Patent Abstract:
A vascular filter guide wire is disclosed for directing precision placement of a cur proximate a blood vessel lesion and filtering particulate matter dislodged by treatment of the vessel. The guide wire includes an actuating mechanism, an elongated flexible core wile having a proximal end mounted to the actuating mechanism and a distal end for insertion through a vasculature to a position downstream of the restriction. A tubular flexible shaft is slidably disposed telescopically along the core wire and includes a proximal portion affixed to the actuating mechanism in movable relation to the core wire. The guide wire includes a collapsible filter at its proximal end to the distal portion of the shaft and, at its distal end, to the core wire. The filter deploys radially in response to axial moment of the core wire relative to the shaft so that it can trap particulate matter arising from treatment of the lesion.

Full Description:
This is a continuation of International Application Ser. No. PCT/US98/23516, filed Nov. 3, 1998. 
    
    
     FIELD OF THE INVENTION 
     The invention relates to vascular filters intended to capture embolic particles, by means of filtration, that may arise from the treatment of diseased blood vessels. 
     BACKGROUND OF THE INVENTION 
     Percutaneous intravascular treatment of diseased blood vessels, such as angioplasty or stent placement procedures, may result in the dislodgment of loose plaque or thrombus which then migrate downstream. Since any such particles may become lodged in other vessels, effectively preventing blood from passing into a the organ which that vessel supplies, and potentially causing serious end-organ damage which may be difficult or impossible to reverse, effective avoidance of this complication is extremely important. 
     One of the early methods of removing residual matter resulting from an angioplasty procedure using a balloon catheter involved maintaining the balloon in an inflated state while performing the intended intervention on the blood vessel. In this manner, much of the material could be removed without an extraneous filtering device. However, the reliability of such a procedure, especially for blood vessels supplying oxygen to the brain, necessitated substantial improvement. 
     Previous attempts at vascular filters have included a vena caval filter, which is permanently deployed in the vena cava via a peripheral vein in order to prevent embolisation of blood clots from the veins of the legs to the lungs, thus avoiding potentially serious and life threatening pulmonary embolism. The filter typically included a plurality of anchoring legs bent outwardly to form hooks to penetrate the vessel wall and secure the filter permanently in position. An example of such a device is disclosed in U.S. Pat. No. 4,619,246. 
     While conventional vena caval filters work well for their intended purposes, they suffer from the disadvantages associated with damaging the inner vessel wall through the inherent penetrating nature of the hooks, and blockage caused over time as the filter becomes endothelialized with the blood vessel inner wall or as recurrent blood clots obstruct blood flow through the filter. 
     In an effort to resolve the problems with vena caval filters, those skilled in the art have developed temporary filtering mechanisms that attach to an angioplasty catheter and withdraw from the vasculature following the procedure. One proposal, disclosed in U.S. Pat. No. 4,723,549, discloses a collapsible wire mesh filter disposed around the distal portion of a wire guided balloon catheter. A filter balloon is positioned beneath the wire mesh and inflates radially outwardly to expand the wire mesh when inserted downstream of a stenosed blood vessel. As the vessel is treated, fine particles dislodged from the stenosis are trapped by the mesh and subsequently removed with the filter and catheter following the procedure. 
     A similar device and method, disclosed in U.S. Pat. No. 4,873,978 includes a balloon catheter directed through a vasculature by a guide wire. The catheter mounts a strainer at its distal end that responds to actuation of a separate control wire to open and close a plurality of tines capable of retaining dislodged particles from a treated stenosis. 
     The temporary filter devices described above require additional lumens and/or control wires beyond those associated with the catheter guide wire to control the filtering procedure. The extra lines and wires typically create added complexity for the operator. Moreover, it is often desirable to adjust the relative spacing between the deployed filter and the stenosed area due to the potential presence of additional blood vessels proximate the stenosis. Because the conventional filters are mounted to the distal ends of the respective catheters, adjustments during the procedure typically cannot be made. Furthermore, the use of balloon catheters and stent devices involving the same procedure could not be achieved with filter protection in place. 
     Therefore, a need exists in the art for a temporary vascular filter which does not require additional control wires and catheter lumens. Moreover, the need exists for such a filter in which adjustment of the filter with respect to a lesioned vessel area, and allows for the exchange of various types of devices (e.g., balloon catheters, stents, etc.), while maintaining protection against distal emboli. The temporary vascular filter guide wire of the present invention satisfies these needs. 
     SUMMARY OF THE INVENTION 
     The apparatus and method of the present invention minimizes the complexity associated with manipulating a vascular filter during an angioplasty or stent placement procedure by incorporating the filter on a catheter guide wire such that the guide wire performs the dual functions of guiding the catheter to a stenosed location, and filtering dislodged particles flowing downstream of the treated area. Moreover, because the guide wire operates independently of the catheter, relative spacing between the filter and the lesion location may be easily altered, and exchanges of various devices over the wire are possible. 
     To realize the advantages described above, the invention, in one form, comprises a vascular filter guide wire for directing precision placement of a catheter or stent proximate a lesion and selectively filtering particulate debris dislodged by treatment. The guide wire includes an actuating mechanism and an elongated flexible core wire having a proximal end mounted to the actuating mechanism and a distal end for insertion through a vasculature to a position downstream of the lesion. A tubular flexible shaft is slidably disposed telescopically along the core wire. The shaft includes a proximal portion affixed to the actuating mechanism in movable relation to the wire proximal end, and a distal portion disposed inwardly from the core wire distal end for placement downstream of the lesion. A collapsible strainer coupled to the shaft distal portion is operable, in response to relative displacement between the shaft and the core wire, to radially extend outwardly within the vasculature so that it can trap particulate matter arising from the treatment of the lesion. 
     In another form, the invention comprises a catheter system for treating a lesion within the vasculature. The catheter system includes a catheter having a lesion treatment device and a vascular filter guide wire for directing the catheter to the lesion. The guide wire includes a collapsible filter for deployment downstream of the catheter to trap particulate matter dislodged from the lesion during the treatment. 
     In yet another form, the invention comprises a method of filtering particulate debris from a vasculature caused by treatment of a lesion with a catheter having a lesion treatment portion, the catheter being guided to the location of the lesion by a vascular filter guide wire having a core wire, a slidable shaft, and a collapsible filter mounted on the shaft and deployable upon relative displacement between the core wire and the shaft. The method includes the steps of first guiding the vascular filter guide wire through the vasculature along a predetermined path to a lesion such that the filter is disposed downstream of the lesion. The next step involves deploying the filter radially outwardly by shifting the shaft relative to the core wire. Then, the catheter is run over the guide wire along the predetermined path to position the lesion treatment portion of the catheter proximate the lesion. The method continues by treating the lesion according to a predetermined procedure then maintaining the filter in a deployed position until the risk of particulate matter is substantially eliminated. The catheter is then withdrawn from the vasculature and the filter retracted radially inwardly by shifting the shaft back to the original position. The method then concludes with the step of removing the guide wire from the vasculature. 
     One embodiment of the invention comprises a vascular filter for controllably expanding within a blood vessel to trap particulate matter loosened from treatment of a lesion. The filter is responsive to relatively shiftable control elements to expand and retract and includes a braid comprising a composite metallic/polymeric material. The material includes a plurality of metallic filaments mounted to the respective shiftable shaft and core wire to define a support structure and a polymeric mesh interwoven with the metallic filaments to define a strainer. 
     Another form of the invention comprises a method of fabricating a vascular filter. The method includes the steps of first selecting a mandrel having a plurality of consecutively connected forms and weaving a continuous layer of braid over the consecutively connected forms. The method proceeds by bonding the braid filaments at spaced apart sections between respective forms and separating the respective braided forms at the bonded sections. The forms are then removed from the layer of braid. 
    
    
     Other features and advantages of the present invention will be apparent from the following detailed description when read in conjunction with the accompanying drawings. 
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is an enlarged, partial sectional view of a catheter system of the present invention deployed within a blood vessel; 
     FIG. 2 is a partial longitudinal view of a guide wire in a retracted position according to a first embodiment of the present invention; 
     FIG. 3 is a partial longitudinal sectional view along line  3 — 3  of FIG. 2; 
     FIG. 4 is a partial longitudinal sectional view similar to FIG. 3 but in a deployed orientation; 
     FIG. 5 is an enlarged view of detail  5 — 5 ; 
     FIG. 6 is a longitudinal view of a filter construction according to an alternative embodiment of the present invention; 
     FIG. 7 is a longitudinal view of a filter construction according to yet another embodiment of the present invention; 
     FIG. 7 a  is a cut-away portion of the FIG. 7 filter construction which illustrates longitudinal pleats, according to the FIG. 7 embodiment of the present invention; 
     FIG. 8 is a mandrel system for use in the method of the present invention; 
     FIG. 9 is a block diagram illustrating steps in preparing the mandrel of FIG. 8; 
     FIG. 10 is a block diagram illustrating steps in fabricating the filter of the present invention; 
     FIGS. 11 a - 11   g  are views of various stages of construction corresponding to the steps of FIG. 10; 
     FIG. 12 is a partial longitudinal sectional view of a guide wire in a retracted state according to a second embodiment of the present invention; 
     FIG. 13 is a partial view of the guide wire of FIG. 12 in an extended state; 
     FIG. 13 a  is an alternative embodiment of the FIG. 13 which is frusto-conical in shape, according to an alternative embodiment of the present invention; 
     FIG. 14 is an axial view along line  14 — 14  of FIG. 13; 
     FIG. 15 is an axial view similar to FIG.  14  and showing an alternative strut arrangement; and 
     FIG. 16 is an axial view similar to FIG.  14  and showing an alternative strut arrangement. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     With reference to FIG. 1, percutaneous angioplasty or stent placement techniques enable operators to minimize trauma often associated with more invasive surgical techniques. This is possible through the use of a thin catheter  20  that advances through the vascular system to a predetermined blood vessel  22  having a lesion such as a stenosis  24  blocking the flow of blood therethrough. Typically, the catheter includes a lesion treatment device such as a balloon  26  or stent (not shown) for positioning coaxially within the lesion. Once positioned, the balloon or stent radially expands, as shown at  28 , to exert a radially outwardly directed force against the material and initiate dilation thereof. 
     In order to reach the lesioned area, however, the catheter must be able to follow a trackable path defined by a catheter guide wire. In accordance with a first embodiment of the present invention, a catheter guide wire, generally designated  30 , provides a trackable path for a catheter and includes a distally disposed collapsible filter  50  to trap particulate matter dislodged by the catheter  20  during treatment of the stenosis. 
     Referring now to FIGS. 2 through 5, the guide wire  30  includes a proximal section  32  comprising a solid core wire  34  having a wave-shaped proximal end  36  (FIG.  2 ). A tubular shaft  38  is coaxially disposed around the core wire and includes an outer diameter equal to the nominal size of the guide wire. The inner diameter of the tube is sized to form a friction fit with the core wire proximal end when slid thereover during insertion and removal of the guide wire. The shaft functions to deploy and retract the filter device, and to guide and support the catheter  20 , and to smoothly transmit rotation from the proximal section  32  to an intermediate section  40 . Preferably, the shaft comprises a polyimide tube or hypotube. In some applications, where relatively long lengths are required, an extension (not shown) may be attached to the proximal section to increase the length up to three meters. 
     The intermediate section  40  extends axially from the proximal section  32  and generally comprises an extension of the shaft  38  to coaxially surround the core wire  34 . The core wire is formed distally with a primary tapered portion  42  defining an annular shoulder  44  for mounting a coiled spring  46 . 
     With further reference to FIGS. 2 through 5, the filter  50  comprises a braided basket  52  having respective inner and outer braid layers  54  and  56  (FIG. 5) that, in one embodiment, serve as supports for a fine filter mesh  58 . The supports expand the basket radially outwardly with the filter axial ends compressed inwardly, and radially retract the basket with the ends tensioned outwardly. The fine mesh  58  (FIG. 5) is interposed between the inner and outer supports along a distal-half portion  60  of the basket to prevent particulate matter from flowing through the blood vessel downstream of the treated stenosis. It is contemplated that the size of the pores of mesh  58  may be in the range of 40 to 500 microns. The meshed distal-half of the filter forms a collection cavity  62  for the material such that when retracted, the material is prevented from escaping the filter. 
     The proximal end of the filter basket is bonded (e.g. adhesively or by soldering) to the shaft  38  which may be inserted between braid layers  54  and  56 . 
     The distal extremity  57  of basket abuts a flexible  30  coil spring  66  that coaxially surrounds the tip of the core wire  34 . The guide wire distal tip is tapered and terminates in a hemispherically shaped tip  72  which is also bonded (e.g. by soldering) to the tip. The guide wire distal tip may be preformed into a “J” configuration (not shown) to aid in advancing the guide wire  30  through the vasculature. 
     With particular reference to FIG. 6, the preferred embodiment of filter  50  according to the present invention includes a braid comprising a composite metallic/polymeric material, eliminating the necessity of a separate mesh layer. In such an embodiment, a plurality of metallic filaments  82  provide structural support to the assembly for deploying and collapsing the filter. Polymeric filaments  84  are located on the distal half of the braid only, to provide a filtration cone  86 . The dual materials, braided simultaneously, provide a pic density which will result in filtration spacing of approximately 40 to 500 microns for filtration, at a metal to polymeric ratio of approximately 1:4. 
     In yet another embodiment of a filter according to the present invention, generally designated  90  and illustrated in FIG. 7, the filtering medium is wrapped in a cylinder  92  with a closed distal end  94  and a flared proximal end  95 . Flaring of the proximal end may be effected by applying heat and pressure to the material thereby increasing the surface area and causing the material to bow radially outwardly. The cylinder is formed with longitudinal pleats  93  (shown in FIG. 7 a ) that are more flexible and collapsible than a straight cone configuration. 
     Referring now to FIGS. 8 and 9, fabrication of the filter  50  may be performed in accordance with a series of process steps as described below. Initially, a mandrel  96  (FIG. 8) with a series of molded forms  97  and  98  is prepared by selecting a mandrel of appropriate length, at step  100  (FIG.  9 ), and providing a plurality of crimps  101  (FIG. 8) on the mandrel at intervals of approximately two to three inches, at step  102 . The process proceeds by placing molds over the crimps, at step  104 , filling the molds with a dissolvable compound, at step  106 , curing the compound, at step  108 , and removing the molds, at step  110 . Suitable materials for molding include water soluble plastics such as polyethylene oxide, chemical soluble plastics such as styrene or PVC, and other water soluble materials such as sugar cubes, or gypsum based compounds. Molded forms may be continuously fabricated along the length of the crimped mandrel sections to maximize production efficiency. Another suitable method envisioned is to individually form the molds and bond to straight mandrels. 
     Referring now to FIGS. 10 and 11 a-g , following preparation of the mandrel  96 , the mandrel itself is selected for the method of fabricating the filters, at step  112 . The method progresses by selecting a braider, at step  114 , and braiding the inner layer  54  (FIG. 11 a ), at step  116 , over the mandrel form system. Because of the convenient serially connected system of forms on the mandrel, the braider progressively weaves a continuous layer of braid over the consecutively connected forms. After the braid is applied, the mandrel is removed from the braider, at step  118 , so that a curable epoxy may be applied to define an adhesive joint  119  (FIG. 11 b ) along spaced apart sections of the braid between forms. This step bonds braid filaments together, at step  120 , so that subsequent separation of the forms minimizes deformation of the braid. 
     A center section  121  (FIG. 11 c ) of each braid is then cut, at step  122 , and a prefabricated filter  123  (FIG. 11 d ) installed over one side of each form, at step  124 . The individual segments are then reconnected, at step  126 , by splicing a section of heat shrink tubing  127  (FIG. 11 e ) over each severed joint. 
     After the segments are re-connected, the mandrel assembly is then re-installed into the braider for braiding of the outer basket  56  (FIG. 11 f ), at step  128 . Following braiding, the mandrel is removed from the braider, at step  130 , with the braid filaments bonded together to form a joint  131  (FIG. 11 g ), at step  132 . The mandrel is then cut at approximately one millimeter on the outside end of the adhesive, at step  134 . At this point, the molded form may be dissolved by an appropriate solvent, at step  136 , and the mandrel removed, at step  138 . Lastly, a polyimide sleeve is bonded, at step  140 , to the end opposite the filter. 
     The alternative filter embodiment  80  may be fabricated similar to the procedure above with only minor variations. Conveniently, because of the composite nature and relatively high pic density of the metallic/polymeric braid, only one braiding step is required. After the final braid, the polymeric strands at the proximal end are mechanically or thermally cut away, and the filaments fused at the large diameter of the formed cone to form the collection cavity and to allow for greater blood flow. 
     In operation, the guide wire  30  may be advanced through a vascular system in any conventional manner to establish a path for the catheter to track over. Generally, as shown in FIG. 1, the guide wire is inserted through the lesion and disposed downstream of the lesion  24  a variably selected distance. The distance selected by the operator may be conveniently adjusted merely by further advancing or slightly withdrawing the guide wire. This provides the highly desirable capability of enabling the operator to independently adjust the selected distance to preclude the possibility of embolic material progressing through a branch path between the lesion and the filter. The catheter  20  is then inserted along the guide wire to access the treatment area. Typically, image scanning techniques aid in the exact positioning of the catheter relative to the lesion such that the lesion treatment device will have maximum effectiveness. 
     The filter may then be deployed by actuating an actuating mechanism (not shown) coupled to the core wire  34  for axially moving the shaft  38  relative to the core wire. As the shaft advances axially along the core wire in the distal direction, the filter basket  52 , having its distal end  57  attached to the fixed core wire and its proximal end connected to the shaft, compresses axially and expands radially outwardly against the inner walls of the blood vessel. In its expanded state, the filter  50  collects any plaque that may have loosened and become dislodged from the treated area. 
     Once the treatment concludes, and the catheter is withdrawn from the body, the filter is retracted radially inwardly by shifting the shaft back to its original position. As the filter retracts, the collection cavity  62  traps any material strained against the filter layer. The guide wire itself is then carefully withdrawn from the vasculature. 
     Referring now to FIGS. 12 through 16, a temporary filter guide wire according to a further embodiment of the present invention is shown, and generally designated  200 . The guide wire generally includes a proximal end  202  having an actuating mechanism  208 , an intermediate portion  220  including a housed collapsible filter element  222 , and a flexible distal end  240 . 
     With particular reference to FIG. 12, the proximal end  202  includes a solid stainless steel core wire  204  having a diameter, for example, of approximately 0.0075 inches and slidably confined coaxially by an elongated shaft  206 . The shaft may include, for example, an inner diameter of approximately 0.010 inches and an outer diameter of approximately 0.014 inches. The proximal tip of the core wire nests within the handle mechanism  208  that includes a rotatable handle element  209  having a formed central blind bore  210  and a threaded hollow shank  212 . A fixed threaded base  214  having a throughbore  216  receives the proximal portion of the shaft  206  and rotatably engages the handle element to define the actuating mechanism. 
     Referring now to FIGS. 12 and 13, the core wire  204  and the shaft  206  extend longitudinally to define the intermediate portion  220  of the guide wire. The filter element  222  is mounted to the intermediate portion and includes an intermediate quad filar spring  224  of approximately 0.002 inch diameter wire that extends approximately three to seven centimeters from the end of the shaft, depending on the application. The respective ends of four wires comprising the quad spring are unwound, straightened, and outwardly biased approximately forty-five degrees from the spring axis at spaced apart radial locations to define a plurality of umbrella shaped filter struts  226 . These struts form the support structure for the filter. As shown in FIGS. 14,  15 , and  16 , the strut spacing may conveniently take on a variety of configurations depending on the particular application desired. Lashed to the struts is a fine wire mesh  228  of approximately 0.001 inches thick within 40 to 500 micron pores for straining particulate matter from the bloodstream. 
     Further referring to FIG. 12, the radial exterior of the distal portion of the core wire  204  carries a bonded housing or pod  230  having an axially open mouth  232  slightly larger in diameter than the diameter of the filter in a closed configuration. The mouth opens into a cavity sufficiently sized to fully enclose the filter during insertion or withdrawal of the guide wire. The pod would also have a rounded inward edge at its proximal opening so as to envelop the filter when retracted and prevent unintentional engagement of a stent or catheter upon withdrawal. In an alternative embodiment, the housing  230  can include a reduced-in-diameter collar  260  radially affixed to the core wire proximate the distal end of the core wire. The pod may be fabricated out of a spring material wound in the opposing direction as the spiral struts to improve the sliding of the two surfaces. Other options include a lubricious plastic such as polyethylene. 
     FIG. 13 a  illustrates an alternative embodiment of the housing  230  in FIG. 13 in which the housing  230  is formed in a frusto-conical configuration including an oversized-in-diameter mouth opening axially outwardly from the core wire distal end and a reduced-in-diameter collar radially affixed to the core wire proximal of the core wire distal end. 
     Operation of the second embodiment proceeds in much the same way as that of the first embodiment, with the guide wire  200  first directed through the vasculature, followed by tracking with a treating catheter. Like the first embodiment, the guide wire  200  is advantageously adjustable in the blood vessel independent of the catheter, allowing a variable selected distance between the location of the stenosis and the filter. However, the way in which the filter  222  expands and retracts differs somewhat from the previously described embodiment. 
     With the handle mechanism  208  in a normally open configuration, the operator turns the rotatable element  209  to incrementally drive the core wire  204  axially with respect to the shaft  206 . The relative axial displacement of the core wire causes the filter housing  230  to become disengaged from the filter struts  226 . Because of the spring biased nature of the filter struts  226 , as the filter exits the housing, the struts expand radially outwardly against the blood vessel wall such that the wire mesh spans the vessel diameter. In its extended state, the filer allows bloodflow to continue through the vessel while dislodged material becomes entrapped in the wire mesh for collection in the cavity. 
     Once the lesion treatment procedure is complete, and the necessity for filtering has completely diminished, the handle mechanism is actuated to pull the core wire back to its original position. This activity causes the housing mouth to re-engage the filter struts and urge the struts radially inwardly as the housing encloses the filter. With the filter fully retracted, the streamlined guide wire may be easily and safely withdrawn from the body. 
     Those skilled in the art will appreciate the many benefits and advantages afforded the present invention. Of relative importance is the feature that avoids any additional control wires, beyond the guide wire itself, in order to expand and retract the filter. Not only does this minimize the number of components necessary to practice the invention, but the angioplasty procedure itself is made safer for the patient. 
     Additionally, the present invention provides the capability of adjusting the distance between the filter and the catheter lesion treatment device in vivo, eliminating the need to withdraw the guide wire or catheter for distance adjustment should the relative spacing be inadequate. 
     The filter itself, in one embodiment, provides substantial manufacturability benefits by requiring only a single braiding step. Consequently, braiding additional filter layers adding to the device&#39;s complexity are eliminated. By minimizing the process steps required to fabricate the filter, costs involved in manufacture are greatly reduced. 
     Moreover, the method of fabricating filters according to the present invention offers added efficiencies in manufacture due to the production line processing scheme. Employing such a scheme serves to dramatically improve the throughput rate of filters to minimize overall costs. 
     While the invention has been particularly shown and described with reference to the preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention. 
     For example, the invention may be used in any intravascular treatment utilizing a guide wire where the possibility of loosening emboli may occur. Although the description herein illustrates angioplasty and stent placement procedures as significant applications, it should be understood that the present invention is in no way limited only to those environments.

Technology Classification (CPC): 8