driveshaft returns to the diameter of its distal tip. The conical section


406


is preferably secured to a conventional driveshaft with a hypo tube coupler


414


. A guide catheter


408


surrounding the driveshaft has a similarly shaped tapered section


410


that surrounds the conical section


406


of the driveshaft. Liquid entering the area between the conical section


406


of the driveshaft and the tapered section of the guide catheter


408


is pushed radially outward by the movement of the driveshaft, thereby forcing the liquid proximally where it can be aspirated either through a sheath


410


surrounding a proximal portion of a driveshaft


412


, or in the lumen created between the sheath


410


and the guide catheter


408


.




To aid in the movement of ablated material proximally, the inner surface of the sheath


410


may include spiral channels


416


or other mechanisms such as blades, etc. that aid in directing ablated material and liquid proximally along the length of the lumen created between the outside of the sheath


410


and the inside of the guide catheter


408


. Alternatively, the inside walls of the guide catheter


408


may include spiral channels (not shown) to aid in the movement of ablated material proximally if the catheter is used with a sealed driveshaft or other catheter that rotates within the guide catheter


408


.




As indicated above, it is sometimes necessary to seal the proximal end of a treatment area in order to guide ablated material into an aspiration lumen or prevent it from escaping in the bloodstream. As shown in

FIG. 13A

, a sheath


420


surrounds an ablation burr


422


that is driven by a driveshaft


424


. Disposed between the sheath


420


and the driveshaft


424


is a lining


426


having a distal end that expands radially when advanced out the distal end of the sheath


420


. The expanded end of the lining


426


seals against the vessel wall in which the sheath is located in order to prevent ablated material from flowing proximally and to guide such ablated material into an aspiration lumen. The lining


426


is composed out of thin flexible polymer film


427


with resilient frame


428


. The frame


428


can be made as a group of parallel strands as shown in

FIG. 13A

, or as a net


429


as shown in FIG.


13


B. In closed state, lining


426


is collapsed within the sheath


420


. Once the lining


426


is extended from the tip of the sheath


420


, the frame


428


or net


429


causes expansion of the lining


426


.




In most of the examples described above, the aspiration lumen comprises the space between the driveshaft and the surrounding sheath. However, in some instances, it may be desirable to use a multi-lumen sheath. One lumen is used to route the guide wire and driveshaft of the ablation burr. Another lumen is used for aspiration.

FIG. 14

shows cross-sections of three different multi-lumen catheters designs that can be used in accordance with the present invention. A catheter


440


includes a large lumen


442


and a smaller lumen


444


. Either lumen can be used for aspiration or routing the ablation driveshaft and guide catheter.




A catheter


450


is divided in the middle by a median strip


452


. The center of the median strip


452


is slightly larger to accommodate a central lumen


454


through which a guide catheter and/or driveshaft can be routed. The lumens created on either side of the median strip


452


can be used for aspiration or fluid infusion.




A catheter


460


has a central lumen


462


that is disposed on a post


464


that extends from the inner wall of the catheter


460


. Each of the catheter designs shown in

FIG. 14

can be extruded using known techniques. With a multi-lumen design, both aspiration and infusion can be used to maintain fluid pressure during the treatment process.




As indicated above, it is sometimes necessary to isolate a treatment area prior to ablating material from a vein graft.

FIG. 15

shows one technique whereby a balloon catheter can be routed through a native coronary vessel


500


. When positioned at the junction of the bypass vessel


502


and the native vessel


500


, the balloon


504


can be expanded to seal the distal end of the bypass vessel. With the distal end sealed, treatment can take place whereby ablated material is drawn into an aspiration lumen


506


within the vessel being treated.




An alternative approach to the treatment of coronary vessels is to route a balloon catheter through the bypass vessel


502


and distal to an original blockage


510


within the native coronary vessel


500


. Using more modern techniques such as atherectomy, it is now possible to treat the original blockages that may not have been treatable when the bypass vessel was installed. A balloon


504


on the distal end of the balloon catheter is inflated distal to the original blockage, an ablation burr or other medical device is advanced through the original blockage


510


. Depending upon the likely composition of the blockage material, the ablated material can be aspirated in the manner described above. With the original blockage treated, it is possible that the patient would have two vessels through which blood can flow to the heart muscle.




While the preferred embodiment of the invention has been illustrated and described, it will be appreciated that various changes can be made therein without departing from the scope of the invention. It is therefore intended that the scope of the invention be determined from the following claims and equivalents thereto.



Claims
  • 1. An ablation burr for removing deposits from a patient's vessel, comprising:a burr body adapted to be rotated by a driveshaft, at least a portion of the burr body having an abrasive surface; the burr body further including a lumen extending at least partially through the burr body, a proximal and distal radially expanded portion and a middle region between the distal and proximal radially expanded portion having a diameter that is everywhere less than the diameter of the proximal and distal portion, the middle region further including an aspiration port in fluid communication with the lumen in the burr body.
  • 2. The ablation burr of claim 1, wherein the drive shaft that rotates the burr body is sealed.
  • 3. The ablation burr of claim 1, wherein the burr body creates a low pressure region adjacent to the aspiration port as the burr body is rotated in a vessel.
  • 4. A method of removing deposits from a vessel in a patient's body, comprising:advancing an ablation burr into a vessel, the burr having a burr body at least a portion of which has an abrasive outer surface, a lumen extending at least partially therethrough, a proximal and a distal radially expanded portion, a middle region between the proximal and distal radially expanded portion having a diameter that is everywhere less than the diameter of the proximal and distal radially expanded portion and an aspiration port within the middle region that is in fluid communication with the lumen; rotating the ablation burr with a driveshaft; engaging the rotating burr with deposits in the vessel; and aspirating ablated deposits through the aspiration port.
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