FIELD
The claimed invention relates to minimally invasive surgical devices, and more specifically to a surgical device used in vessel harvesting surgical procedures.
BACKGROUND
Minimally invasive surgical approaches are gaining increased interest in relation to coronary procedures. Coronary revascularization procedures such as the grafting of the internal thoracic artery (ITA) has shown superior long-term patency and improved patient outcome in coronary artery bypass graft (CABG) surgeries. While conventional approaches to ITA harvesting have included median sternotomy or multiple thoracoports, a minimally invasive approach is desirable. A minimally invasive procedure related to revascularization using either the left or right internal thoracic artery (ITA), or the left or right internal mammary artery (IMA) may utilize access to the ITAs via sub-xiphoid access, where increased surgical space is gained by accessing the internal thoracic arteries via incision at the subxiphocostal region.
Upon harvesting either the left internal thoracic artery (LITA) or the right internal thoracic artery (RITA) anastomoses to the left anterior descending (LAD) coronary artery and to the right coronary artery (RCA), respectively, can be performed without cardiopulmonary bypass (CPB). A significant advantage of this approach is that a perfectly harvested ITA graft can be perfectly anastomosed to the usual site on the LAD artery, or onto the RCA artery. A minimally invasive ITA harvesting procedure involving sub-xiphoid access also results in superior cosmetic results, is reasonably painless, and the arterial grafting can be accomplished on the beating heart. Recent approaches of minimally invasive ITA harvesting surgical techniques have been shown to result in increased effective length of ITA bypasses, reduced operation times, and improved patient recovery.
While less invasive surgical approaches for ITA harvesting and CABG have shown promise, the visualization, maintenance of insufflation, and distal suturing of a coronary anastomosis in totally endoscopic coronary artery bypass grafting on the beating heart is technically demanding. While minimally invasive surgical tools and procedures can create larger working spaces to accommodate additional surgical tools such as endoscopes, suturing tools, and the like. However, achieving an increased working space should ideally preserve chest wall integrity and avoid CPB. Likewise, a minimally invasive surgical approach should not compromise the reliability of a cardiac repair. Therefore, there is a need for suitable surgical tools to aid in the take-down or harvesting of ITA during minimally invasive harvesting and revascularization surgical procedures.
SUMMARY
A device for vessel harvesting is disclosed. The device for vessel harvesting may include a distal housing, a dissector coupled to the distal housing, a drive element coupled to the dissector, and an actuator coupled to the drive element.
Another device for vessel harvesting is disclosed, which may include a distal housing defining a rotatable dissector, a shaft coupled to the distal housing may further include a first articulation joint movable within a first plane, and a second articulation joint movable within a second plane, which is substantially perpendicular to the first plane, a barrel chain drive element coupled to the rotatable dissector, and an actuator coupled to the drive element.
Another device for vessel harvesting is disclosed. The device for vessel harvesting may include a shaft and a dissector coupled to the shaft.
Another device for vessel harvesting is disclosed. The device for vessel harvesting may include a shaft, a distal tip defining an arcuate finger coupled to a distal end of the shaft, and a member slidably engaged to the distal tip.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a top-left-front perspective view of one embodiment of a minimally invasive surgical device.
FIGS. 2A-2C are a series of exploded views illustrating the assembly steps of the minimally invasive surgical device of FIG. 1.
FIGS. 3A and 3B are side cross-sectional and top cross-sectional views, respectively, of the minimally invasive surgical device of FIG. 1, illustrating the operational principles of the minimally invasive surgical device.
FIGS. 3C and 3D are side cross-sectional and top cross-sectional views, respectively, of the minimally invasive surgical device of FIG. 1, illustrating the operational principles of the minimally invasive surgical device.
FIGS. 3E and 3F are side cross-sectional and top cross-sectional views, respectively, of the minimally invasive surgical device of FIG. 1, illustrating the operational principles of the minimally invasive surgical device.
FIGS. 4A-4C are partial cross-sectional top views of alternate embodiments of drive mechanisms for a minimally invasive surgical device.
FIGS. 5A-5H are side views of alternate embodiments of dissectors for a minimally invasive surgical device.
FIG. 6 is a top-left-front perspective view of another embodiment of a minimally invasive surgical device.
FIG. 7 is a top-left-front perspective of another embodiment of a minimally invasive surgical device.
FIG. 8 is a top-left-front perspective of another embodiment of a minimally invasive surgical device.
FIG. 9 is a top-left-front perspective of another embodiment of a minimally invasive surgical device.
FIGS. 10A-10B are side partial cross-sectional views of a distal end of the minimally invasive surgical device of FIG. 9, illustrating a closed and opened position, respectively.
FIG. 11 is a top-left-front perspective view of another embodiment of a minimally invasive surgical device.
FIG. 12 is an exploded view of a distal end of the minimally invasive surgical device of FIG. 11.
FIGS. 13A and 13B are top-left-front perspective views focused on an assembled distal end of the minimally invasive surgical device of FIG. 11 in an open and closed position, respectively.
FIGS. 14A and 14B are a side cross-sectional view and front end view, respectively, of the minimally invasive surgical device of FIG. 11 in an open position.
FIGS. 15A and 15B are a side cross-sectional view and front end view, respectively, of the minimally invasive surgical device of FIG. 11 in a closed position.
FIG. 16 is an enlarged side view of a portion of the shaft of the minimally invasive surgical device of FIG. 11.
FIGS. 17A and 17B are side views of a further embodiment of a minimally invasive surgical device having an embodiment of a selective locking mechanism.
FIGS. 18A to 18C are various views of a lever protrusion of the embodiment of the selective locking mechanism of FIG. 17A.
FIGS. 19A to 19B are various views of a locking arm of the embodiment of the selective locking mechanism of FIG. 17A.
FIGS. 20A to 20G are various views of the interaction of the locking arm and the lever protrusion of the embodiment of the selective locking mechanism of FIG. 17A.
FIGS. 21A to 21F are various views of the interaction of the locking arm and the lever protrusion of the embodiment of the selective locking mechanism of FIG. 17A.
FIGS. 22A to 22D are various views of a lever having a lever protrusion of the embodiment of the selective locking mechanism of FIG. 17A.
FIGS. 23A to 23D are various views of a locking arm of the embodiment of the selective locking mechanism of FIG. 17A.
It will be appreciated that for purposes of clarity and where deemed appropriate, reference numerals have been repeated in the figures to indicate corresponding features, and that the various elements in the drawings have not necessarily been drawn to scale in order to better show the features.
DETAILED DESCRIPTION
FIG. 1 is a top-left-front perspective view of one embodiment of a minimally invasive vessel harvesting device 10. The minimally invasive vessel harvesting device 10 has a housing 12 which extends down to form a handle 14. The device also has an actuation lever 16 pivotably coupled to the handle 14. The minimally invasive vessel harvesting device 10 also has a shaft 18 which is coupled to the housing 12. The minimally invasive vessel harvesting device 10 has a distal tip housing 20 on the opposite end of the shaft 18 which defines a blunt dissector 22 used in a minimally invasive surgical procedure involving the harvesting of IMA for revascularization. The blunt dissector 22 is coupled to the actuation lever 16, and movement of the actuation lever 16 will rotate the blunt dissector 22 to achieve adjustable positioning of the blunt dissector 22 during use in a minimally invasive cardiovascular procedure such as the harvesting of internal thoracic arteries. This mechanism will be described in further detail. The blunt dissector 22 is an arcuate or curved appendage that has a smooth, atraumatic tip allowing for and enabling the gentle manipulation and separation of tissue, while preventing damage to anatomical features and structures surrounding the tissue of interest. Blunt dissection, in general, refers to an element of surgical procedure where careful separation of tissues is accomplished with the use of fingers or blunt surgical tools. The blunt dissector tip is useful in procedures related to ITA/IMA take-down or harvesting procedures. The shape, maneuverability, and atraumatic nature of the blunt dissector 22 are features that contribute to improved utility, reduced risk of harming surrounding tissue, and achieving positive results during a minimally invasive surgical procedure. While the blunt dissector 22 shown in FIG. 1 is an atraumatic, arcuate appendage, or gentle finger, other embodiments may be blunt, partially blunt, or have partial edges. Still other embodiments may have portions or edges that may be partially sharpened or shaped as needed for their intended surgical procedure. While an actuation lever is shown in this embodiment, other embodiments may include an actuator such as a lever, sliding rod, knob, pulley, gear, solenoid, motor, or other actuator known to those skilled in the art.
FIGS. 2A-2C are a series of exploded views illustrating the assembly steps of the minimally invasive surgical device of FIG. 1. FIG. 2A illustrates the assembly steps of the distal tip housing 20 of the minimally invasive vessel harvesting device 10. A blunt dissector 22 defining an upper dissector 28, lower dissector 30, and having an inner surface 32 also defines a dissector base 24 and a hub 26. A gear assembly 34 defining a gear shaft 36 having an upper gear 38, lower gear 40 and capstan 42 is placed inside the inner diameter of the hub 26 on the blunt dissector 22. The upper gear 38 has several teeth 44 and recesses 45 interposed between the teeth 44. Likewise, the gear 40 also has several teeth 46 and recesses 47 interposed between the teeth 46. A pin 84 is inserted into hole 25 on the blunt dissector 22 and into a corresponding hole 37 on the gear assembly 34. While a pin is used to assemble these components, other means of assembly may also be used, such as adhesion, welding, or utilizing a single component in another embodiment that defines the dissector and the gear assembly. Next, the blunt dissector 22 and gear assembly 34 are placed into a hole 54 on a distal end 48D of an upper distal tip housing 48. The upper distal tip housing 48 also defines an alignment guide 50, a side wall 56, and a tube portion 58 at a proximal end 48P. The tube portion 58 further defines an internal channel 52.
FIG. 2B illustrates the continued assembly of the minimally invasive vessel harvesting device 10 of FIG. 1. A drive element, in this embodiment a barrel chain 60, having several barrel 62 portions interposed between several tab 64 portions along a wall 66 of the barrel chain 60 is placed inside the upper distal tip housing 48 such that the wall 66 of the barrel chain 60 rides against the side wall of the upper distal tip housing 48 opposite side wall 56, the barrels 62 are captured in the recesses 47 between the teeth 46 on the lower gear 40 and also in the recesses 45 between the teeth 44 on the upper gear 38 (although not visible in this view), around the gear assembly and against the side wall 56 of the upper distal tip housing 48. It should be noted that the tabs 64 are sized and configured such that they will provide stiffness to the barrel chain 60 as well as maintain alignment and tracking of the barrel chain 60 in the capstan 42 portion, not visible here, of the gear assembly 34. A drive coupler 68 having a drive element coupler 70 and a drive rod coupler 72 at the end of a drive rod slot 74 is coupled to the end of the barrel chain 60 by fitting the drive element coupler 70 of the drive coupler 68 over the terminating barrel 62 in the barrel chain 60. A drive rod 76 having a ball end 78 at the distal end 76D of the drive rod 76 is captured in the drive rod coupler 72 by placing the ball end 78 into the drive rod coupler 72 and guiding the drive rod 76 through the drive rod slot 74 on the drive coupler 68. The drive rod 76 and the drive coupler 68 are freely movable within the channel 52 inside the tube portion 58 of the upper distal tip housing 48. A lower distal tip housing 80 having a tube portion 82 at a proximal end 80P is fixedly attached to the upper distal tip housing 48, completing the assembly of the upper distal tip housing 48. FIG. 2C illustrates another assembly step in the minimally invasive vessel harvesting device 10. The distal tip housing tube 86 with the drive rod 76 protruding is inserted into a shaft opening 90 of a distal end 18D of the shaft 18 on the minimally invasive vessel harvesting device 10. This distal tip housing tube 86 is fixedly attached to the shaft 18 by welding, brazing or other methods known to those skilled in the art. Further assembly steps of the device including the handle, lever and other components is well known to those skilled in the arts of minimally invasive vessel harvesting devices. It should be noted that while a barrel chain drive is described in regard to the embodiment described herein, that other drive elements or drive mechanisms may also be used in other embodiments of the minimally invasive vessel harvesting device. The embodiment shown has a monolithic, or single piece barrel chain as the drive element. A drive element could include a chain or a belt, a coupler, a drive rod or a combination thereof. Alternate drive attachments to the gear assembly including the capstan and gears shown herein may be used, for example, slotted shafts or spools, cylindrical bearings or bushings, or other rotatable shafts known to those skilled in the art. Any structural element suitable for extending from or attaching to the blunt dissector for the purpose of attaching a drive element to and rotating the blunt dissector would be a suitable drive attachment. Alternative drive elements to the barrel chain and drive coupler may also be used as drive elements in other embodiments of the minimally invasive vessel harvesting device described herein. Stiff belts, rods, wires, linked chains, or other linkages known in the art capable of pushing or pulling on a drive attachment coupled to a blunt dissector may be used as drive elements in alternate embodiments.
FIGS. 3A and 3B are side cross-sectional and top cross-sectional views, respectively, of the minimally invasive vessel harvesting device of FIG. 1, illustrating the operational principles of the minimally invasive vessel harvesting device. FIG. 3A illustrates the invasive vessel harvesting device 10 in a neutral position with respect to the position of the actuation lever 16 and the blunt dissector 22. The actuation lever 16 is in a position partially away from the handle 14, and the blunt dissector 22 is oriented in a position such that it is aligned with the shaft 18 of the minimally invasive vessel harvesting device 10. The internal components of the actuation lever 16 are also visible in the cross-sectional view of FIG. 3A. The actuation lever 16 is pivotably coupled about a pivot 92 and also defines a lever gear 94 with several lever gear teeth 96. A drive gear 100 pivots about a pivot point 88, and the drive gear 100 defines several teeth 101 and a drive gear coupler 102. The teeth 101 on the drive gear 100 engage with the teeth 96 on the lever gear 94. The drive rod 76 has a drive rod coupling ball 98 on its proximal end 76P, which is held within the drive gear coupler 102.
FIG. 3B is a top cross-sectional view of the upper distal tip housing 48, illustrating the position of the components within the upper distal tip housing 48, particularly the blunt dissector 22 corresponding to the lever position shown in FIG. 3A. It should be noted that in this position shown in FIG. 3B, the blunt dissector 22 is oriented in such a fashion that the arcuate portion of the blunt dissector 22 is aligned with the shaft 18 of the minimally invasive vessel harvesting device 10, at an angle of approximately 0 degrees in reference to the angle indicator shown in FIG. 3B.
FIGS. 3C and 3D are side cross-sectional and top cross-sectional views, respectively, of the minimally invasive vessel harvesting device of FIG. 1, illustrating the operational principles of the minimally invasive vessel harvesting device. FIG. 3C illustrates the invasive vessel harvesting device 10 in a rotated position with respect to the position of the actuation lever 16 and the blunt dissector 22. The actuation lever 16 is in a position squeezed in a direction 104 towards the handle 14, and the blunt dissector 22 is oriented in a position such that it is rotated clockwise in reference to the shaft 18 of the minimally invasive vessel harvesting device 10. When the lever 16 is squeezed towards the handle 14, the lever gear 94 engages lever drive gear 100 and rotates the lever drive gear 100 in direction 106. Since the lever drive gear 100 is coupled to the drive rod 76, the drive rod 76 is pulled in direction 108. FIG. 3D is a top cross-sectional view of the upper distal tip housing 48, illustrating the position of the components within the upper distal tip housing 48, particularly the blunt dissector 22 corresponding to the lever position shown in FIG. 3C. As drive rod 76 is pulled in direction 108, drive coupler 68 is also pulled in direction 108 as the ball end 78 of the drive rod 76 is coupled to the drive coupler 68. The barrel chain 60 is also pulled in direction 108, as the barrel chain 60 coupled to the drive element coupler 70 on the drive coupler 68. Thus, the blunt dissector 22 is rotated in direction 110 as the barrel chain 60 engages with the teeth 46 on lower gear 40, being at an angle of approximately 135 degrees in reference to the angle indicator shown in FIG. 3D.
FIGS. 3E and 3F are side cross-sectional and top cross-sectional views, respectively, of the minimally invasive vessel harvesting device of FIG. 1, illustrating the operational principles of the minimally invasive vessel harvesting device. FIG. 3E illustrates the invasive vessel harvesting device 10 in another rotated position with respect to the position of the actuation lever 16 and the blunt dissector 22. The actuation lever 16 is in an open moved in a direction 112 away from the handle 14, and the blunt dissector 22 is oriented in a position such that it is rotated counterclockwise in reference to the shaft 18 of the minimally invasive vessel harvesting device 10. When the lever 16 is moved away from the handle 14, the lever gear 94 engages lever drive gear 100 and rotates the lever drive gear 100 in direction 114. Since the lever drive gear 100 is coupled to the drive rod 76, the drive rod 76 is pushed in direction 116. FIG. 3F is a top cross-sectional view of the upper distal tip housing 48, illustrating the position of the components within the upper distal tip housing 48, particularly the blunt dissector 22 corresponding to the lever position shown in FIG. 3E. As drive rod 76 is pushed in direction 116, drive coupler 68 is also pushed in direction 116 as the ball end 78 of the drive rod 76 is coupled to the drive coupler 68. The barrel chain 60 is also pushed in direction 116, as the barrel chain 60 coupled to the drive element coupler 70 on the drive coupler 68. The tabs 64 on the barrel chain 60, as previously described, provide additional support and stiffness to the barrel chain 60 and allow the chain to be pushed. Thus, the blunt dissector 22 is rotated in direction 118 as the barrel chain 60 engages with the teeth 46 on lower gear 40, at an angle of approximately -135 degrees in reference to the overlaid angle indicator shown in FIG. 3F. The embodiment described herein has a blunt dissector 22 which is pivotable relative to the distal housing and is pivotable in a rotation range of about 270 degrees in reference to the overlaid angle indicator shown in FIGS. 3B, 3D, and 3F. This rotation of the blunt dissector 22 is pivotable about a plane that is substantially parallel to the distal housing. Other embodiments including a rotatable dissector such as the one described herein may be configured to rotate over a full range of about 210 degrees, about 270 degrees or about 360 degrees. The rotation range of the blunt dissector 22 enables a precise control over the articulation and position of the blunt dissector during surgical procedures involving vessel harvesting.
FIGS. 4A-4C are partial cross-sectional top views of alternate embodiments of drive mechanisms for a minimally invasive vessel harvesting device. FIG. 4A is a partial cross-sectional top view of a belt drive element 120 which is coupled to a drive shaft 122 similar to the capstan of the embodiment of a vessel harvesting device as shown in FIGS. 1-3F. This drive shaft 122 has a capstan slot 124 into which the belt drive element 120 is fixedly attached.
FIG. 4B is a partial cross-sectional top view of a segmented chain drive 126 which is coupled to a gear assembly drive shaft 123 similar to the capstan of the embodiment of a vessel harvesting device as shown in FIGS. 1-3F. This segmented chain drive 126 has a gear assembly drive shaft 123 around which the segmented chain drive 126 is coupled. The segmented chain drive 126 is made of several links 128. Each link 128 defines a clasp 13 having a recess 132, a support tab 134, and a peg 136. Each link 128 is connected to another subsequent link 128 by connecting a tab 136 one link 128 to a recess 132 on the subsequent link 128.
FIG. 4C is a partial cross-sectional top view of another embodiment of a barrel chain 138 comprised of a single piece having several barrels 140 disposed upon a chain wall 142 and spaced such that they engage with and couple to with the gears on a gear assembly drive shaft 125, similar to the capstan of the embodiment of a vessel harvesting device as shown in FIGS. 1-3F.
FIGS. 5A-5H are side views of alternate embodiments of dissectors for a minimally invasive vessel harvesting device. FIG. 5A is a side view of an alternate embodiment of a dissector for a minimally invasive vessel harvesting device. FIG. 5A shows a dissector 144 having a dissector base 146, an upper dissector 148, and a lower dissector 150. The dissector 144 also defines an inner surface 152. This dissector 144 has an arcuate, C-shaped profile with an opening on one side. FIG. 5B is a side view of an alternate embodiment of a dissector for a minimally invasive vessel harvesting device. FIG. 5B shows a dissector 154 having a dissector base 156, an upper dissector 158, and a lower dissector 160. The dissector 144 also defines an inner surface 152. This dissector 144 has an arcuate, C-shaped profile with an opening facing a slightly downward angle. FIG. 5C is a side view of an alternate embodiment of a dissector for a minimally invasive vessel harvesting device. FIG. 5C shows a dissector 164 having a dissector base 166, an upper dissector 168, and a lower dissector 170. The dissector 164 also defines an inner surface 172. This dissector 164 has an angular square-like profile with a side facing opening. FIG. 5D is a side view of an alternate embodiment of a dissector for a minimally invasive vessel harvesting device. FIG. 5D shows a dissector 174 having a dissector base 176, an upper dissector 178, a lower dissector 180. The dissector 174 also defines an inner surface 182. This dissector 174 has an angular, L-shaped profile. FIG. 5E is a side view of an alternate embodiment of a dissector for a minimally invasive vessel harvesting device. FIG. 5E shows a dissector 184 having a dissector base 186, an upper dissector 188, a lower dissector 190. The dissector 184 also defines an inner surface 192. This dissector 184 has an arcuate, C-shaped profile with a side facing opening. FIG. 5F is a side view of an alternate embodiment of a dissector for a minimally invasive vessel harvesting device. FIG. 5F shows a dissector 196 having a dissector base 198, an upper dissector 200, a lower dissector 202. The dissector 196 also defines an inner surface 204. This dissector 196 has an arcuate, C-shaped profile with a side facing opening. FIG. 5G is a side view of an alternate embodiment of a dissector for a minimally invasive vessel harvesting device. FIG. 5G shows a dissector 208 having a dissector base 210, an upper dissector 212, a lower dissector 214. The dissector 208 also defines an inner surface 216. This dissector 208 has an arcuate, C-shaped profile with a downward facing opening. FIG. 5H is a side view of an alternate embodiment of a dissector for a minimally invasive vessel harvesting device. FIG. 5H shows a dissector 226 having a dissector base 222, an upper dissector 224, a lower dissector 220. The dissector 224 also defines an inner surface 218. This dissector 224 has an arcuate, half C-shaped profile. Alternate embodiments of dissectors may have shapes such as L-shaped, corkscrew, or have sharper angles than embodiments directly illustrate herein. The inner surface of some of the alternate embodiments of the dissectors described herein may have smooth, textured, or conformable surfaces. Alternate embodiments of dissectors may be composed of materials such as plastic, metal, ceramic, composites, or combinations thereof.
FIG. 6 is a top-left-front perspective view of another embodiment of a minimally invasive vessel harvesting device 228. The minimally invasive vessel harvesting device 228 has a housing 230 which extends down to form a handle 232. The device also has an actuation lever 234 which operates in a similar fashion as previous embodiments described herein. The minimally invasive vessel harvesting device 228 also has a shaft 242 which is coupled to the housing 230 by a rotational adapter which is not completely visible in this view, but is known to those skilled in the art. An indicator fin 236 of the rotational adapter can be seen in this view, however. The minimally invasive vessel harvesting device 228 has a distal tip housing 254 which is pivotably coupled to a distal shaft portion 244 by a second articulation joint 248. The distal tip housing has a blunt dissector 252 similar to those described previously herein. The distal shaft portion 244 is pivotably coupled to the shaft 242 by a first articulation joint 246. The first articulation joint 246 is operationally coupled to a first articulation knob 238 such that rotation of the first articulation knob 238 causes the first articulation joint 246 to articulate the distal shaft portion 244 in a first plane 250. The second articulation joint 248 is operationally coupled to a second articulation knob 240 such that rotation of the second articulation knob 240 causes the second articulation joint to articulate the distal tip housing 254 in a second plane 256. In this example, the first plane 250 is substantially perpendicular to the second plane 256. In other embodiments having two articulation joints, the two articulation planes may not be substantially parallel. Other embodiments may have more or fewer, including none, articulation joints. The articulation joints in other embodiments may be capable of movement in more than one plane. Embodiments of rotation adapters and minimally invasive surgical devices are known to those skilled in the art.
FIG. 7 is a top-left-front perspective of another embodiment of a minimally invasive surgical device. The minimally invasive vessel harvesting device 260 has a housing 262 which forms an ergonomic handle 264. The device also has a channel 266 which is configured to provide a path for a sliding member 270 to slide longitudinally along the device 260 from its distal end 260D to its proximal end 260P. The channel 266 also defines several positioning recesses 268 which correspond to mating features on the sliding member 270. This aspect of the design provides a means to slide the sliding member 270 along the channel 260, while locking the position of the sliding member 270 if desired. The minimally invasive vessel harvesting device 260 also has a shaft 274 which is coupled to the housing 262. The shaft 274 extends towards the distal end 260D of the minimally invasive vessel harvesting device 260 and has a secondary shaft 276 coupled to the shaft 274. Coupled to the secondary shaft 276 is a distal tip 278 which defines a u-shaped or protuberant, arcuate finger 280 extending in an arcuate fashion. The arcuate curvature of the finger 280 is formed in a direction substantially perpendicular to the distal tip 278 and perpendicular to the shaft 274 and secondary shaft 276 and may be considered as and used as a blunt dissector. While the arcuate finger 280 does not close at both ends in contact with the distal tip 278, a gliding member 282 provides such a closure. The gliding member 282 is coupled to the sliding member 270 and configured such that when the sliding member 270 is moved towards the proximal end 260P, the gliding member 282 also moves towards the proximal end 260P of the minimally invasive vessel harvesting device 260. When the gliding member 282 moves in a direction towards the proximal end 260P of the minimally invasive vessel harvesting device 260, the arcuate finger 280 is open. This open position allows for the minimally invasive vessel harvesting device 260 to be placed around a vessel such as an IMA to place the arcuate finger 280 around the vessel during a harvesting or takedown procedure. When the gliding member 282 moves in a direction towards the distal end 260D of the minimally invasive vessel harvesting device 260, the arcuate finger 280 is in a position that in combination with the position of the arcuate finger 280 forms a closed loop. This closed loop position allows for the operator of the minimally invasive vessel harvesting device 260 to hold or secure a vessel such as an IMA in place within the closed loop formed by the gliding member 282 and the arcuate finger 280 during a harvesting or takedown procedure. In other embodiments the loop formed by the gliding member 282 and the arcuate finger 280 may be substantially parallel to the shaft 274 of the minimally invasive vessel harvesting device 260, or at a position somewhere between substantially parallel and substantially perpendicular. Other embodiments may not form an arcuate loop and may form closures or loops of differing shapes.
FIG. 8 is a top-left-front perspective of another embodiment of a minimally invasive surgical device. The minimally invasive vessel harvesting device 286 has a housing 288 which forms an ergonomic handle 290. The minimally invasive vessel harvesting device 286 also has a shaft 292 which is coupled to the 288. The shaft 292 extends towards the distal end 286D of the minimally invasive vessel harvesting device 286. Coupled to the shaft 292 are several arcuate shaped blunt dissectors or omega-shaped fingers 296, 302, 308. These are referred to as omega-shaped due to their similarity to the Greek letter omega. They may also be referred to as c-shaped or u-shaped. The arcuate curvature of the fingers 296, 302, 308 are formed in a direction substantially perpendicular to the shaft. A first omega-shaped finger 296 is coupled to the shaft 292 by a first tubular mount 294 and defines an opening 298. A second omega-shaped finger 302 is coupled to the shaft 292 by a tubular mount 300 and defines an opening 304. A third omega-shaped finger 308 is coupled to the shaft 292 by a tubular mount 306 and defines an opening 310. The openings 298, 304, 310 formed by each of the omega-shaped fingers 296, 302, 308 allows for the minimally invasive vessel harvesting device 286 to be placed around a vessel such as an IMA in one or more locations to place one or more of the omega-shaped fingers 296, 302, 308 around the vessel during a harvesting or takedown procedure to temporarily hold or secure the vessel in a desired placement or position. In other embodiments the opening formed by the fingers 296, 302, 308 may be substantially parallel to the shaft 292 of the minimally invasive vessel harvesting device 286, or at a position somewhere between substantially parallel and substantially perpendicular. Other embodiments of fingers may not form an arcuate loop and may form closures or loops of differing shapes.
FIG. 9 is a top-left-front perspective of another embodiment of a minimally invasive surgical device. The minimally invasive vessel harvesting device 312 has a housing 314 at a proximal end 312P, the housing forming an ergonomic handle 316. The device 312 also has an articulation lever 318 disposed within the housing 314 and a rotation adaptor knob 320. The rotation adaptor knob 320 can be rotated around a longitudinal axis of an attached shaft 322 to enable rotatable positioning of the shaft 322 and therefore a distal end 312D of the device 312. The hollow shaft 322 is mounted onto the rotation adaptor knob 320 and contains a rigid rod or drive wire which is not visible here but will be described later in more detail. Along the shaft 322, closer to the housing 314, is a first plurality of horizontal articulation joints 324 each composed of several slits 324S. Further towards the distal end 312D of the device 312, also located along the shaft 322, is a second plurality of vertical articulation joints 326 each composed of several slits 326S. The first plurality of articulation joints 324 articulate in a plane substantially perpendicular to or substantially horizontal in relation to a plane bisecting the housing 314 or in line with the lever 318. The second plurality of articulation joints 326 articulate in a plane substantially parallel to or substantially vertical in relation to a plane bisecting the housing 314. These articulation joints 324, 326 are constructed of slits 324S, 326S in the desired direction of articulation. It should be noted that upon rotation of the rotation adaptor knob 320 this aforementioned relationship of the direction of articulation between the shaft 322 and the directions of articulation become offset by the amount of rotation. In the case of the embodiment shown in FIG. 9, each partial rotation of the rotation adaptor knob 320 rotates the shaft 322 sixty degrees about a longitudinal axis defined by the shaft 322, although alternate embodiments may have different extents of partial rotation. Alternate embodiments of an articulating shaft 322 may include varying numbers of slits, for example, from about 1 to about 10, from about 3 to about 8, or from about 5 to about 7. The slits 324S, 326S are defined by partial circumferential segmentation of the outer surface of the hollow rigid shaft 322. While the articulation feature in this embodiment consists of multiple slits for each joint, the articulation feature in alternate embodiments may also include other articulating joint constructions configured to be similarly positioned, such as hinges, flexible shaft materials, and other types of articulating joint construction known to those skilled in the art, and will also be configured such that the shaft 322 can be formed into a desired shape or angle of approach for the surgical procedure, and will remain in the set configuration until intentionally moved to a different shape or angle of the shaft 322. While these articulation joints 324, 326 move and are configured to be positioned in the aforementioned planes, alternate arrangements of articulation joints may be used in alternate device embodiments. For example, horizontal articulation joints may be located closer to the distal tip 328 while vertical articulation joints may be located closer to the housing 314, vertical and horizontal articulation joints may alternate along the shaft, or varying numbers of each may be present in alternate device embodiments. Further towards the distal end 312D of the device 312 is a distal tip 328 fixedly mounted onto the shaft 322. The distal tip 328 includes an arcuate finger 330 and a slidably engaged gliding member 332 which reversibly form a channel or opening 334 defined by the combination of the gliding member 332 and the arcuate finger 330 in the position shown in FIG. 9. The enclosed channel or opening 334 is configured to retain a vessel, artery, or other anatomical feature within the channel or opening 334. The vessel, artery, or other anatomical feature can be released by actuating the lever 318. As the lever 318 of the device 312 is squeezed towards the handle 316, the gliding member 332 moves along a cam path 336 defined by the distal tip 328 to open and allow entry or passage of a vessel or other anatomical feature into the channel or opening 334 defined by the distal tip 328. Further details of this movement are detailed in regard to FIGS. 10A and 10B.
FIGS. 10A-10B are side partial cross-sectional views of a distal end of the minimally invasive surgical device of FIG. 9, illustrating a closed and opened position, respectively. FIG. 10A illustrates the arrangement of the distal tip 328 when the lever 318 of the device 312 is in the unsqueezed position, with lever 318 positioned away from the handle 316. The drive wire 342 is coupled to the gliding member 332 and is fully extended towards the distal end 312D of the device 312. This arrangement maintains the gliding opening 334 at the distal tip 328 of the device 312, with the gliding member 332 and the arcuate finger 330 completing a full closure around the channel or opening 334. In this configuration, a vessel can be entrained within the opening 334 for holding or other desired surgical manipulation, for example, during a vessel harvesting minimally invasive surgical procedure. When the lever 318 is squeezed towards the handle 316 of the device 312, the drive wire 342 and also the connected gliding member 332 are caused to slide or move in direction 338, towards the proximal end 312P of the device 312.
FIG. 10B illustrates the position of the features and elements of the distal tip 328 of the device 312 once the handle 316 is squeezed towards the handle 316. As the drive wire 342 moves in direction 338, the gliding member 332 moves along with the drive wire 342 along the cam path 336 defined by the distal tip 328. The cam path 336 is configured such that the gliding member 332 rotates away from the distal tip 328 in direction 340 as the inner surface of the gliding member 332 interferes with the defined path of the cam path 336. This movement in direction 338 and substantially simultaneous rotation in direction 340 allows for additional clearance to open the opening 334 for a vessel or other anatomical feature to be placed within the opening 334 on the distal tip 328 of the device 312. When the desired anatomical feature is placed into the opening 334, the lever 318 can be released by the user of the device 312 and position of the distal tip 328 returns to the position illustrated in FIG. 10A, effectively trapping or capturing the anatomical feature securely in the opening 334 of the distal tip 328.
FIG. 11 is a top-left-front perspective view of another embodiment of a minimally invasive surgical device. The minimally invasive vessel harvesting device 344 has a housing 346 at a proximal end 344P, the housing forming an ergonomic handle 348. The device 344 also has an articulation lever 350 disposed within the housing 346 and a rotation adaptor knob 352. The rotation adaptor knob 352 can be rotated around a longitudinal axis of an attached shaft 354 to enable rotatable positioning of the shaft 354 and therefore a distal end 344D of the device 344. The hollow shaft 354 is mounted onto the rotation adaptor knob 352 and contains a drive wire which is not visible here but will be described later in more detail. Along the shaft 354, closer to the housing 346, is a first plurality of horizontal articulation joints 356 each composed of several slits 358. Further towards the distal end 344D of the device 344, also located along the shaft 354, is a second plurality of vertical articulation joints 360 each composed of several slits 362. The first plurality of articulation joints 356 articulate in a plane substantially perpendicular to or substantially horizontal in relation to a plane bisecting the housing 346 or in line with the lever 350. The second plurality of articulation joints 360 articulate in a plane substantially parallel to or substantially vertical in relation to a plane bisecting the housing 346. These articulation joints 356, 360 are constructed of slits 358, 362 in the desired direction of articulation. It should be noted that upon rotation of the rotation adaptor knob 352 this aforementioned relationship of the direction of articulation between the shaft 354 and the directions of articulation become offset by the amount of rotation. In the case of the embodiment shown in FIG. 11, each partial rotation of the rotation adaptor knob 352 rotates the shaft 354 sixty degrees about a longitudinal axis defined by the shaft 354, although alternate embodiments may have different extents of partial rotation. Alternate embodiments of an articulating shaft 354 may include varying numbers of slits, for example, from about 1 to about 10, from about 3 to about 8, or from about 5 to about 7. The slits 358, 362 are defined by partial circumferential segmentation of the outer surface of the hollow rigid shaft 354. These slits may be formed by laser cutting, machining, or other means known to those skilled in the art. While the articulation feature in this embodiment consists of multiple slits for each joint, the articulation feature in alternate embodiments may also include other articulating joint constructions configured to be similarly positioned, such as hinges, flexible shaft materials, and other types of articulating joint construction known to those skilled in the art, and will also be configured such that the shaft 354 can be formed into a desired shape or angle of approach for the surgical procedure, and will remain in the set configuration until intentionally moved to a different shape or angle of the shaft 354. While these articulation joints 356, 360 move and are configured to be positioned in the aforementioned planes, alternate arrangements of articulation joints may be used in alternate device embodiments. For example, horizontal articulation joints may be located closer to a distal housing or distal tip 364 while vertical articulation joints may be located closer to the housing 346, vertical and horizontal articulation joints may alternate along the shaft, or varying numbers of each may be present in alternate device embodiments. Further towards the distal end 344D of the device 344 is a distal tip 364 fixedly mounted onto the shaft 354. The distal tip 364 includes an arcuate first blunt dissector 366 and an arcuate second blunt dissector 368 that are in an open position. The first blunt dissector may also be referred to as an arcuate finger, and the second blunt dissector 368 may also be referred to as a fixed member or a gliding member, due to a gliding movement of the first cam portion 382 throughout a cam path. When open, as illustrated in FIG. 11, the distal tip 364 is configured to receive a vessel, artery, or other anatomical feature within the distal tip 364 when the distal tip 364 is closed. The vessel, artery, or other anatomical feature can be retained and releasably held by actuating the lever 350 and placing the first blunt dissector 366 and the second blunt dissector 368 into a closed position. Further details of this operational movement are detailed in regard to FIGS. 13A-13B and 14A and 14B.
FIG. 12 is an exploded view of a distal end of the minimally invasive surgical device of FIG. 11. The hollow shaft 354 is shown, having a tip 370 fixedly attached to the hollow shaft 354, further defining a head 372 and a keyway 374. A flat tip key 376 having a drive coupler 378 and an actuator coupler 386 is inserted into the keyway 374 on the tip 370. The flat tip key 376 is coupled to the drive wire, which is not shown in this view. An actuator pin 380, further defining a first cam portion 382 and a second cam portion 384 is attached to the actuator coupler 386 on the flat tip key 376. Next, a first guide tip portion body 388 which defines a first cam path 390, a channel 392, and the first blunt dissector 366 is placed over the tip 370 on the hollow shaft 354. A second guide tip portion body 394, which defines an inner cam path 396, and the second blunt dissector 368 having a is then placed inside the first guide tip portion body 388, completing the distal tip 364 assembly.
FIGS. 13A and 13B are top-left-front perspective views focused on an assembled distal end of the minimally invasive surgical device of FIG. 11 in an open and closed position, respectively. When the minimally invasive device is at rest, the relative positions of second blunt dissector 368 and first blunt dissector 366 are in an open position, and the first cam portion 382 is located closer to the hollow shaft 354 within the first cam path 390 on the first guide tip portion body 388. There may be a corresponding cam path on the opposite side of the first guide tip portion body 388 which is not shown in this view. The corresponding cam path may just be a straight path, rather than the curved path of the first cam path 390. The second blunt dissector 368 has a guiding feature 398 that seats within a corresponding recess (not shown) on the first blunt dissector 366. FIG. 13B shows the first blunt dissector 366 and second blunt dissector 368 in a closed position. Once the actuation lever is squeezed, the drive wire pushed distally, and the first cam portion 382 engaged in a distal direction away from the shaft within the first cam path 390, the first blunt dissector 366 and second blunt dissector 368 are in a closed position. This operating function will be further discussed in regard to FIGS. 14A and 14B.
FIGS. 14A and 14B are a side cross-sectional view and front-end view, respectively, of the minimally invasive surgical device of FIG. 11 in an open position. Within the housing 346 of the device 344, a spring 402 is shown providing a bias on the actuation lever 350 while the device 344 is in an open position or a position in which the actuation lever 350 has not been actuated. Also visible are the drive wire 400 coupled to a ball end 406 captured in a lever coupler 404 within the actuation lever 350. FIG. 14B is a front-end view showing the position of the first blunt dissector 366, second blunt dissector 368, and guiding feature 398 while the device 344 is in the open position. In this position, the device 344 is configured to receive a vessel, artery, or other anatomical feature within the opposing pincers, or first blunt dissector 366 and second blunt dissector 368.
FIGS. 15A and 15B are a side cross-sectional view and front-end view, respectively, of the minimally invasive surgical device of FIG. 11 in a closed position. As the actuation lever 350 of the device 344 is squeezed or actuated towards the handle in direction 408, the drive wire 400 is moved in a direction 410 towards the distal end of the device 344. As previously described in regard to FIGS. 13A and 13B, as the drive wire 400 and first cam portion 382 are coupled, the movable second blunt dissector 368 is pushed closed relative to the fixed first blunt dissector 366 along first cam path 390, where in the closed position, the device 344 may be used to hold onto and gently grasp a vessel, artery, or other anatomical feature within the closed structure defined by the first blunt dissector 366 and second blunt dissector 368.
FIG. 16 is an enlarged side view of a portion of the shaft of the minimally invasive surgical device of FIG. 11. FIG. 16 shows an enlarged side view highlighting a hollow shaft 414 having a first set of slits 412 which includes a first plurality of slits 416 and a second plurality of slits 418. The hollow rod or shaft 414 has a length and an outer circumference. The first set of slits includes a first plurality of slits across the outer circumference dissecting an apex of the hollow rod and a second plurality of slits oriented 180 degrees around the outer circumference of the hollow rod relative to the first plurality of slits. Each of the slits illustrated in FIG. 16 are made of a cross-sectional compound shape incorporating a rectangular portion and a circular portion. The rectangular portion is in communication with the outer circumference of the hollow rod. Other embodiments may incorporate slits having alternate compound shapes or alternate orientations of respective portions of compound shapes, such as triangles, squares, and other multi-sided polygons to form a variety of compound shapes.
Several parameters are notated in FIG. 16, designating important dimensional considerations relative to the slit geometry and arrangement. Diameter, d, of the circular portion of the slit, and cross-sectional height, h, of each slit is notated. As several heights are shown, h1, h2, h3, h4, they are separately designated. The heights in each of the first plurality of slits 416 and a second plurality of slits 418 illustrated in FIG. 16 show an arched or parabolic arrangement as formed by the plurality of adjacent slits. Other embodiments may have different shaped arches or arcs or may be of equivalent heights with respect to adjacent slits. The width, w, of the rectangular portion of each slit is designated, as is the spacing, s, between each slit. Lastly, the web distance, We, the distance between the circular portion or inner boundary of each of the first plurality of slits 416 and the inner boundary or circular portion of each of the second plurality of slits is indicated in FIG. 16. The diameter, d, of the circular portion is believed to influence the stress induced on the hollow shaft when bending. The circular portion is considered to reduce stress concentrations during multiple bending operations while articulating the shaft multiple times during the use of an instrument. Larger diameter circles may reduce the stresses induced while bending as compared to smaller diameter circles. The cross-sectional height — h1, h2, h3, h4 — of the slit is inversely proportional to the web distance, We, and the balance between height and web distance may provide a tradeoff in the operation and performance of the instrument shaft between bendability and yield strength. This particular arrangement provides an instrument shaft configured to yield under bending stresses without breaking. When We is larger more stress can be accommodated by the instrument shaft under bending stress, and when We is smaller, less stress can be accommodated by the instrument shaft under bending stress. Height, h, width, w, and spacing between slits, s, influence the bend angle and bending radius of the portion of the hollow instrument shaft that includes a set of slits. Reduced dimensions in h, w, and s will provide a tighter bend radius, and vice versa. It should be noted that regardless of the relative dimensions and arrangements of each of the aforementioned parameters illustrated in FIG. 16, that each of the slits may have differing values of each of the aforementioned parameters in alternate embodiments of an articulatable instrument shaft. This combination of parameters and features as described can be combined to provide an articulatable instrument shaft that has rigidity, malleability, and robustness that can be articulate and bent, hold its shape, and be repeatedly manipulated during the course of a minimally invasive surgical procedure. As shown in FIG. 11, for example, an instrument shaft may have multiple sets of slits having similar features as described previously, such as a second set of slits, or a third or fourth set of slits, or more. These multiple sets of slits may be all oriented similarly, or as in the example from FIG. 11, the multiple sets of slits are perpendicular to one another, for example, a second set of slits is oriented 90 degrees around the outer circumference of the hollow rod relative to the first plurality of slits. Additionally, alternate embodiments may have only one set of slits or may be oriented 180 degrees apart or of varying angles depending on application considerations. Furthermore, slits may have alternate shapes — such as triangular, circular, polygonal — alternate compound shapes — such as dog bone, mushroom, or hot dog-shaped — and alternate dimensions as compared to those characterized and defined herein. Overall shaft diameter also plays a role and interacts with each of the features defined previously, and presumably would have to be modified or scaled proportionally for differing shaft diameters.
Any of the disclosed embodiments may include a locking mechanism to maintain or lock the position of one or both of the blunt dissectors in a desired position by manipulation of the lever. By way of example, the embodiment of the minimally invasive surgical device 344 illustrated in FIG. 11 may include a selective locking mechanism 500 that is illustrated in FIGS. 17A and 17B, and the selective locking mechanism 500 may allow a user to engage the selective locking mechanism 500 by pivoting the lever 350 towards the housing to a specified position in which the selective locking mechanism 500 is engaged in a lock position in which the first blunt dissector 366 and the second blunt dissector 368 are maintained, or locked, in the closed position. In such a configuration, the minimally invasive surgical device 344 is maintained in the closed position. Further pivoting of the lever 350 towards the housing 346 disengages the selective locking mechanism 500 and the first blunt dissector 366 and the second blunt dissector 368 are rotated into the open position in which the minimally invasive surgical device 344 is in the open position.
Turning to FIGS. 18A and 18B, which are partial side and partial rear views of the lever 350, and FIGS. 22A to 22D, which are various views of the lever 350, the selective locking mechanism 500 may include a lever protrusion 502 that extends from a portion of the lever 350. With reference to FIG. 18A, the lever protrusion 502 may generally extend along a protrusion axis 504 in a direction normal to a pivot axis 505 (illustrated in FIG. 22D) of the lever 350. The lever protrusion 502 may also extend normal to a distally-facing surface 506 of the lever 350, and the distally-facing surface 506 may extend parallel or substantially parallel to the pivot axis of the lever 350. The pivot axis 505 may be normal to a plane 522 that extends through a middle portion of the lever 350 such that the plane 522 is a plane of symmetry or a plane of substantial symmetry relative to the lever 350. In the reference coordinate system of FIGS. 22A to 22D, the pivot axis 505 may extend parallel to the X-axis and the plane 522 may be parallel to the Y-Z plane. Thus, the protrusion axis 504 may extend along the Y-Z plane, but the protrusion axis 504 may form an acute angle with a reference line parallel to the Y-axis.
Turning to FIG. 18A, the lever protrusion 502 may extend along the protrusion axis 504 from a first end 508 that is adjacent to the distally-facing surface 506 to a second end 510, and the first end 508 may be coupled to or integrally formed with the distally-facing surface 506. Referring to FIG. 18B, the lever protrusion 502 may be defined by an upper surface 512 that may be planar or substantially planar and may extend from the first end 508 to the second end 510. The lever protrusion 502 may also be defined by a lower surface 514 that may be planar or substantially planar and may extend from the first end 508 to the second end 510. The upper surface 512 and the lower surface 514 may each extend in a direction parallel to the protrusion axis 504, but the upper surface 512 and the lower surface 514 may not be parallel. In particular, the upper surface 512 and the lower surface 514 may be disposed at an acute angle towards a lateral engagement surface 516, and the lateral engagement surface 516 may extend from a first end 518 of the upper surface 512 to a first end 520 of the lower surface 514. However, in some embodiments, the upper surface 512 and the lower surface 514 may be parallel or substantially parallel. The lever protrusion 502 may also include a lateral trailing surface 524 that may extend from a second end 526 of the upper surface 512 to a second end 528 of the lower surface 514.
The selective locking mechanism 500 may also include a locking arm 530 that is illustrated in FIG. 17A, in which the locking arm 530 is coupled to the housing 346, and FIGS. 23A to 23D, which provide various views of the locking arm 530 itself. The locking arm 530 is configured to selectively engage a portion (e.g., all or a portion of the lateral engagement surface 516) of the lever protrusion 502 to lock the lever 350 in a desired position. In particular, and with reference to FIG. 17A, the locking arm 530 may include a cantilevered support arm 532 that extends from a first end 534 to a second end 536 along an arm axis 538, with the first end 534 being fixed or secured to a portion, such as an interior portion, of the housing 346. The first end may include or be coupled to a coupling portion 531 that may be configured to be received into or secured to the portion of the interior portion, of the housing 346. The second end 536 may be a free end that may be displaced relative to the first end 534 when a force is applied to the second end 536.
Turning to FIG. 19A, the locking arm 530 further includes a locking element 540 that is disposed at or coupled to the second end 536 of the support arm 532. The locking element 540 may extend along a locking element axis 542 from a first end 544 that is formed integrally with or coupled to the second end 536 of the support arm 532 to a second end 546 that extends beyond the second end 536 of the support arm 532.
Referring to FIG. 19B, which is a cross-sectional view of the locking element 540, the locking element 540 may be defined by an upper surface 548 that may be substantially planar or contoured (e.g., cambered) and may extend from the first end 544 to the second end 546 of the locking element 540. The locking element 540 may further be defined by lower surface 550 that may be substantially planar or contoured (e.g., cambered) and may extend from the first end 544 to the second end 546 of the locking element 540. An end surface 551 may extend from a first end 552 of the upper surface 548 to a first end 554 of the lower surface 550. The end surface 551 may have a rounded or contoured shape when viewed in cross-section, or may have a linear shape, as illustrated in FIG. 19B. The locking element 540 may also include a locking notch 556 that may extend through the locking element 540 along the locking element axis 542 from the second end of the locking element 542 towards the first end 544 of the locking element 540. In some embodiments, the locking notch 556 may extend completely through the locking element 540 along the locking element axis 542 from the second end of the locking element 542 to the first end 544 of the locking element 540. The locking notch 556 may be configured to receive the lateral engagement surface 516 (as illustrated in FIG. 18C) of the lever protrusion 502 to lock the lever 350 in a position that will be described in more detail below. The locking notch 556 may be defined by an inner top surface 558 that extends at an acute angle to (or, in some embodiments, generally parallel to) the upper surface 548 and by an inner bottom surface 560 that extends at an acute angle to (or, in some embodiments, generally parallel to) the lower surface 550. An inner end surface 562 may extend from a first end of the inner top surface 558 to a first end of the inner bottom surface 560. The inner end surface 562 may have a rounded or contoured shape when viewed in cross-section, and the shape may correspond or generally correspond to the shape of the lateral engagement surface 516 (as illustrated in FIG. 18C) of the lever protrusion 502. In some embodiments, the inner top surface 558, the inner bottom surface 560, and the inner end surface 562 may cooperate to form a cross-sectional shape that corresponds to or is complementary to the wedge-shape of the upper surface 512, the lower surface 514, and the lateral engagement surface 516 of the lever protrusion (illustrated in FIG. 18C). In some embodiments, the cross-sectional shape of the inner top surface 558, the inner bottom surface 560, and the inner end surface 562 may generally extend along a notch axis 576 that may be parallel to or substantially parallel to the wedge axis 570 of the lever protrusion illustrated in FIGS. 18C and 20A. As such, the locking notch 556 may have a cross-sectional shape shaped, dimensioned, oriented, and/or otherwise configured to receive a portion of the lever protrusion 502 such that the inner end surface 562 is in contact with or adjacent to the lateral engagement surface 516 of the lever protrusion 502 when the selective locking mechanism 500 engaged in the lock position. In such a lock position, all or a portion of the inner bottom surface 560 may be in contact with all or a portion of the lower surface 514 of the locking protrusion 502.
In operation, and with reference to FIG. 11, the selective locking mechanism 500 may allow a user to engage the selective locking mechanism 500 by pivoting the lever 350 towards the housing to a specified lock position in which the first blunt dissector 366 and the second blunt dissector 368 are maintained, or locked, in the closed position (i.e., a second configuration). Before pressure is applied to the lever 350 to pivot the lever 350 towards the housing 346 (i.e., when the lever 350 is in a first position), the first blunt dissector 366 and the second blunt dissector 368 are disposed in an open position (i.e., a first configuration). When, as previously described, the first blunt dissector 366 and the second blunt dissector 368 are positioned around a portion of an organ that is to be manipulated by the minimally invasive surgical device, the user may begin to pivot the lever 350 towards the housing 346 (i.e., from the first position of the lever 350 towards a second position of the lever 350) by applying a first force to the lever 350, which displaces the lever protrusion 502 towards the stationary locking arm 530, as illustrated in the partial cross-sectional view in FIG. 20A. The lever protrusion 502 will continue to displace towards the stationary locking arm 530 until a portion of the upper surface 512 at or adjacent to the first end 518 of the lever protrusion 502 contacts a portion of the lower surface 550.
As illustrated in FIG. 20B, further displacement of the lever 350 towards the housing 346 continues to displace the lever protrusion 502 upward, which causes the second end 536 of the support arm 532, and the locking element 540 at the second end 536 of the support arm 532, to displace in a direction 563 normal to—and away from—the arm axis 538 (as it would be in an unflexed state of the support arm 532, as provided in FIG. 20A) by the force provided by the contact of the portion of the sloped upper surface 512 of the lever protrusion 502 against the portion of the lower surface 550 of the locking element 540. Further upward displacement of the lever protrusion 502 brings the lateral engagement surface 516 of the lever protrusion into contact with a lower lip 564 of the locking element 540 that, as illustrated in FIG. 19B, extends between an end of the lower surface 550 and an end of the inner bottom surface 560 of the locking notch 556.
Further displacement of the lever 350 towards the housing 346 by the user continues to displace the lever protrusion 502 upward until a point when the lateral engagement surface 516 of the lever protrusion 502 clears the lower lip 564 of the locking element 540, at which point the second end 536 of the support arm 532, and the locking element 540 at the second end 536 of the support arm 532, displaces in a direction 565 normal to—and towards— the (unflexed) arm axis 538 due to the stored spring energy in the locking arm 530. As the lateral engagement surface 516 of the lever protrusion 502 clears the lower lip 564 of the locking element 540, the lateral engagement surface 516 of the lever protrusion 502 snaps into contact with a portion of the inner end surface 562 and/or a portion of at least one of the inner bottom surface 560 and the inner top surface 558 defining the locking notch 556, as illustrated in FIG. 20C. As the lever 350 is displaced by the user into this second position of the lever 350, the user will feel a tactile “snap” as a portion of the lever protrusion 502 is received into all or a portion of the locking notch 556 and the selective locking mechanism 500 is engaged. With the portion of the lever protrusion 502 disposed within all or a portion of the locking notch 556 (i.e., in the engaged position), the first blunt dissector 366 and the second blunt dissector 368 are maintained in the closed position without the need for the user to apply a force to the lever 350. Thus, the user can release the lever 350 (or cease to apply pressure to the lever 350) and proceed to manipulate the portion of the organ that is grasped or secured by the first blunt dissector 366 and the second blunt dissector 368 of the minimally invasive surgical device.
When the user desires to disengage the selective locking mechanism 500 and displace the first blunt dissector 366 and the second blunt dissector 368 into the second “open” position (for example, to release the portion of the organ that was manipulated), the lever 350 is squeezed by the user (i.e., a second force is applied by the user) from the second position of the lever 350 towards a third position of the lever 350, which displaces the lever protrusion 502 upward 502 from the engaged position illustrated in FIG. 20C. As the lever protrusion 502 displaces upward, a portion of the upper surface 512 and/or a portion of the lateral engagement surface 516 engage the inner top surface 558 of the locking element 540, as illustrated in FIG. 20D, which displaces the locking element 540 in the direction illustrated by arrow 563 (in FIG. 20B).
Further upward displacement of the lever protrusion 502 towards the third position of the lever 350 brings the lateral engagement surface 516 of the lever protrusion 502 into contact with an upper lip 566 of the locking element 540 that extends between an end of the inner top surface 558 and an end of the upper surface 548, as shown in FIG. 20D.
Continued displacement of the lever 350 towards the housing 346 continues to displace the lever protrusion 502 upward, at which point the lateral engagement surface 516 clears the upper lip 566 of the locking element 540, at which point the second end 536 of the support arm 532, and the locking element 540 at the second end 536 of the support arm 532, displaces in the direction 565 towards the (unflexed) arm axis 538, as illustrated in FIG. 20E. The user will feel a further tactile indication as the lever protrusion 502 moves out of physical contact with the locking element 540 (i.e., the third position of the lever 350), and this tactile indication indicates that the selective locking mechanism 500 is not engaged.
When the selective locking mechanism 500 has been moved out of the engaged position, as illustrated in FIG. 20E, the user may release the lever 350. Because the lever 350 is biased into a position away from the hosing 346 by the spring 402, the lever 350 will displace under the influence of the biasing force from the third position towards the first position, thereby displacing the lever protrusion 502 downward (as illustrated in FIG. 20F), which causes the lower surface 514 of the lever protrusion 502 to contact a portion of the upper surface 548 of the locking element 540, which causes the locking element 540 at the second end 536 of the support arm 532 to displace in a direction 568 normal to—and away from—the (unflexed) arm axis 538 by the force provided by the contact of the portion of the sloped lower surface 514 of the lever protrusion 502 against the portion of the upper surface 548 of the locking element 540.
Further downward displacement of the lever protrusion 502 clears the end surface 551 of the locking element 540, thereby allowing the locking element 540 at the second end 536 of the support arm 532 to displace in a direction opposite to arrow 568 an to arrive at a normal resting position (i.e., the first position of the lever 350) illustrated in FIG. 20G, in which the lever 350 is fully extended away from the housing 346 and in which the lever protrusion 502 is disposed below the locking element 540. The lever protrusion 502 and locking element 540 and now in position in which the selective locking mechanism 500 may be engaged again, as illustrated in FIG. 20A.
FIGS. 21A to 21F illustrate the interrelation of the lever protrusion 502 and the locking element 540 from a opposite view to that of FIGS. 20A to 20G, with FIG. 21A corresponding to the position of FIG. 20A, FIG. 21B corresponding to the position of FIG. 20B, FIG. 21C corresponding to the position of FIG. 20C, FIG. 21D corresponding to the position of FIG. 20D, FIG. 21E corresponding to the position of FIG. 20E, and FIG. 21F corresponding to the position of FIG. 20F.
Various advantages of a device for vessel harvesting have been discussed above. Embodiments discussed herein have been described by way of example in this specification. It will be apparent to those skilled in the art that the foregoing detailed disclosure is intended to be presented by way of example only, and is not limiting. As just one example, although the end effectors in the discussed examples were often focused on the use of a scope, such systems could be used to position other types of surgical equipment. Various alterations, improvements, and modifications will occur and are intended to those skilled in the art, though not expressly stated herein. These alterations, improvements, and modifications are intended to be suggested hereby, and are within the spirit and the scope of the claimed invention. The drawings included herein are not necessarily drawn to scale. Additionally, the recited order of processing elements or sequences, or the use of numbers, letters, or other designations therefore, is not intended to limit the claims to any order, except as may be specified in the claims. Accordingly, the invention is limited only by the following claims and equivalents thereto.
Patent Application
20230181212
