Patent Application
20090259210
1. Field of the Invention
The present invention relates to treatment of cardiac conditions in living beings, and more particularly to forming structural members within the cardiac venous system for the treatment of cardiac conditions in living beings.
2. Description of Related Art
Cardiovascular disease (“CVD”) is the leading cause of death in the United States; see, e.g., C. Lenfant, Fixing the Failing Heart, Circulation, Vol. 95, 1997, pages 771-772; American Heart Association, Heart and Stroke Statistical Update, 2001; C. Lenfant, Cardiovascular Research: An NIH Perspective, Cardiovasc. Surg., Vol. 5, 1997; pages 4-5; J. N. Cohn et al., Report of the National Heart, Lung, and Blood Institute Special Emphasis Panel on Heart Failure Research, Circulation, Vol. 95, 1997, pages 766-770.
Heart failure (“HF”) is generally defined as a change in the pumping function of the heart accompanied by typical signs or symptoms. Heart failure is a progressive disorder whereby the hemodynamic and symptomatic states of the patient worsen over time despite the absence of clinically apparent adverse events. The symptomatic deterioration is often accompanied by progressive left ventricular (“LV”) chamber remodeling.
Preventing or reversing remodeling has emerged as desirable in the treatment of cardiomyopathy. Cardiomyopathy is a general term for disease of heart muscle regardless of the underlying etiology, which may be, for example, ischemic, hypertensive, dilated, hypertrophic, infiltrative, restrictive, viral, postpartum, valvular, or idiopathic. Cardomyopathy typically results in heart failure.
At the present time, the most effective treatment for patients in end-stage heart failure is heart transplantation. However, given the chronic shortage of donor hearts, alternate strategies are needed to improve the lives of those with heart failure. Moreover, transplantation is not the most suitable treatment option for patients with milder forms of the disease. Other treatment approaches include the delivery of drugs to the site of action through the bloodstream, and the injection of cells into ischemic myocardium to improve cardiac function. An example of an approach for treating cardiovascular problems with intramyocardial scaffolding is disclosed in United States Patent Application Publication No. 2005/0271631, published Dec. 8, 2005 in the name of Lee et al. and entitled “Material compositions and related systems and methods for treating cardiac conditions.” Tissue engineering approaches for cardiac therapy that are generally intended to repair lost or damaged tissue through the use of cellular transplantation and biomaterial scaffolds have also been disclosed. One example of this approach involves suturing fetal cardiomyocyte-seeded alginate gels to the epicardial surface in order to preserve LV function. Another treatment approach involves the use of mechanical external constraints to limit, stop, or even reverse negative left ventricular remodeling. One previously disclosed study included suturing a polymeric mesh to the epicardial surface for the intended purpose of providing an external support to prevent LV dilation and deterioration of LV function post-MI. See Kelley S T, Malekan R, Gorman J H 3rd et al., Restraining infarct expansion preserves left ventricle geometry and function after acute anteroapical infarction, Circulation 1999; 99:135-42. Another previously disclosed device that has been investigated provides a plurality of sutures that are implanted in an open-chest procedure across the ventricle under tension to provide a change in the ventricle shape and a decrease in chamber diameter. This trans-cavitary suture network is intended to decrease the radius of the ventricle to thus reduce ventricular wall stress. Another previously disclosed device under clinical investigation is generally a mesh structure that is implanted as a jacket around the heart and adjusted to provide a snug fit during open-chest surgery. It is intended that the jacket restrains the heart from further enlargement. See, for example, Hani N. Sabbah, Reversal of Chronic Molecular and Cellular Abnormalities Due to Heart Failure by Passive Mechanical Ventricular Containment, Circ. Res., Vol. 93, 2003, pages 1095-1101; Sharad Rastogi et al., Reversal of Maladaptive Gene Program in Left Ventricular Myocardium of Dogs with Heart Failure Following Long-Term Therapy with the Acorn Cardiac Support Devide, Heart Failure Reviews, Vol. 10, 2005, pages 157-163. Still another approach being investigated provides a nitinol mesh as a similar external restraining device to that described above; however, the super-elastic system is intended to assist in systolic contraction, and is generally intended for use via thorascopically guided minimally invasive delivery. Still another system being investigated includes a rigid ring that is implanted during open-chest surgery as another external constraining device to the ventricle. This ring is intended to decrease ventricular wall stress and prevent further enlargement of the heart by reducing the radius and modifying the shape of the ventricle. Examples of devices and methods similar to one or more of those discussed above have been disclosed by various companies, including the following: “Acorn;” “Myocor;” “Paracor;” “Cardioclasp;” and “Hearten.” The Cardioclasp device is disclosed in an article by Abul Kashem et al., CardioClasp: A New Passive Device to Re-Shape Cardiac Enlargement, ASAIO Journal, 2002.
Myocardial infarction (“MI”) is a medical emergency in which some of the heart's blood supply is suddenly and severely reduced or cut off, causing the myocardium to die because it is deprived of its oxygen supply. A myocardial infarction may progressively advance into heart failure. Scar tissue formation and aneurismal thinning of the infarct region often occur in patients who survive myocardial infarctions. It is believed that the death of cardiomyocytes results in negative left ventricular (LV) remodeling which leads to increased wall stress in the remaining viable myocardium. This process results in a sequence of molecular, cellular, and physiological responses which lead to LV dilation. Negative LV remodeling is generally considered an independent contributor to the progression of heart failure.
Mitral regurgitation (“MR”) is incompetency of the mitral valve causing flow from the left ventricle (LV) into the left atrium during systole. Common causes include mitral valve prolapse, ischemic papillary muscle dysfunction, rheumatic fever, and annular dilation secondary to LV systolic dysfunction and dilation.
Despite advances in the treatment of heart failure, aneurismal thinning and mitral regurgitation, further improvement in the speed of treatment and reduction of the complexity and intrusiveness of treatment techniques and devices is desirable. Generally, improved treatment techniques and devices are desirable for the treatment of all forms of cardiomyopathy, including early forms of the disease.
Each of the various embodiments of the present inventions overcome one or more of the needs and shortcomings discussed above. Additional improvements and advantages may be recognized by those of ordinary skill in the art upon study of the present disclosure.
One embodiment of the invention is an apparatus to form structural members in the cardiac venous system in order to reinforce the myocardium are provided. In various aspects the apparatus may include a catheter tube. The catheter tube defines a distal end, a proximal end, an outer surface, and an inner surface, and the inner surface defines a lumen. The apparatus may include a barrier. In various aspects, the barrier is disposed generally about the distal end of the catheter tube. The barrier is transformable between a collapsed position and an expanded position. The barrier in the collapsed position is deliverable into the vein segment and the barrier in the expanded positions occludes the vein segment. The barrier cooperates with the catheter tube to allow occluding agent to be delivered through the lumen into portions of the vein segment distal of the barrier.
Another embodiment of the invention is a catheter for establishing an occlusion within a cardiac vein, comprising an elongated catheter body having a distal end and a proximal end and comprising an injectate lumen extending longitudinally within the catheter body; a barrier disposed about a periphery of the catheter body in proximity to the distal end thereof and about the injectate lumen, the barrier being controllably transformable between a collapsed position for movement of the catheter body within the cardiac vein, and an expanded position for occluding the cardiac vein in cooperation with the catheter body; and an injectate port disposed in the catheter body distally of the barrier, the injectate lumen being in fluid communication with the injectate port.
Another embodiment of the invention is a catheter for establishing an occlusion within a cardiac vein, comprising means for advancing a distal end of a catheter to a site within the cardiac vein; means for establishing a first venous occlusion about the catheter near a distal end thereof to occlude the cardiac vein at the site, in cooperation with the catheter; means for introducing an occluding agent into the cardiac vein at the site to form at the site a second venous occlusion generally contiguous to the first venous occlusion; and means for withdrawing the distal end of the catheter from the site following the occluding agent introducing step.
Another embodiment of the invention is a method for forming structural members in the cardiac venous system, which includes occluding a vein segment by transforming a barrier disposed about the distal end of a catheter tube from a collapsed position into an expanded position at a vein segment proximal end of the vein segment, and delivering a occluding agent through a lumen defined by the catheter tube into the vein segment distal of the barrier.
Another embodiment of the invention is a method for establishing an occlusion within a segment of a cardiac vein, comprising advancing a distal end of a catheter to a site within the cardiac vein; establishing a first venous occlusion about the catheter in proximity to a distal end thereof to occlude the cardiac vein at the site, in cooperation with the catheter; introducing an occluding agent into the cardiac vein at the site to form at the site a second venous occlusion generally contiguous to the first venous occlusion; and withdrawing the distal end of the catheter from the site following the occluding agent introducing step.
Another embodiment of the invention is a method for establishing an occlusion within a cardiac vein, comprising positioning a distal end of a catheter outer tube within the vein; expanding a barrier disposed about the catheter outer tube near the distal end thereof for occluding the vein at a first location with an expanded barrier, in cooperation with the catheter; positioning a distal end of a catheter inner tube within the vein and spaced apart from the barrier, the distal end of the catheter inner tube having an occluder coupled thereto; expanding the occluder within the vein for occluding the vein with an expanded occluder at a second location spaced-away from the first location; introducing occluding agent from the catheter into the vein between the expanded barrier at the first location and the expanded occluder at the second location; releasing the expanded occluder from the distal end of the inner tube; collapsing the barrier; and withdrawing the catheter from the vein.
Another embodiment of the invention is a heart prosthetic for treating a heart in a diseased condition, comprising a first occlusion of a first composition disposed within a part of a cardiac vein; and a second occlusion of a second composition different than the first composition disposed within a part of the cardiac vein contiguous to the first occlusion; the first and second occlusions being essentially in a solid state for provide structural support to the heart.
Another embodiment of the invention is a kit which, in various aspects, includes an occluding agent and a catheter. The occluding agent solidifies from the liquid state to a solid state within a vein segment to form at least a portion of a structural member. The catheter includes a catheter tube and a barrier. The catheter tube has a proximal end and a distal end and defines a lumen. The barrier is disposed about the distal end and the barrier is transformable between a collapsed position and an expanded position. The catheter is positionable within a vein segment, and the catheter is configured to deliver the occluding agent into portions of the vein segment distal of the barrier.
Another embodiment of the invention is a kit comprising a source of an injectable occluding agent; and a catheter. The catheter comprises an elongated catheter body, a coupler, and an injection port. The catheter body has a distal end and a proximal end and comprising an injectate lumen extending longitudinally within the catheter body, and a barrier disposed about a periphery of the catheter body in proximity to the distal end thereof and about the injectate lumen, the barrier being controllably transformable between a collapsed position for movement of the catheter body within the cardiac vein, and an expanded position for occluding the cardiac vein in cooperation with the catheter body. The coupler is in fluid communication with the injectate lumen, the occluding agent source being adapted for coupling to the first coupler. The injectate port is disposed in the catheter body distally of the barrier, the injectate lumen being in fluid communication with the injectate port.
Other features and advantages of the inventions will become apparent from the following detailed description and from the claims.
The Figures are to facilitate explanation of the present invention. The number, position, relationship and dimensions of the parts shown in the Figures to form the various implementations described herein, as well as dimensions and dimensional proportions to conform to specific force, weight, strength, flow and similar requirements, are explained herein or are understandable to a person of ordinary skill in the art upon reading this patent. Where used in various Figures, the same numerals designate the same or similar parts. Furthermore, when the terms “top,” “bottom,” “right,” “left,” “forward,” “rear,” “first,” “second,” “inside,” “outside,” and similar terms are used, the terms should be understood in reference to the orientation of the structures shown in the drawings and utilized to facilitate understanding. Similarly, when the terms “proximal,” “distal,” and similar positional terms are used, the terms should be understood in reference to the structures shown in the drawings and utilized to facilitate understanding.
Occluding agent may be delivered into one or more selected sections of the cardiac venous system by a catheter to form one or more structural members configured to reinforce the myocardium in order to prevent, moderate, stop, or reverse negative cardiac remodeling due to various adverse cardiac conditions, both acute and chronic. The cardiac conditions that may be treated using the apparatus and methods described herein may include cardiomyopathy, myocardial infarctions, acute myocardial infarctions, arrhythmias, valvular insufficiency, congestive heart failure, mitral regurgitation and other heart valve abnormalities, other cardiac complications, and combinations thereof. Kits for treating the cardiac conditions using the methods described herein are also contemplated.
The myocardium is composed of interlacing bundles of cardiac muscle fibers arranged spirally around the circumference of the heart. These cardiac muscle fibers receive blood through coronary circulation. The coronary arteries branch from the aorta just beyond the aortic valve to supply blood to the cardiac muscle fibers, and the coronary veins empty into the right atrium via the coronary sinus. The myocardium is well supplied with a highly distributed system of coronary arteries and veins. Typically, each coronary artery as it courses along the surface of the heart has coronary veins that course generally alongside. This is also generally true of the smaller branches of the main coronary arteries, including those that penetrate into the myocardium and perfuse the deeper layers of the muscle of the heart. Small veins such as venules return the blood to larger cardiac veins. Thus the venous system network of the heart is distributed throughout the thickness of the heart muscle and is present everywhere arteries are present.
Material may be implanted or injected into cardiac veins as discrete masses at various sites in the cardiac venous system, where it occludes the vein at the site of injection but also disperses in the vein and also into venules and possibly even the capillaries in fluid communication with the site of injection in order to reinforce the myocardium for the purpose of preventing, moderating, stopping or reversing negative cardiac remodeling due to various adverse cardiac conditions, both acute and chronic, or for the purpose of treating localize anomalies of the heart, or for both purposes. Cardiac conditions that may be treated using such techniques include cardiomyopathy, myocardial infarctions, acute myocardial infarctions, arrhythmias, valvular insufficiency, congestive heart failure, mitral regurgitation and other heart valve abnormalities, and other cardiac complications. Kits for treating the cardiac conditions using the techniques described herein are also contemplated. Exemplary techniques are described in US Patent Application Publication No. US 2008/0269720, published Oct. 30, 2008 (Sabbah, “Cardiac Repair, Resizing and Reshaping Using the Venous System of the Heart”), which hereby is incorporated herein in its entirety by reference thereto.
Although one or more vein segments of the cardiac venous system are occluded by the structural members formed from the occluding agent, occlusion of the vein segments is not adverse to treatment. Veins have much thinner walls with less smooth muscle than arteries. Relative to arteries, veins have very little elasticity because venous connective tissue contains considerably more collagen fibers than elastin fibers. Moreover, venous smooth muscle has little inherent myogenic tone. Accordingly, veins are highly distensible and have little elastic recoil, so that non-occluded veins in proximity to occluded veins can easily distend to accommodate additional volumes of blood diverted from the occluded vein segment 400 with only a small increase in venous pressure.
The occluding agent may be delivered into vein segments of the cardiac venous system by the catheter 10 to form structural members configured to treat a localized heart anomaly, the heart generally, the ventricle(s), or the atria. Where a generalized treatment is desired, mapping need not be performed to select the sections into which the occluding agent is delivered. A generalized approach is particularly applicable to the ventricles. Where a localized treatment is desired, the site of the heart disorder such as a myocardial infract may be identified, and vein segments of the cardiac venous system encompassing the localized heart disorder may be selected. Occluding agent may be delivered by the catheter 10 into the vein segments to form structural members to reshape and/or remodel the atria, and in particular an enlarged left atrium, and/or to aid in prevention of atrial fibrillation and/or other atria-related conditions. Suitable techniques for identifying various heart disorders such as thin walled regions or aneurysms requiring treatment may include MRI, echocaridogram, and other imaging and mapping modalities as would be recognized by those of ordinary skill in the art upon study of this disclosure.
Identifying the vein segments of the cardiac venous system into which the occluding agent may be delivered to form structural members may be done empirically. Alternatively, computer-aided selection may be practiced if desired. In one technique, finite element model simulation is used to model a region of the heart such as the left ventricle. For example, using an imaging or mapping technique, parameters of the patient's left ventricle, including the location, extent and thickness of damaged wall areas, are measured and added to the model. The formation of structural members in selected vein segments of the cardiac venous system may be simulated by changing the transmural coordinates of epicardial and endocardial mesh nodes in border zone elements corresponding to the selected segments, along with changing the contractility of the elements. The selected vein segments may be changed over successive simulations to identify an optimal set of vein segments of the cardiac venous system to receive occluding agent for the formation of structural members. A suitable finite element model simulation is disclosed in an article by Samuel T. Wall et al., Theoretical Impact of the Injection of Material Into the Myocardium: A Finite Element Model Simulation, in Circulation AHA 106.657270, Nov. 27, 2006, which hereby is incorporated herein in its entirety by reference thereto.
While some cardiac conditions may be treated in one procedure, other cardiac conditions may be treated by successive deliveries of the occluding agent into the cardiac venous system over time. For example, in some aspects, the occluding agent may be delivered into one or more vein segments of the cardiac venous system to form structural member(s), and the effect studied before delivery of the occluding agent into additional vein segment(s) of the cardiac venous system to form additional structural member(s). In various aspects, the delivery of the occluding agent into one or more vein segment(s) of the cardiac venous system to form structural member(s) may be configured to fine tune the beneficial results of prior deliveries.
The occluding agent 100 (see
Exemplary occluding agent 100 includes natural and synthetic polymers (any FDA approved polymer for human implantation), fibrin sealants, alginates, collagens, sugars, hydrogels, self-assembling peptides, PLGA, PEG, coagulation protein based sealants, hyaluronic acid, alginate and chitosan hydrogels and beads, alginate material with covalently attached peptides, alginate beads coated with chitosan material, self-assembling peptide scaffold hydrogels, and so forth, either alone or in combinations of two or more. Suitable biopolymer materials are commercially available from a variety of commercial sources, including the NovaMatrix Unit of FMC Biopolymer Corporation, 1735 Market Street, Philadelphia, Pa. 19103 and Omrix Biopharmaceuticals, 630 5th Avenue, 22nd Floor, New York, N.Y. 10111. This list of occluding agent 100 is illustrative, and the occluding agent 100 may be essentially any FDA approved material that has a degree of purity, preparation time, ease of expression (viscosity), reaction rate (cure time), strength (energy to failure), compliance, water uptake, burst strength, tissue adherence, endurance, degradation rate, and so forth, suitable for forming a supportive structure upon delivery into the selected vein segment 400. The various properties of the occluding agent 100 such as stiffness, compliance, and resorption rate may be tailored to the particular condition(s) being treated and may be tailored for the size of the vein segment 400 into which the agent is to be delivered.
The occluding agent 100 may serve as a platform for delivery of other therapeutic materials, including living cells (including, for example, myocytes, fibroblasts, fibrocytes or profibrotic blood progenitor cells, stem cells, and muscle cells), growth factor (including, for example, angiogenic factors such as VEGF, FGF, and HGF; chemotractants; stem cell derived factor; and TGF-b), stem cell products, peptides, proteins, genes, chondrocytes, insoluble molecules, other biologics, and so forth, alone or in combinations of two or more.
The catheter 10, in various aspects, may be used to deliver the occluding agent 100 into the vein segment 400 and, in various aspects, may be configured to prevent entrainment of the occluding agent 100 in the venous flow and subsequent conveyance of the occluding agent 100 into the right atrium of the heart. An implementation of the catheter 10 is illustrated in
The outer tube 40 may be made from a range of materials. For example, in one implementation, the outer tube 40 may be a metal, such as, for example, stainless steel or nitinol. In another implementation, the outer tube 40 can be made from one or more polymers such as polyethylene, nylon, polyimide, among others. Combinations of materials such as the above materials may also be employed, and the material(s) may be varied along the length of the outer tube 40. The materials and dimensions are generally selected to provide a desired balance of longitudinal stiffness and torsional rigidity based on the characteristics of the outer tube 40 to allow the outer tube 40 to be positioned within the vein segment 400 of the patient.
As illustrated, the barrier 60 extends circumferentially around the outer tube outer surface 42 generally proximate the outer tube distal end 48 to block blood flow between the outer tube outer surface 42 and the vein inner surface 404 (see
The barrier 60 is transformable between at least a collapsed position 67 as illustrated in
With the barrier 60 in the collapsed position 67, the outer tube 40 may be positioned within the vein segment 400 such that the outer tube distal end 48 is generally at the vein segment proximal end 406 (
In the expanded position 69, portions of the barrier outer surface 62 may be generally biased against the venous inner surface to anchor the outer tube 40 to the venous inner surface 404 and to prevent blood flow from passing between the venous inner surface 404 and the outer tube outer surface 42 in the proximal direction. With the barrier 60 in the expanded position 69, fluid may be communicated from the barrier chamber 65 into the outer tube outer lumen 45 to collapse the barrier 60 into the collapsed position 67 in order to release the barrier outer surface 62 from the venous inner surface 404 so that the outer tube 40 may be withdrawn.
In the implementation of the catheter 10 illustrated in
As illustrated, portions of the inner tube 50 generally proximate the inner tube distal end 58 may extend forth from the outer aperture 80 defined by the terminus of the outer lumen 45 at the outer tube distal end 48, as illustrated in
The outer tube proximal end 46 and the inner tube proximal end 56 are generally illustrated in
An occluder 70 may be removably disposed upon the inner tube distal end 58, as illustrated in
Where the occluder 70 is a balloon-type occluder, it may be inflatable between at least a contracted position 77 and a dilated position 79, and the inner lumen 55 may fluidly communicate with the occluder chamber 75 to introduce fluid into the occluder chamber 75 in order to inflate the occluder 70 from the contracted position 77 into the dilated position 79. With the occluder 70 in the contracted position 77, the occluder 70 may be advanced upon the inner tube distal end 58 through the outer lumen 45. The inner tube distal end 58 may be extended forth from the outer aperture 80 and manipulated to position the occluder 70 within the vein segment 400, and fluid may be communicated from the inner lumen 55 into the occluder chamber 75 to inflate the occluder 70 from the contracted position 77 into the dilated position 79, as illustrated in
The occluder 70 illustrated in
As illustrated in
Operation of an implementation of the catheter 10 to deliver the occluding agent 100 into the vein segment 400 is generally illustrated in
In
As illustrated in
As illustrated in
As illustrated in
In
As illustrated in
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As illustrated in
A suitable catheter 340 for injecting occluding agent into the cardiac venous system is shown in various operating conditions in
The catheter 340 includes an expandable barrier 344, shown collapsed in
The inner tube 350 is slidably received within the lumen 346 for placing an occluder 360 within the vein in a spaced-apart relationship with the barrier 344. The occluder 360, which is removably disposed at the distal end of the inner tube 350, is passed through the lumen of the outer tube 342 in a collapsed condition, is advanced through the vein a desired distance from the distal end of the outer tube 342, and is expanded to engage the wall of the vein for establishing the other end of the segment into which the occluding agent is to be introduced. Although shown in
The inner tube 350 includes two lumen (not shown). One of these lumen is for transmitting fluid to/from the occluder 360 where the occluder 360 is designed to be inflatable and releasable, or inflatable and deflatable, or for containing a wire for mechanically releasing the occluder 360 where the occluder is designed to expand upon release, such as a sponge. Where the occluder is designed to expand upon release, the release wire and associated lumen may be eliminated if the release mechanism is triggered by the pressure of occluding agent injectate in the other lumen. The other lumen is for communicating fluid with ports 352, 354 and 356 (illustratively three ports are shown) on the inner tube 350. The ports 352, 354 and 356 are for introducing occluding agent into the between the occluder 360 and the barrier 344, and may be used to suction blood from the volume if desired.
To place occluding agent within a desired segment of the cardiac venous system, the catheter 340 as shown in
Radiopaque materials may be disposed proximate the distal end of the outer tube 342 and/or the distal end of the inner tube 350 to facilitate or confirm proper placement of the distal end of the catheter 340 within the desired segment of the cardiac venous system.
The proximal ends (not shown) of the outer tube 342 and the inner tube 350 extend from the proximal end of the catheter 340 and are connected to a handle (not shown) to allow the a physician to control the various functions performed by the catheter 340.
Methods for forming a structural member 500 in the vein segment 400 to reinforce the myocardium include delivering the occluding agent 100 into the vein segment 400, the occluding agent 100 solidifying within the vein segment 400 thereby forming the structural member 500. Treating a particular cardiac condition by selecting one or more vein segments 400, delivering the occluding agent 100 into the one or more vein segments 400 thereby forming one or more structural members 500 within the one or more vein segments 400 may be included in the methods. The catheter 10 may define one or more lumen 15 for delivering the occluding agent 100 into the vein segment 400. The methods, in various implementations, may include positioning at least one occluder 70 within the vein thereby occluding the vein segment 400 and retaining the occluding agent 100 within the vein segment 400. Positioning at least one occluder 70 using the catheter 10 may be included in the methods. The methods may include disposing the occluding agent 100 within the vein segment 400 between an occluder 170 and an occluder 270. Various implementations of the methods may include the occluder 170, the occluding agent 100, and the occluder 270 defining the structural member 500. Including a therapeutic material in the occluding agent 100 may be part of the methods in various aspects.
Delivering the occluding agent 100 into the vein segment 400 by a particular implementation of the catheter 10 may proceed in the following manner. The method may be initiated by placing the outer tube distal end 48 within the vein segment 400 by navigating the catheter 10 through various bodily lumen. Transforming the barrier 60 (
The methods may include removing the blood from the vein segment 400. The methods, in various aspects, may include inflating the occluder 170 from the contracted position 177 into the dilated position 179 and pushing the occluder 170 in the dilated position distally to push blood distally from the vein segment 400. In various aspects, the methods may include withdrawing blood from the vein segment 400 through annular lumen 255 and/or through inner lumen 55.
The methods, in various aspects, may include delivering the occluding agent 100 into the vein segment 400 through the outer aperture 80 via the annular lumen 255, the occluder 170 and the barrier 60 holding the occluding agent 100 within the vein segment 400. In other aspects, the methods may include detaching the inner tube distal end 58 from the occluder 170, and delivering the occluding agent 100 via the inner lumen 55 through the inner aperture 90 into the vein segment 400. In still other aspects, the methods may include detaching the inner tube 50 from the occluder 170, withdrawing the inner tube 50 from the outer lumen 45, and delivering the occluding agent 100 into the vein segment 400 through the outer aperture 80 via the outer lumen 45.
The methods may include detaching the inner tube distal end 58 from the occluder 170 and withdrawing the inner tube distal end 58 may be included in the methods, the barrier 60 remaining in the expanded position 69 thereby securing the occluding agent 100 in the vein segment 400. In various aspects, the inner tube 50 may be substantially or entirely withdrawn from the outer lumen 45.
The methods may proceed by withdrawing the outer tube distal end 48 somewhat in the proximal direction with the barrier 60 in the expanded position 69. Passing the inner tube 50 through the outer lumen 45 and extending the inner tube distal end 58 forth from the outer aperture 80 into the vein segment 400, and inflating a occluder 270 secured to the inner tube distal end 58 thereby retaining the occluding agent 100 between the occluder 170 and the occluder 270 may be steps in the various methods. Compressing the occluding agent 100 within the vein segment 400 by dilating the occluder 270 and locking the occluder 270 into position in the vein segment 400 by biasing portions of the occluder outer surface 272 against the vein inner surface 404 may be part of the methods. The methods may include detaching the inner tube distal end 58 from the occluder 270, deflating the barrier 60 into the collapsed position 67, and withdrawing the catheter 10 including the inner tube 50 and the outer tube 40 thereby locking the occluding agent 100 into the vein segment 400 by interposing the occluding agent 100 between the occluder 170 and the occluder 270.
In a variation of the catheters 10 and 340 and the methods of operating them, the inner tubes 50 and 350 may be fixed or have very limited slidable motion relative to the outer tubes 40 and 342. With reference to the catheter 340 (
The various exemplary implementations described herein are illustrative of the invention. Variations and modifications of these implementations are possible, and practical alternatives to and equivalents of the various elements of the embodiments are contemplated. These and other variations and modifications of the implementations disclosed herein may be made without departing from the scope and spirit of the invention, as set forth in the following claims.
This application claims the benefit of U.S. Provisional Patent Application Ser. No. 61/123,700, filed Apr. 10, 2008, which hereby is incorporated herein in its entirety by reference thereto.
| Number | Date | Country | |
|---|---|---|---|
| 61123700 | Apr 2008 | US |
