Source: https://patents.google.com/patent/US6702763B2/en
Timestamp: 2019-04-20 01:23:00+00:00

Document:
2004-12-02 First worldwide family litigation filed litigation Critical https://patents.darts-ip.com/?family=26955284&utm_source=google_patent&utm_medium=platform_link&utm_campaign=public_patent_search&patent=US6702763(B2) "Global patent litigation dataset” by Darts-ip is licensed under a Creative Commons Attribution 4.0 International License.
This invention claims the benefit of U.S. Provisional Application Serial No. 60/272,073 filed on Feb. 28, 2001 and is also related to U.S. application Ser. Nos. 09/864,510, 09/864,793, and 09/864,794, all of which were filed on May 24, 2001.
Following coronary occlusion, successful acute reprefusion by thrombolysis, (clot dissolution) percutaneous angioplasty, or urgent surgery can decrease early mortality by reducing arrhythmias and cardiogenic shock. It is also known that addressing ischemic cardiomyopathy in the acute phase, for example with reperfusion, may salvage the epicardial surface. Although the myocardium may be rendered akinetic, at least it is not dyskinetic. Post-infarction surgical re-vascularation can be directed at remote viable muscle to reduce ischemia. However, it does not address the anatomical consequences of the akinetic region of the heart that is scarred. Despite these techniques for monitoring ischemia, cardiac dilation and subsequent heart failure continue to occur in approximately 50 percent of post-infraction patients discharged from the hospital.
In response to these and other problems, an improved apparatus and method is provided for restoring the geometry of the left ventricle to counteract the effects of cardiac remodeling. One embodiment of the present invention provides an apparatus and method to reconstruct an enlarged left ventricle of a human heart, using a shaper, having a size and shape substantially equal to the size and shape of an appropriate left ventricle, wherein the shaper is adapted to be temporarily placed into the enlarged left ventricle during a surgical procedure. Another aspect of one embodiment comprises a ventricular patch adapted for placement into the left ventricle of a heart made from a sheet of biocompatible material, and having a plurality of markings coupled to the sheet, wherein the markings are configured in distinct patterns for post operatively evaluating movement of the patch. In another aspect of one embodiment, a device is presented, comprising of a handle and a sizing template adapted to be coupled to the handle. Such components are also presented as a kit for use during ventricular restoration surgery.
FIG. 2a is a side view of one embodiment of a shaping device.
FIG. 2b is a side view of a balloon embodiment of a shaping device.
FIG. 2c is a section view of another balloon embodiment of a shaping device.
FIG. 2d is a section view of another balloon embodiment of a shaping device.
FIG. 2e is a section view of another balloon embodiment of a shaping device.
FIG. 2f is a section view of another balloon embodiment of a shaping device.
FIG. 2g is a side view of a wire frame embodiment of a shaping device in an expanded condition.
FIG. 2h is a side view of a wire frame embodiment of a shaping device in a collapsed condition.
FIG. 2j is a section view cut transversely through the embodiment of FIG. 2h.
FIG. 3a is a top view of one embodiment of a patch.
FIG. 3b is a top view of one embodiment of markings which may be coupled to the patch of FIG. 3a.
FIG. 3c is a top view of one embodiment of markings which may be coupled to the patch of FIG. 3a.
FIG. 3d is a top view of one embodiment of markings which may be coupled to the patch of FIG. 3a.
FIG. 3e is a top view of one embodiment of markings which may be coupled to the patch of FIG. 3a.
FIG. 4a is a top view of one embodiment of a set of sizers.
FIG. 4b is a top view of one embodiment of a handle to be used with the set of sizers illustrated in FIG. 4a.
FIG. 4c is a detailed section view illustrating a connection between the handle and a sizer.
FIG. 4d is a section view of one embodiment of a sizer.
FIG. 4e is a section view of one embodiment of a sizer.
FIG. 4f is a section view of one embodiment of a sizer.
FIG. 4g is a top view of one embodiment of a sizer made of malleable wire.
FIG. 4h is a side view of the sizer illustrated in FIG. 4g.
FIG. 5a is a top view of one embodiment of a patch holder.
FIG. 5b is a top view of one embodiment of a suture hook.
FIG. 7a illustrates one embodiment of a process utilizing several aspects of the present invention.
FIG. 7b is a continuation of the process illustrated in FIG. 7a.
Turning to FIG. 1, there is presented an overview method 100 for performing and using one embodiment of the present invention. A more complete discussion of this method will be presented below. The method 100 may use the following components: a shaping device 200 (FIG. 2a), a patch 300 (FIG. 3a), a sizer 402 a (FIG. 4a), and a suture hook 520 (FIG. 5). Referring back to FIG. 1, at step 102, a surgeon determines the appropriate size for the patient's left ventricle based on the patient's height, weight, body surface area and other patient specific conditions. Once the patient's appropriate ventricle size has been determined, at step 104, the surgeon can then select the appropriate volume for the shaping device 200. At step 106, the surgeon opens up the chest cavity in a conventional manner. An incision is cut into the myocardial wall of an enlarged heart in step 108. At step 110, the surgeon identifies non-viable tissue. At step 112,the surgeon may remove all or some of the non-viable tissue (i.e., the dyskentic and akinetic areas) of the myocardium. A continuous round stitch, known in the art as a Fontan stitch, may then be woven into the ventricle, at step 114. The stitch produces an annular protrusion, which forms an opening. At step 116, the shaping device 200 may be inserted into the ventricle through this opening. At step 118, The musculature of the myocardium may be pulled over the shaping device to form a left ventricle having a predetermined volume, shape and contour. The shaping device 200 may then be compressed and removed at step 120. At step 122, with the aid of the sizer 402 a, the surgeon may determine the preferred location of and size of the patch 300 which may be placed in the left ventricle. The patch 300 is then cut to size in step 124 and secured to the inside of the myocardium in step 126. At step 128, with the patch 300 suitably placed, the ventricle is closed by joining the myocardial walls over the patch.
FIG. 2a illustrates one embodiment of a shaping device 200. In an inflated condition, the shaping device 200 is pre-shaped to generally model the appropriate volume and shape of the left ventricle.
The shape of the normal heart is of particular interest as it dramatically affects the way that the blood is pumped. The left ventricle which is the primary pumping chamber, is somewhat conical or apical in shape in that it is longer (long axis longest portion from aortic valve to apex) than it is wide (short axis widest portion from ventricle wall to septum) and descends from a base with a decreasing cross-sectional circumference to a point or apex. The left ventricle is further defined by a lateral and posterior ventricle wall and a septum, which extends between the auricles and the ventricles. The pumping of the blood from the left ventricle is accomplished by two types of motion. One of these motions is a simple squeezing motion, which occurs between the lateral wall and the septum. The squeezing motion occurs as a result of a thickening of the muscle fibers in the myocardium. This compresses the blood in the ventricle chamber and ejects it into the body. The thickness changes as the ventricle contracts. This is seen easily by echpcardiogram and can be routinely measured.
The shaping device may be of an “appropriate shape” for a patient. In other words, the shaping device may be of a shape similar to the shape of the left ventricle. In one embodiment, the shaping device 200 may be a generally conical shaped object composed of portions of spherical elements having different radii. Referring back to FIG. 2a, the illustrative embodiment of the shaping device may be divided lengthwise into six sections where each section is a length “L2” apart. L2, therefore, may be determined from the formula: L2=0.1665*L. At line “A—A”, a width W1 of the shaping device 200 is approximately 0.543*L. The back surface 202 of the shaping device 200 is generally shaped as a portion of a sphere, having a radius of 0.802*L. At a line “C—C”, a width W2 of the shaping device 200 is approximately 0.628*L. The side surfaces 204 a and 204 b are combinations of portions of spheres with different radii. Between the line A—A and the line C—C, the side surfaces 204 a and 204 b have a radius of 0.515L.
In some embodiments, such as illustrated in FIG. 2b, the shaping device may be an inflatable balloon 201, having a thickness of in the range of 0.02 to 0.08 inches, preferably 0.03 inches. A distal end of a filler tube 208 may be coupled to a point 207 along the exterior surface of balloon 201. For instance, the point 207 could be located approximately ⅓ along balloon's 201 length, as illustrated in FIG. 2b. In other embodiments, the filler tube 208 may be coupled vertex 206. Such tubes are well known in the art, and illustratively may be made of materials such as PVC. A proximal end of the filler tube 208 may be connected to a fluid reservoir, such as a syringe 210 which may inject a pre-specified amount of fluid into the balloon 201 through the filler tube 208. Also coupled to the distal end of the filler tube 208 may be a fluid control device such a stopcock 212. The injection of fluid through the filler tube 208 inflates the balloon 201 to an inflated condition, as illustrated in FIG. 2b. Once inflated, the fluid inside the shaping device may be prevented from escaping by locking the stopcock 212. This allows the balloon 201 to stay inflated with the proper volume, shape and contour during the reconstruction procedure.
The fluid pressure inside the balloon 201 may also be monitored by a pressure transducer, such as a piezoelectric transducer (not shown) coupled to the filler tube 208 with a y-connection (not shown). In other words, one lead of the y-connection would be coupled to a pressure monitor, the other lead would be coupled to the fluid source. Alternatively, the pressure monitor could be coupled to a three way stopcock (not shown), which would monitor the pressure on the filler tube side of the three way stopcock.
In contrast, if the balloon 201 is made from an elastomeric material, the balloon 201 may significantly expand. Such elastomeric materials may include latex, polyurethane, silicone, and other elastomers sold under the trade names KRATON (Shell Chemical, New York, N.Y.), C-FLEX (Concept Polymer, Largo, Fla.) and SANTOPRENE (Monsanto, St. Louis, Mo.) Once the balloon is substantially inflated, the influx of additional fluid causes additional expansion of the balloon. Using this embodiment, the surgeon would simply inflate the balloon to a specific volume. The original shape of the balloon may be maintained during this expansion by selectively thickening the walls of the balloon. FIG. 2c is a section view of an embodiment showing thickened walls of an “expandable balloon” 220. An insertion or distal end 222 of the balloon 220 has walls at a maximum thickness. From the line A—A, the wall thickness progressively decreases to a vertex 224 at point G. In some embodiments, the vertex 224 connects to the filler tube 208. The wall thickness will depend on the expansion range of the balloon. For example, for an expansion of 100 to 150 cc, the thickness of the balloon would vary from 0.01″ at a thin end to 0.05″ at the thick end. Thus, this size or volume of this embodiment may be controlled by controlling the amount and pressure of the fluid injected into the balloon 220.
In another embodiment, the shaping device could have walls that are relatively thick and are coupled to foam spacers or thermoplastic polymer pads surrounding the exterior of the balloon. Turning now to FIG. 2d, there is shown a section view of an embodiment having polymer pads 232 a through 232 l coupled to the exterior of a balloon 230. In a substantially inflated condition, polymer pads 232 a-232 l provide a plurality of contact points: “A” through “L”. Contact points “A” though “L”, if connected, would define a space of approximately the same volume occupied by the balloon 201 (FIG. 2a). Consequently, the balloon 230 would need less fluid for inflation and the polymer pads 232 a through 232 l would also provide puncture resistance.
In yet another embodiment, the shaping device could be a balloon within a balloon. FIG. 2e. illustrates such an embodiment. A balloon 250 is generally shown in FIG. 2e. The balloon 250 comprises a outer balloon 252 and an inner balloon 254. In one embodiment, the inner balloon 254 is inflatable with a fluid, such as saline solution fluid. As in other embodiments, the inner balloon 254 may be inflated through the filler tube 208. A space 256 between the inner balloon 254 and the outer balloon 252 may be pre-filled with a gel 258, such as a silicone gel or saline solution.
FIG. 2f is a section view illustrating another embodiment of a balloon 260 formed to be puncture resistant. In this embodiment, the wall 262 proximal to the vertex 206 is progressively thickened to protect the proximal side of the balloon 260 from punctures during the reconstruction procedure. In an alternative embodiment, the wall 262 could be coupled to protective pads located around the vertex 206 to protect the balloon 260 from punctures. In yet another embodiment, the balloon could be made from a thick, self sealing latex rubber. Such latex compounds are well known in the industry.
The shaping device is not limited to polymeric balloon embodiments. FIG. 2g illustrates a shaping device 280 made from a wire skeleton or frame. The wire frame could be made from surgical grade stainless steel, titanium, tantalum, or nitinol, which is a commercially available nickel-titanium alloy material that has shape memory and is superelastic. Nitinol medical products are available from AMF of Reuilly, France, and Flexmedics Corp., of White Bear Lake, Minn.
The shaping device 280 illustrated in FIG. 2g is in an expanded condition. Running through the center of shaping device 280 is a main shaft 282. The main shaft 282 has a distal end 284 and a proximal end 286. At the distal end 284 is a joint 288. Coupled to the joint 288 is a series of back ribs 290 a though 290 h (only back ribs 290 a through 290 e are visible in FIG. 2g). Back ribs 290 a through 290 h are connected to front ribs 292 a-292 h by hinges 294 a though 294 h (only front ribs 292 a-292 e and hinges 294 a 294 e are visible in FIG. 2g). The proximal end of front ribs 292 a through 292 e are connected to a collar 296 through a series of hinges (not shown) radially spaced around collar 296. The use of hinges around collar 296 encourages front ribs 292 a-292 h to form a convex angle with respect to shaft 282 at collar 296.
FIG. 2h shows the shaping device 280 in a collapsed position. In a collapsed position, back ribs 290 a-290 h and front ribs 292 a-292 h surround shaft 282 as illustrated in FIG. 2j. FIG. 2j is a section view cut transversely through shaft 282 and the front ribs 292 a-292 h. In operation, once the shaping device 280 is inserted into the left ventricle, a surgeon may slide collar 296 along shaft 282 towards distal end 284. The force exerted on collar 296 will cause the ribs to buckle radially outward as illustrated in FIG. 2g. Eventually, the front ribs 292 a-292 h will bend under the applied force. Because the front ribs 292 a-292 h are under stress, they will tend to push the collar 296 towards proximal end 286. A lock 294 prevents any desired movement towards proximal end 286. Thus, the collar 296 is held firmly in place along shaft 282 by the front ribs 292 a-292 h exerting a force through collar 296 to lock 294. The lock 294 is spring (not shown) activated and is designed such that the collar 296 may easily slide over the lock when moving from the proximal end 286 to the distal end 284. When the surgeon is ready to remove the shaping device 280, the surgeon may collapse the shaping device 280 by pressing down on lock 294 which will allow the collar 296 to slide past the lock 294 towards the proximal end 286.
As will be explained in greater detail below, a patch is often used in the ventricle reconstruction procedure. A patch is made from sheet material and may be a variety of shapes, including circular, elliptical, or triangular, preferably sized and configured with a shape similar to a Fontan neck, as discussed below. As illustrated in FIG. 3a, an elliptical patch 300 may have a length between 30 and 50 millimeters along a major axis 302 and a width along a minor axis 304 of between 20 and 30 millimeters. The preferable thickness of the patch is in the range of 0.3 to 0.7 mm. The water permeability is preferably less than 5 ml per cm sq. per minute at 120 mm Hg. The burst strength of the patch is preferably 30 to 35 kg/cm2. Finally, the 45° angle suture retention strength of the patch should be greater than 3 kg.
In order to be useful, the markings must be arranged in a pattern that allows post operative evaluation. One such pattern is a series of equally spaced substantially parallel lines as illustrated in FIG. 3b. Another pattern is a grid of substantially parallel lines as illustrated in FIG. 3c. The distance between these parallel lines may be in standard units, such as 1 centimeter. Another pattern could be in the form of concentric circles, as illustrated in FIG. 3d. Yet, another pattern could be a series of lines radiating from a single point at, for instance, a set angle apart. Such a pattern is illustrated in FIG. 3e.
Turning now to FIG. 4a, there is illustrated a set of sizers 402 a-402 d. The sizers 402 a-402 d are shaped to be the approximate size of the patch 300 (FIG. 3a). Similar to the patch, the sizers 402 a-402 d will be of various geometries, length and width combinations. For illustrative purposes, the sizers 402 a-402 d discussed herein will be elliptical in shape. For posterior repairs to the ventricle, however, the sizers may have a general triangular shape. Referring back to FIG. 4a, the length of the sizers along a major axis 403 may be in the range of 2 to 7 cm in length. The length along a minor axis 405 may be 1 to 5 cm in length. The sizers may have a connection 406 for attachment to a handle 404 (FIG. 4b). The sizers 402 a-402 d can be made out of plastic or stainless steel or any rigid material. Four sizers 402 a-402 d are illustrated in FIG. 4a, however, any number of sizers in a variety of could be provided.
Turning now to FIG. 4b, the handle 404 may also be made from stainless steel, plastic or any other suitable material. The handle 404 includes a shaft 408 having a proximal end 410 and a distal end 412. The distal end 412 couples to the connection 406 of the sizers 402 a-402 d. The proximal end 410 is coupled to a hand grip 414. The hand grip 414 is sized to fit a human hand. Such hand grips are well known in the art. A surgeon may connect any of the sizers 402 a-402 d to the handle 404. The use of handle 404 with a sizer allows the surgeon to easily estimate the size of the opening to be patched by holding the sizer up to and into the opening. If the sizer is to small, another one may be selected. This process may be repeated until the surgeon feels he has a sizer of the correct shape and size. As will be explained in greater detail below, once the proper size has been determined the sizer may be placed on material and be used as a template to cut the patch 300 to the appropriate size.
FIG. 4c is a section view illustrating the connection 406 between the distal end 412 of shaft 408 and the sizer 402 a. In this embodiment, the connection 406 comprises a circular opening 422. Embedded in the walls of the opening 422 and running through the opening 422 is a rod 420. The rod 420 may be made of surgical stainless steel or another appropriate rigid material. In the illustrative embodiment, the distal end 412 includes a slot 425 with angular walls forming two flanges 423 a and 423 b. At the base of the slot 425 is a circular groove. The circular grove runs generally parallel to the slot 425 and has an interior diameter slightly larger than the exterior diameter of rod 420. The base of the slot 425 is slightly smaller than the diameter of rod 420. When distal end 412 is inserted into circular groove, flanges 423 a and 423 b slide over rod 420 until rod 420 is in the circular groove. Thus, flanges 423 a and 423 b are “snapped” over rod 420, and thus, will keep rod 420 in the cylindrical groove. The sizer 402 a may rotate with respect to shaft 408. The sizer 402 a may be removed from handle 404 by pulling on the sizer 402 a which causes a sufficient amount of force on rod 420 to lift flanges 423 a and 423 b over rod 420. In other embodiments, connection 406 may be a screw connection.
In another embodiment, the sizers may have a cutting edge which can be used to cut the patch 300 to the appropriate shape. Turning now to FIG. 4d, a sizer 430 is shown connected to the handle 408. In this embodiment, the sizer 430 may have a ridge 432 concentric to the shape of the sizer 430. The ridge 432 allows a surgeon to accurately estimate the size of the opening by placing the ridge 432 into the opening. The sizer 430 may also have a circumferential flange or lip 434 around the perimeter of the sizer to assist in defining the patch size. The patch will typically be slightly larger than the size of the opening. The width of the lip 434 will preferably have a constant width around its circumference, typically in the range between 5 and 8 centimeters. A cutting edge 436 may also be coupled to the perimeter of the lip. In operation, the surgeon may use the sizer as illustrated in FIG. 4d to estimate the size of the opening, remove die sizer 430 from the handle 408, turn the sizer 430 over with respect to the handle 408, and re-attach the sizer 430 to the handle 408. The cutting edge 436 may then be used to cut the patch material to the correct size and shape by pressing the cutting edge into the patch material.
FIG. 4e illustrates an embodiment of a sizer 440 having a protrusion 442 concentric to the shape of the sizer 440. The protrusion 442 may also be used to define a suture line on the patch material by pressing the protrusion 442 against the patch material causing an indentation in the patch material which the surgeon can use as a guide to suture the patch. Turning now to FIG. 4f, which illustrates embodiment of a sizer 450 having a slot or groove 452 concentric to the shape of the sizer. The groove 452 may be used by the surgeon to define a suture line by allowing the surgeon to use a marking instrument, such as a pen, to trace the suture line on the patch material.
FIG. 4g illustrates yet another embodiment of a sizer. The sizer 460 may be a malleable wire 462 coupled to movable legs 464 a-464 d (464 a and 464 b are visible in FIG. 4g). The moveable legs 464 a-464 d are coupled to a handle 466. The handle 466 includes a shaft 468 having a proximal end 470 and a distal end 472. The distal end 472 couples to the movable legs 464 a-464 d. The proximal end 470 is coupled to a hand grip 474. The hand grip 474 is similar to the handgrip 414 of FIG. 4b. FIG. 4h is a section view of the sizer 460 cut through the movable legs 464 a-464 d. The malleable wire 462 may be manipulated by the surgeon into any appropriate shape. Additionally, because one end 476 of the malleable wire 462 is free to slide past the moveable legs 464 a and 464 d, the perimeter of the shape formed by the wire may be lengthened or shortened as desired.
Turning now to FIG. 5a, there is illustrated a patch holder 500. The patch holder 500 comprises a patch plate 502 coupled to legs 504 a-504 d (504 a and 504 b are visible in FIG. 5a). The legs 504 a-504 d are coupled to a handle 506, which is similar to handle 466 discussed above. The patch plate 502 has an adhesive means on side 508, such as an adhesive backing or nylon hooks, which temporarily adheres to the patch. In operation, after a surgeon has constructed the appropriate patch, the surgeon may use patch holder 500 to place the patch into the opening, after suturing has begun, the patch holder may be removed, leaving the patch in place.
Turning now to FIG. 5b, there is illustrated a suture hook 520. The suture hook 520 is “L” shaped and made of stainless steel, plastic or another rigid material. The suture hook 520 has a long leg 522 which may be approximately 6 inches long. Coupled to long leg 522, is short leg 524 which may be in the range of one-eighth to one-quarter inch long. The suture hook 520 is adapted to be used to pull up on the sutures in the patch 300 to secure the patch 300 to the heart.
Referring now to FIGS. 7a and 7 b, which illustrates generally a method 700 for performing and using at least one embodiment of the present invention. At step 702, a surgeon determines the appropriate size for the patient's left ventricle based on the patient's height, weight, body surface area and other patient specific conditions (as discussed previously in reference to FIG. 2a). Once the patient's appropriate ventricle size has been determined, at step 704, the surgeon can then select the appropriate volume for the shaping device.
In step 714, the preferred location of the patch 300 is been determined relative to the circumferential line. In step 716, a continuous Fontan stitch may be placed in proximity to the line, along the long axis of the heart. The Fontan stitch produces an annular protrusion, which forms a neck relative to the circumferential line. The annular protrusion may be further defined by placing a rim support around its perimeter. This neck initially may have a round circular configuration. A second Fontan stitch may be placed 90 degrees from the initial stitch along the short axis of the heart. Other stitches may be placed as needed to form the heart to the shaping device. The stitch will serve to shape the heart along the short axis of the heart if needed.
In step 718, the shaping device 200 may then be inserted into the ventricle. The shaping device 200 is then inflated or expanded, the volume of which is equivalent to the appropriate volume of the ventricle for the patient. The shaping device 200 provides the model upon which the ventricle can be shaped and contoured through the use of the Fontan suture in step 720. The Fontan suture may then tightened with the aid of the suture hook 520, in step 722. As the suture or sutures are tightened, the musculature of the myocardium will form the physiologically correct volume, shape and contour over the shaping device. The appropriately oval-shaped opening in the neck defines the area where the patch will be placed. Once the suture is tightened down, the shaping device 200 may be collapsed and removed in step 724.
The size of the opening in the neck formed by the Fontan stitch will vary from patient to patient. If the patch 300 is used to close the ventricle, the surgeon should determine the size of the patch to be used (step 726). To determine the appropriate size of the patch, the surgeon may connect any of the sizers 402 a-402 d to the handle 404 to measure the size of the opening, and thus, the size patch 300 that is needed to fit into the neck formed by the Fontan stitch or stitches. In step 728, the surgeon may then construct a patch. In embodiments with different sizers, once the proper sizer has been selected, the sizer can be placed on the patch and be used as a template to cut the patch 300 to the appropriate size. Alternatively, a surgeon may select a precut patch.
When air evacuation is confirmed by transesophageal echo, the patient can be weaned off bypass usually with minimal, if any inotropic support. Decannulasation may be accomplished with conventional methods (step 736).
a cutting edge coupled to at least a portion of the lip and substantially concentric to the lip for cutting the patch during use.
2. The device of claim 1, wherein the sizing template comprises a major axis and a minor axis, wherein the major axis is between about 2 cm and about 7 cm in length, and wherein the minor axis is between about 1 an and about 5 cm in length.
3. The device of claim 1, wherein the sizing template comprises a substantially inflexible material.
4. The device of claim 1, wherein the handle comprises a shaft and a grip, and wherein the shaft comprises a distal end coupled to the sizing template and a proximal end coupled to the grip.
5. The device of claim 1, wherein the handle comprises a shaft and a grip, wherein the shaft comprises a distal end coupled to the sizing template and a proximal end coupled to the grip, and wherein the grip is configured to fit a human hand.
6. The device of claim 1, wherein the sizing template comprises stainless steel.
7. The device of claim 1, wherein the sizing template comprises plastic.
8. The device of claim 1, wherein the handle is coupled to the sizing template with a screw connection.
9. The device of claim 1, wherein the handle is coupled to the sizing template with a resistance connection.
10. The device of claim 1, wherein at least a portion of the periphery of the sizing template comprises an elongated member.
11. The device of claim 1, wherein at least a portion of the periphery of the sizing template comprises an elongated member, and wherein a size of the periphery of the sizing template is adjustable.
closing at least a portion of the opening using at least a portion of the patch, such that the enlarged left ventricle is substantially reconstructed into a shape and volume of an appropriate left ventricle.
13. The method of claim 1, wherein determining the size and shape of the opening using a sizing template comprises trying sizing templates with different sized peripheries.
14. The method of claim 1, wherein determining the size and shape of the opening using a sizing template comprises trying sizing templates with different shaped peripheries.
15. The method of claim 12, further comprising cutting the patch to a desired shape and size.
16. The method of claim 12, further comprising tracing at least a portion of a suture line onto the patch.
17. The method of claim 12, further comprising tracing at least a portion of a suture line onto the patch and attaching at least a portion of the patch to the left ventricle using at least a portion of the suture line as a guide for a suture.
19. The method of claim 18, wherein determining the size and shape of the opening using a sizing template comprises trying sizing templates with different sized peripheries.
20. The method of claim 18, wherein determining the size and shape of the opening using a sizing template comprises trying sizing templates with different shaped peripheries.
21. The method of claim 18, further comprising tracing at least a portion of a suture line onto the patch.
22. The method of claim 18, further comprising tracing at least a portion of a suture line onto the parch and attaching at least a portion of the patch to the left ventricle using at least a portion of the suture line as a guide for a suture.
24. The method of claim 23, wherein determining the size and shape of the opening using a sizing template comprises trying sizing templates with different sized peripheries.
25. The method of claim 23, wherein determining the size and shape of the opening using a sizing template comprises trying sizing templates with different shaped peripheries.
27. The method of claim 26, wherein determining the size and shape of the opening using a sizing template comprises trying templates with different sized peripheries.
28. The method of claim 26, wherein determining the size and shape of the opening using a sizing template comprises trying sizing templates with different shaped peripheries.
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