The disclosure relates generally to the field of medical devices. More particularly, the disclosure relates to rod insertion tools, rods and methods for placing rods in patients.
Over time, bone may degenerate as a result of trauma, disease, and/or natural processes, such as aging. Bone degeneration can affect surrounding tissues and have significant impact on the lifestyle of the patient. For example, destabilization of a spine may result in alteration of a natural spacing between adjacent vertebrae, which can place pressure on nerves that pass between vertebral bodies. Over time, this pressure can cause pain and even permanent nerve damage.
Spinal stabilization procedures are now routinely performed on patients suffering from spinal destabilization. These procedures can be used to maintain and/or re-establish the natural spacing between vertebrae. These procedures can be performed using surgical or recently-developed minimally invasive procedures. Both approaches typically involve the securement of pedicle screws to the pedicles of adjacent vertebrae and placement of a rod between adjacent pedicle screws. The fixed connection between the pedicle screws, and, therefore, between the vertebrae, stabilizes the spacing between the vertebrae. The rod can also be leveraged to compress the vertebrae by reducing the existing spacing between the vertebrae when necessary or desired.
Despite advances in the art, rod placement procedures still face challenges. For example, alignment of rods with pedicle screws, particularly with minimally-invasive procedures and techniques, continues to have a degree of imprecision. Furthermore, current devices fail to provide a sufficiently simple indication of when a rod has been advanced sufficiently. Thus, a need exists for improved rod insertion tools, rods and methods useful in the placement of rods in patients.
Various exemplary rod insertion tools, rods and methods useful for placing rods in patients, such as in the stabilization of the spine of a patient, are described and illustrated herein.
An exemplary rod insertion tool comprises a handle; a main body connected to the handle, the main body having a main body proximal end defining a proximal opening, a main body distal end defining a distal opening, and an inner passageway extending between the proximal and distal openings; a rod engaging member having a rod engaging member proximal end and a rod engaging member distal end, the rod engaging member disposed within the inner passageway and adapted to move from an extended position in which the rod engaging member distal end is disposed outside of the inner passageway to a chambered position in which the rod engaging member distal end is disposed within the inner passageway; and an adjustment mechanism disposed through the proximal opening and operably connected to the rod engaging member proximal end, the adjustment mechanism adapted to cause axial movement of the rod engaging member within the inner passageway upon activation of the adjustment mechanism.
Another exemplary rod insertion tool includes a movable arm attached to the main body. The movable arm is movable between a retracted position on a first side of the main body proximal end and an extended position on a second, opposite side of the main body proximal end.
Another exemplary rod insertion tool includes an outer sheath movable between a retracted position and an extended position and an actuator mechanism operably linked to the outer sheath such that activation of the actuator mechanism causes the outer sheath to move from the retracted position to the extended position.
An exemplary rod has a main body extending between a frustoconical distal end and a rounded frustoconical proximal end and defines an indented faceted surface adjacent the proximal end. The exemplary rod is particularly well-suited for use with the exemplary rod insertion tools.
An exemplary method comprises verifying that each of a movable arm and an outer sheath of an insertion tool according to an embodiment are in their respective retracted position. If one or both of the movable arm and outer sheath is not in its retracted position, an optional step of an exemplary method can comprise placing one or both of the movable arm and outer sheath in its respective retracted position. Another step comprises securing a rod with a rod engaging member of an insertion tool of an embodiment. Another step comprises placing the rod engaging member of the insertion tool in its chambered position. Another step comprises moving the rod through the rod openings of the pedicle screws by moving the insertion tool. Another step comprises moving the movable arm of the insertion tool from its retracted position to its extended position such that the distal end of the movable arm is disposed immediately adjacent a tower to which the first, or proximal, pedicle screw is secured. If compression between the pedicle screws is desired, another step can comprise causing the outer sheath of the insertion tool to move to its extended position such that the distal end of the outer sheath contacts the first tower associated with the first pedicle screw and forces the first pedicle screw to move toward the second pedicle screw.
Additional understanding of the inventive rod insertion tools, rods and methods can be obtained with review of the detailed description, below, and the appended drawings.
The following detailed description and the appended drawings describe and illustrate various exemplary spinal rod insertion tools, spinal rods and methods for placing spinal rods in a patient. The description and drawings are exemplary in nature and are provided to enable one skilled in the art to make and use one or more exemplary spinal rod insertion tools, spinal rods and/or to practice one or more exemplary methods. They are not intended to limit the scope of the claims in any manner.
Insertion tool 100 comprises a handle 110 connected to a main body 112. The main body 112 defines an inner passageway 114 that extends between proximal 116 and distal 118 ends of the main body 112. A proximal opening 120 is disposed on the proximal end 116 of the main body 112 and provides communication to the inner passageway 114. Similarly, a distal opening 122 is disposed on the distal end 118 of the main body 112 and provides communication to the inner passageway 114. A rod engaging member 124 is disposed within the inner passageway 114. An adjustment mechanism 126 is operably connected to an end of the rod engaging member 124 and adapted to cause movement of the rod engaging member 124 toward one or both of the proximal 116 and distal 118 ends of the main body 112. A locking mechanism 128 is operably connected to the adjustment mechanism 126 and, when activated, adapted to secure the adjustment mechanism 126 in a position and prevent or substantially prevent movement of the rod engaging member 124 within the inner passageway 114.
The handle 110 need only be a simple member that can be gripped and held by a single human hand. As such, the handle 110 can have any suitable size, shape and configuration. A skilled artisan will be able to select a handle of appropriate size, shape and configuration for an insertion tool according to a particular embodiment based on various considerations, including the intended use of the insertion tool and/or particular needs of the intended users of the insertion tool.
While considered optional, the handle 110 can include various structural elements and/or features that enhance the ergonomic properties of the handle 110 and/or insertion tool 100. For example, the handle 110 can define various indents, ridges, channels, and/or other structures that may facilitate gripping and/or holding of the handle 110 by a user.
The handle 110 can be formed from a single material or from multiple materials. For example, a simple molded plastic part can be used. Alternatively, the handle 110 can comprise a part formed of two or more materials, such as an over-molded part that includes a relatively soft elastomeric grip section 130 disposed on a base section 132 formed of a relatively rigid material, such as a plastic.
The main body 112 can be integrally formed with the handle 110 or can comprise a separate element fixedly connected to the handle 110. In either approach, the main body 112 can be said to be connected to the handle 110, and vice versa.
The main body 112 provides a housing that defines the inner passageway 112 that receives the rod engaging member 124. As such, the main body 112 can have any suitable size, shape and configuration, and need only be capable of receiving the rod engaging member 124 and operating as described herein. A skilled artisan will be able to select an appropriate size, shape and configuration for the main body of an insertion tool according to a particular embodiment based on various considerations, including the intended use of the insertion tool and the patient population with which the insertion tool is intended to be used. As best illustrated in
The inner passageway 114 is sized and configured to receive the rod engaging member 124 and to allow the slideable movement of the rod engaging member 124 within the passageway, as described below. Thus, the inner passageway 114 can have any suitable size, shape and configuration. A skilled artisan will be able to select an appropriate size, shape and configuration for the inner passageway of an insertion tool according to a particular embodiment based on various considerations, including the size, shape, configuration and material of the associated rod engaging member. Examples of suitable inner passageways include passageways having circular cross-sectional shapes, elliptical cross-sectional shapes, square cross-sectional shapes, cross-sectional shapes of other geometric profiles, inner passageways that have a constant inner diameter or width along their length and inner passageways that have an inner diameter or width that varies along their width, either irregularly, continuously, or intermittently.
The inner passageway 114 in the illustrated insertion tool is exemplary of a suitable inner passageway. In this embodiment, the inner passageway 114 includes a main portion 134, which terminates at the proximal opening 120 at the proximal end 116 of the main body 112, having a circular cross-sectional shape with a constant inner diameter along its length. A distal portion 136, which terminates at the distal opening 122 at the distal end 118 of the main body 112, defines a chamber 138 that has an inner width extending from one portion 140 of the inner wall 142 of the inner passageway 114 to an opposing portion 144 of the inner wall 142 of the inner passageway 114 that is greater than the inner diameter of the main portion 134. As best illustrated in
The rod engaging member 124 is an elongate member disposed in the inner passageway 114 of the main body 110. The rod engaging member 124 is capable of being moved toward one or the proximal 116 and distal 118 ends of the inner passageway 114 or alternately toward the proximal 116 and distal ends 118 of the inner passageway 114.
The proximal end 150 of the rod engaging member 124 is operably connected to the adjustment mechanism 126, as described below. The distal end 152 defines an engaging structure 154 adapted for holding a rod with which the insertion tool 100 is intended to be used. Any suitable structure can be used for the engaging structure. A skilled artisan will be able to select an appropriate engaging structure for an insertion tool according to a particular embodiment based on various considerations, including the nature, size and configuration of a rod with which the insertion tool is intended to be used. Examples of suitable engaging structures includes a distal portion of the rod engaging member with one or more magnets embedded therein or thereon, a projection adapted to be inserted into a complimentary channel defined by an appropriate rod, and other suitable structures.
The engaging structure 154 included in the illustrated embodiment is an example of a suitable structure for the engaging structure. In this embodiment, the engaging structure 154 includes a pair of opposing arms 156, 158 that define an internal notch, such as u-shaped notch 160. A first shoulder 162 projects inwardly into the u-shaped notch 160 from the first arm 156 and defines a first mating surface 164. Similarly, a second shoulder 166 projects inwardly into the u-shaped notch 160 from the second arm 158 and defines a second mating surface 166. The first 164 and second 166 mating surfaces are complimentary to surfaces 206 defined by a rod intended to be used with the insertion tool 100, such as rod 200 illustrated in
As best illustrated in
The adjustment mechanism 126 is operably connected to the rod engaging member 124 such that activation of the adjustment mechanism, accomplished through appropriate action, causes axial movement of the rod engaging member 124 within the inner passageway 114. For example, in the illustrated embodiment, the adjustment mechanism 126 is a rotatable knob that is operably connected to the rod engaging member 124 through complimentary mating threads. For the illustrated embodiment, clockwise rotation of the adjustment mechanism 126 results in axial movement of the rod engaging member 124 toward the distal end 118 of the inner passageway 114, while counter-clockwise rotation of the adjustment mechanism 126 results in axial movement of the rod engaging member 124 toward the proximal end 116 of the inner passageway 114. In use, the adjustment mechanism 126 of the illustrated insertion tool 100 can be rotated clockwise to cause rod engaging member 124 to move to the extended position in which the distal end 152 and the engaging structure 154 are disposed distal to and outside of the chamber 138. This can be performed prior to and in preparation for engagement with a rod. Subsequently, the adjustment mechanism 126 can be rotated counter-clockwise to cause the rod engaging member 124, with or without an engaged rod, to move to the chambered position in which the distal end 152 and the engaging structure 154 are disposed within the chamber 138. The adjustment mechanism can also be configured to operate in an opposite manner, e.g., counter-clockwise rotation to move the rod engaging member 124 to the extended position and clockwise rotation to cause the rod engaging member 123 to move to the chambered position.
Any suitable structure can be used for the adjustment mechanism 126 and a skilled artisan will be able to select an appropriate structure for an insertion tool according to a particular embodiment based on various considerations, including the size and configuration of the main body 112 and inner passageway 114, and any preferences for the type of motion by an intended user of the insertion tool to effect movement of the rod engaging member 124. The illustrated adjustment mechanism 126 provides an example of a suitable structure. In the illustrated embodiment, the adjustment mechanism 126 defines an external knob 168 and an internal thread 170. An internal threaded member 172 defines a complimentary external thread 174 that interfaces with the internal thread 170 of the adjustment mechanism 126 and is fixedly secured to the proximal end 150 of the rod engaging member 124. Alternatively, the internal threaded member 172 can be integrally formed by the proximal end 150 of the rod engaging member 124. The adjustment mechanism 126 is fixed in position, such as by retaining rods 176, 178, such that rotation of knob 168 results in linear movement of the internal threaded member 172 and, as a result, of the attached rod engaging member 124.
A locking mechanism 128 is operably connected to the adjustment mechanism 126 and, when activated, adapted to secure the adjustment mechanism 126 in a position and prevent or substantially prevent movement of the rod engaging member 124 within the inner passageway 114 For example, in the illustrated embodiment, the locking mechanism 128 is a depressable button that attached or formed with a shaft member. Upon depression of the button, the locking mechanism effectively secure the adjustment mechanism 126 as a portion of the shaft member projects into a portion of the inner passageway 114 to prevent distally-directed movement of the rod engaging member 124 beyond a particular point. Alternatively, the shaft member can project into a portion of the rod engaging member 124 or attached structure such that the locking mechanism 128 prevents any further movement, distally-directed or proximally-directed, upon activation, such as by depression of the illustrated button.
Any suitable structure can be used for the locking mechanism 128 and a skilled artisan will be able to select an appropriate structure for an insertion tool according to a particular embodiment based on various considerations, including the size and configuration of the main body 112 and inner passageway 114, and any preferences for the type of motion by an intended user of the insertion tool to effect prevention of movement of the rod engaging member 124. The illustrated locking mechanism 128 provides an example of a suitable structure.
In this embodiment, insertion tool 300 includes a movable arm 350 attached to the main body 312. The movable arm 350 is movable between a retracted, or seated, position, illustrated in
As best illustrated in
In this embodiment, a modular arm 350′ is used in place of the movable arm 350 of the embodiment illustrated in
In this embodiment, insertion tool 400 includes an outer sheath 470 disposed along the external surface of the main body 412 and an actuator mechanism 472 operably linked to the outer sheath 470. The outer sheath 470 has a proximal end 474 and a distal end 476 and extends between the proximal 474 and distal 476 ends along a length of the main body 412. The outer sheath 470 is movable between a retracted position and an extended position. In the retracted position, illustrated in
Any suitable structure can be used for the outer sheath, and a skilled artisan will be able to select an appropriate structure for an outer sheath in an insertion tool according to a particular embodiment based on various considerations, including the size, shape and configuration of the main body. The structure selected need only be able to perform as described. The illustrated outer sheath 470 is an example of a suitable structure. In this embodiment, the outer sheath 470 comprises an elongate member disposed around the main body 412. The distal end 476 of the outer sheath 470 defines a cylindrical portion that extends around the entire circumference of the main body 412. Along a significant portion of its length, though, the outer sheath 470 defines a window 476 through which the main body 412 is accessible. As illustrated, the window 476 is advantageously positioned along an inner curve of the main body 412 in the illustrated embodiment, while the material of the outer sheath 470 along the length defining the window 478 is disposed along the outer curve of the main body 412. Other examples of suitable structures for an outer sheath include an elongate, continuous tubular member. Alternatively, instead of having a portion that extends around a circumference of the main body, a solid member, such as a wire or rod, can be placed along a length of the main body.
Any suitable structure can be used for the actuator mechanism, and a skilled artisan will be able to select an appropriate structure for an actuator mechanism in an insertion tool according to a particular embodiment based on various considerations, including the size, shape and configuration of the outer sheath and the main body in the insertion tool. The illustrated actuator mechanism is an example of a suitable structure. In this embodiment, the actuator mechanism 472 includes a grip 480 that is pivotably mounted to the main body 412 at pivot connection 482 and attached to the proximal end 474 of the outer sheath 470 through grip extension 484. When the grip 480 is brought closer to the handle 410 of the insertion tool 400, it pivots on pivot connection 482 such that the grip 480 moves toward the handle 410 and the grip extension 484 moves away from the handle 410. By way of its attachment to grip extension 484, the proximal end 474 of the outer sheath 470 moves downward with respect to the main body 412 as a result of the upward movement of grip 480. In turn, this forces the outer sheath 470 to move to its extended position, placing its distal end 476 axially beyond the distal end 418 of the main body 412. A connector, such as ratchet mechanism 486, can extend between the grip 480 and the handle 410 to prevent premature, reverse, or other undesired movement of grip 480 and, therefore, outer sheath 470.
In this embodiment, insertion tool 400′ includes a knob 480′ with an extension rod 481′ that is connected to pivot arm 483′. When the knob 480′ is rotated, pivot arm 483′ pivots on pivot connection 482′ such that pivot arm extension 484′ moves away from the handle 410′. By way of its attachment to pivot arm extension 484′, the proximal end 474′ of the outer sheath 470′ moves downward with respect to the main body 412′ as a result of the rotational movement of knob 480′. In turn, this forces the outer sheath 470′ to move to its extended position, placing its distal end 476′ axially beyond the distal end 418′ of the main body 412′.
The insertion tools described herein can be used in the placement of rods in patients. For example, the insertion tools can be used in the placement of a spinal rod through first and second pedicle screws that have been secured to vertebrae of a patient. Accordingly, methods of using the insertion tools are also contemplated. As described above, an exemplary method comprises verifying that each of a movable arm and an outer sheath of an insertion tool according to an embodiment are in their respective retracted position. If one or both of the movable arm and outer sheath is not in its retracted position, an optional step of an exemplary method can comprise placing one or both of the movable arm and outer sheath in its respective retracted position. Another step of an exemplary method comprises securing a rod with a rod engaging member of an insertion tool of an embodiment. Another step of an exemplary method comprises placing the rod engaging member of the insertion tool in its chambered position. Another step of an exemplary method comprises moving the rod through the rod openings of the pedicle screws by moving the insertion tool. Another step of the exemplary method comprises moving the movable arm of the insertion tool from its retracted position to its extended position such that the distal end of the movable arm is disposed immediately adjacent a tower to which the first, or proximal, pedicle screw is secured. If compression between the pedicle screws is desired, another step of an exemplary method can comprise causing the outer sheath of the insertion tool to move to its extended position such that the distal end of the outer sheath contacts the first tower associated with the first pedicle screw and forces the first pedicle screw to move toward the second pedicle screw.
Another exemplary method comprises verifying that a movable arm of an insertion tool according to an embodiment is in its retracted position. If the movable arm is not in its retracted position, an optional step of an exemplary method can comprise placing the movable arm in its respective retracted position. Another step of an exemplary method comprises securing a rod with a rod engaging member of an insertion tool of an embodiment. Another step of an exemplary method comprises placing the rod engaging member of the insertion tool in its chambered position. Another step of an exemplary method comprises moving the rod through the rod openings of the pedicle screws by moving the insertion tool. Another step of the exemplary method comprises moving the movable arm of the insertion tool from its retracted position to its extended position such that the distal end of the movable arm is disposed immediately adjacent a tower to which the first, or proximal, pedicle screw is secured.
Another exemplary method comprises moving the movable arm of an insertion tool according to an embodiment from its retracted position to its extended position prior to a step of moving a rod through rod openings of the pedicle screws. Another step of an exemplary method comprises securing a rod with a rod engaging member of the insertion tool. Another step of an exemplary method comprises placing the rod engaging member of the insertion tool in its chambered position. Another step of an exemplary method comprises moving the rod through the rod openings of the pedicle screws by moving the insertion tool. In this step, the movable arm, which is in its extended position, can be used as a visual or other guide for the movement of the insertion tool and, therefore, the attached rod. Another step of the exemplary method comprises continuing the step of moving the rod through the rod openings until the distal end of the movable arm is disposed immediately adjacent a tower to which the first, or proximal, pedicle screw is secured.
Each of the elements of the insertion tools and spinal rods can be made from any suitable material and a skilled artisan will be able to select appropriate materials for an insertion tool according to a particular embodiment based on various considerations, including the desired properties of each element. Conventional materials currently used in similar devices are considered suitable, as are materials developed subsequent to this disclosure and accepted as suitable for use in similar devices. Examples of suitable materials for various elements of the insertion tools and spinal rods include, but are not limited to, titanium, titanium alloys, stainless steel, ceramics, and polymeric materials. The insertion tools and spinal rods can be autoclaved, chemically sterilized, or otherwise treated in preparation for use in a surgical and/or minimally-invasive procedure, which should be considered when selecting appropriate materials.
The foregoing detailed description refers to exemplary rod insertion tools, rods and methods and includes the best mode for practicing the invention. The description and the appended drawings illustrating the described rod insertion tools, rods and methods are intended only to provide examples and not to limit the scope of the claims in any manner.
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