The disclosure relates to the field of medical devices. More particularly, the disclosure relates to orthopedic medical devices for fixating, immobilizing, and manipulating bones, and components of these medical devices. Specific examples relate to external fixation stabilizers suitable for spacing a footplate from the ground. The disclosure also relates to external fixation systems, external fixation kits, and various related methods.
There is a need for improved external fixation stabilizers, external fixation stabilizer assemblies, external fixation systems, external fixation kits, and various related methods.
Various external fixation stabilizers are described and illustrated herein.
An example external fixation stabilizer comprises a non-metallic base member having an upper surface and a lower surface; a connector member extending from the upper surface of the base member; and a footing member attached to the lower surface of the base member and comprising a non-metallic material.
Another example external fixation stabilizer comprises a non-metallic base member having an upper surface and a lower surface, the upper surface defining a cavity; a connector member partially disposed in the cavity of the base member and extending away from the base member; and a footing member attached to the lower surface of the base member and comprising a non-metallic material.
Another example external fixation stabilizer comprises a non-metallic base member having an upper surface, a lower surface, an outer circumferential wall, an upper inner circumferential wall, a lower inner circumferential wall, and a separating wall defining an opening disposed between the upper inner circumferential wall and the lower inner circumferential wall, the upper inner circumferential wall and the separating wall cooperatively defining an upper cavity that extends from the upper surface to the separating wall, the lower inner circumferential wall and the separating wall cooperatively defining a lower cavity that extends from the lower surface to the separating wall; a connector member partially disposed in the lower cavity and extending through the opening and into the upper cavity; and a footing member attached to the lower surface of the base member and comprising a non-metallic material.
Various external fixation stabilizer assemblies are described.
An example external fixation stabilizer assembly comprises a non-metallic base member having an upper surface, a lower surface, an outer circumferential wall, an upper inner circumferential wall, a lower inner circumferential wall, and a separating wall defining an opening disposed between the upper inner circumferential wall and the lower inner circumferential wall, the upper inner circumferential wall and the separating wall cooperatively defining an upper cavity that extends from the upper surface to the separating wall, the lower inner circumferential wall and the separating wall cooperatively defining a lower cavity that extends from the lower surface to the separating wall; a spacer having a base portion defining a first terminal surface, an extension portion defining a second terminal surface, an outer wall defining a shoulder comprising an interface between the base portion and the extension portion, and an inner circumferential wall defining a passageway extending from the first terminal surface to the second terminal surface; a connector member partially disposed in the lower cavity and having a shaft extending into the upper cavity and through the passageway of the spacer; and a footing member attached to the lower surface of the base member and comprising a non-metallic material.
Various example external fixation systems are described.
An example external fixation system comprises a plate having a plate upper surface and a plate lower surface and defining a first passageway extending from the plate lower surface to the plate upper surface and a second passageway extending from the plate lower surface to the plate upper surface; a first external fixation stabilizer comprising a first non-metallic base member having a first upper surface and a first lower surface, a first connector member extending from the first upper surface of the first base member, and a first footing member attached to the first lower surface of the first base member and comprising a non-metallic material; and a second external fixation stabilizer comprising a second non-metallic base member having a second upper surface and a second lower surface, a second connector member extending from the second upper surface of the second base member, and a second footing member attached to the second lower surface of the second base member and comprising a non-metallic material. The first connector member is disposed through the first passageway and the second connector member is disposed through the second passageway.
Various example external fixation kits are described.
An example external fixation kit comprises a first external fixation stabilizer comprising a non-metallic base member having an upper surface and a lower surface; a connector member extending from the upper surface of the base member; and a footing member attached to the lower surface of the base member and comprising a non-metallic material; a second external fixation stabilizer comprising a non-metallic base member having an upper surface and a lower surface, the upper surface defining a cavity; a connector member partially disposed in the cavity of the base member and extending away from the base member; and a footing member attached to the lower surface of the base member and comprising a non-metallic material; a spacer having a base portion defining a first terminal surface, an extension portion defining a second terminal surface, an outer wall defining a shoulder comprising an interface between the base portion and the extension portion, and an inner circumferential wall defining a passageway extending from the first terminal surface to the second terminal surface; and a packaging substrate.
Another example external fixation kit comprises a first external fixation stabilizer comprising a non-metallic base member having an upper surface and a lower surface; a connector member extending from the upper surface of the base member; and a footing member attached to the lower surface of the base member and comprising a non-metallic material; a second external fixation stabilizer comprising a non-metallic base member having an upper surface and a lower surface, the upper surface defining a cavity; a connector member partially disposed in the cavity of the base member and extending away from the base member; and a footing member attached to the lower surface of the base member and comprising a non-metallic material; a first spacer having a base portion defining a first terminal surface, an extension portion defining a second terminal surface, an outer wall defining a shoulder comprising an interface between the base portion and the extension portion, and an inner circumferential wall defining a passageway extending from the first terminal surface to the second terminal surface; a second spacer having a base portion defining a first terminal surface, an extension portion defining a second terminal surface, an outer wall defining a shoulder comprising an interface between the base portion and the extension portion, and an inner circumferential wall defining a passageway extending from the first terminal surface to the second terminal surface; a plate having a plate upper surface and a plate lower surface and defining a first passageway extending from the plate lower surface to the plate upper surface and a second passageway extending from the plate lower surface to the plate upper surface; and a packaging substrate
Various example methods are also described.
An example method comprises attaching a first external fixation stabilizer to an external fixation plate; and attaching a second external fixation stabilizer to the external fixation plate.
Another example method comprises attaching a spacer to a first external fixation stabilizer; attaching the first external fixation stabilizer to an external fixation plate; and attaching a second external fixation stabilizer to the external fixation plate.
Additional understanding of the claimed devices and methods can be obtained by reviewing the detailed description of selected examples, below, with reference to the appended drawings.
The following detailed description and the appended drawings describe and illustrate various example medical devices, components of medical devices, systems, kits, and methods individually selected by the inventors for the purpose of enabling one skilled in the art to make and use examples of the inventive medical devices, components, systems, and kits, and to perform examples of the inventive methods. The examples do not limit the scope of the claims in any manner.
As best illustrated in
As best illustrated in
Also as best illustrated in
The upper inner circumferential wall 128 defines an inner diameter 144 for the upper cavity 140 and the lower circumferential wall 132 defines an inner diameter 164 for the lower cavity 160. In the illustrated example external fixation stabilizer 100, the inner diameter 164 of the lower cavity 160 is less than the inner diameter 144 of the upper cavity 140. In this example, this configuration is considered advantageous at least because it provides a desirable interface between the connecting member 112 and the base member 110. It is noted, though, that other relative configurations of the upper 160 and lower 140 cavities can be included in an external fixation stabilizer according to a particular embodiment.
The connector member 112 has a base 170, a circumferential flange 171, and a shaft 172 extending away from the base 170. The base 170 has a base outer diameter 174 and the shaft 172 has a shaft outer diameter 176. The base outer diameter 174 is greater than the shaft outer diameter 176 and is greater than the opening inner diameter 136. The shaft outer diameter 176 is less than the base outer diameter 174 and is less than the opening inner diameter 136. As best illustrated in
In this example, base 170 defines a faceted outer surface 178 that facilitates interaction with tools that can used during securement of the external fixation stabilizer to another member, such as an external fixation frame. For example, in the illustrated example, the outer surface 178 defines a hexagon that can be received by standard sockets and wrenches. The base can define any suitable structure for interacting with any tool or tools that may be desired for use in securing a external fixation stabilizer to an external fixation frame, and a skilled artisan will be able to select an appropriate structure for the base in an external fixation stabilizer according to a particular embodiment based on various considerations, including the structure of any tool desired to be used to secure the external fixation stabilizer during to an external fixation frame. Examples of suitable structures for the base in example external fixation stabilizers include faceted outer surfaces of standard and non-standard configurations and sizes for interaction with sockets, wrenches, and/or other external grasping tools, and recesses on the terminal surface of the base that are suitable for receiving a portion of a driving tool, such as a screwdriver or other tool.
In this example, shaft 172 defines a continuous outer surface 180 that is substantially smooth and free of ribs, threads, or other structural interruptions to the surface 180. This structural configuration is considered advantageous at least because it provides options for securing the external fixation stabilizer 100 to an external fixation frame. For example, the shaft 172 can be modified to include a passageway that will accept a pin or other member to secure the external fixation stabilizer 100 to an external fixation frame. The shaft 172 and its outer surface 180 can define any suitable structure for securing a external fixation stabilizer to an external fixation frame, and a skilled artisan will be able to select an appropriate structure for the shaft and its outer surface in an external fixation stabilizer according to a particular embodiment based on various considerations, including the structure of any external fixation frame with which the external fixation stabilizer is desired to be used, whether it is desirable to discourage or prevent removal of the external fixation stabilizer from an external fixation frame after the external fixation stabilizer has been secured to an external fixation frame, and other considerations. Examples of suitable structures for the shaft in example external fixation stabilizers include a threaded outer surface, an outer surface that defines one or more detents, and an outer surface that defines one or more passageways, and other suitable structures.
An optional washer can be positioned between the base 170 of the connector member 112 and the base member 110, as an alternative to or in addition to circumferential flange 171.
The footing member 114 is disposed on the lower surface 122 of the base member 122 and, in the illustrated example, partially on the outer circumferential wall 124 of the base member 110. As such, the footing member 114 has a lower portion 184 that is disposed adjacent, and in contact with, the lower surface 122 of the base member 110 and an upper portion 186 that is disposed radially outward of, and in contact with, a portion of the outer circumferential wall 124 of the base member 110. As best illustrated in
The lower portion 184 of the footing member 114 in the illustrated example includes a series of channels 188. While inclusion of the series of channels 188 is optional, its inclusion is considered advantageous at least because the series of channels 188 enhances gripping of a surface, such as a floor, by the footing member 114 when the external fixation stabilizer 100 is used with a footplate or other suitable external fixation frame. The lower portion of the footing member in an external fixation stabilizer can have any suitable structure and a skilled artisan will be able to select a suitable structure for a lower portion of the footing member in an external fixation stabilizer according to a particular embodiment based on various considerations, including any desired surface gripping properties. Examples of suitable structures include the series of channels 188 illustrated in
The upper portion 186 of the footing member 114 extends from the lower portion 184 along the outer circumferential wall 124 toward the upper surface 120. In the illustrated example, the upper portion 186 of the footing member 114 extends along only a portion of the axial length of the base member 110. In this example, the upper portion 186 of the footing member 114 extends along about half of the axial length of the base member 110. It is noted, though, that the upper portion of the footing member in an external fixation stabilizer according to a particular embodiment can extend along any suitable axial length of the base member of the external fixation stabilizer. Examples of suitable axial lengths of the base member for the upper portion of the footing member to extend include, but are not limited to, about entire axial length of the base member, the entire axial length of the base member, more than half of the axial length of the base member, about half of the axial length of the base member, half about the axial length of the base member, less than half of the axial length of the base member, about one-fourth of the axial length of the base member, and one-fourth of the axial length of the base member.
Base member 210 has an upper surface 220, a lower surface 222, an outer circumferential wall 224, a separating wall 226 that lies on a plane that is perpendicular to common lengthwise axis 216, and a circumferential shoulder 206 that lies on a plane that is perpendicular to common lengthwise axis 116. An upper inner circumferential wall 228 and the separating wall 226 cooperatively define an upper cavity 240 that extends from the upper surface 220, into the base member 210 to the separating wall 226. Similarly, a lower inner circumferential wall 232 and the separating wall 226 cooperatively define a lower cavity 260 that extends from the lower surface 222, into the base member 210 to the separating wall 226. Separating wall 226 defines an opening 234 having an opening inner diameter 236. The opening 234 provides communication between the upper cavity 240 and the lower cavity 260. As best illustrated in
In this example, base member has a lower portion 225 the has a cylindrical configuration and an upper portion 227 that has a frustoconical configuration. As best illustrated in
The connector member 212 has a base 270, a circumferential flange 171, and a shaft 272 extending away from the base 270. The base 270 has a base outer diameter 274 and the shaft 272 has a shaft outer diameter 276. The base outer diameter 274 is greater than the shaft outer diameter 276 and is greater than the opening inner diameter 236. The shaft outer diameter 276 is less than the base outer diameter 274 and is less than the opening inner diameter 236. In this example, shaft 272 defines a threaded outer surface 280 onto which a nut or other threaded fastener can be attached to secure the external fixation stabilizer to an external fixation frame.
The footing member 214 is disposed on the lower surface 222 of the base member 222 and partially on the outer circumferential wall 224 of the base member 210. As such, the footing member 114 has a lower portion 284 that is disposed adjacent, and in contact with, the lower surface 222 of the base member 210 and an upper portion 286 that is disposed radially outward of, and in contact with, a portion of the outer circumferential wall 224 of the base member 110. The lower portion 284 of the footing member 214 in the illustrated example defines a series of channels 288. The upper portion 286 of the footing member 214 extends from the lower portion 284 along the outer circumferential wall 224 toward the upper surface 220. In this example, the upper portion 286 of the footing member 214 extends along only a portion of the axial length of the lower portion 225 of the of the base member 210.
The upper inner circumferential wall 228 defines a diameter 244 for the upper cavity 240 and the lower circumferential wall 232 defines a diameter 264 for the lower cavity 260. In this example, the diameter 264 of the lower cavity 260 is less than the diameter 244 of the upper cavity 240. In this example, this configuration is considered advantageous at least because it allows larger items to enter the upper cavity 240 than the lower cavity 240, such as the spacers described below.
As best illustrated in
As best illustrated in
In the example spacer 300, the inner circumferential wall 320 is a continuous annular surface 330 free of ribs or other structural interruptions to the surface 330. This configuration is considered advantageous at least because it allows the spacer 300 to be used with a variety of external fixation stabilizers, regardless of the structure defined by the external surface of the shaft of the connector member of the external fixation stabilizer. For example, the illustrated spacer 300 can be used with an external fixation stabilizer having a connector member with a shaft that defines a continuous outer surface, such as the external fixation stabilizer 100 described above and illustrated in
Alternatively, the inner circumferential wall of a spacer according to a particular embodiment can define a tapering diameter or structural features that facilitate securement of the spacer to an object, such as the shaft of an external fixation stabilizer. For example, the inner circumferential wall of a spacer according to a particular embodiment can define a threaded surface for mating with a threaded outer surface of a shaft of a connector member in a particular external fixation stabilizer.
The shaft 272 of the connector member 212 of the external fixation stabilizer 200 extends through the passageway 322 of the spacer 300. The first terminal surface 316 of the base portion 310 of the spacer 300 is disposed adjacent, and in contact with, the upper surface 220 of the base member 210 of the external fixation stabilizer 200. The second terminal surface 318 of the base portion 310 of the spacer 300 is disposed away from, and free of contact with, the upper surface 220 of the base member 210 of the external fixation stabilizer 200. As such, the spacer 300 is positioned on the connector member 212 with the base portion 310 disposed adjacent, and in contact with, the upper surface 220 of the base member 210 of the external fixation stabilizer 200. The extension portion 312 is disposed away from, and not in contact with, the upper surface 220 of the base member 210 of the external fixation stabilizer 200.
The shaft 272 of the connector member 212 of the external fixation stabilizer 200 extends through the passageway 322 of the spacer 300. The second terminal surface 318 of the extension portion 312 of the spacer 300 is disposed adjacent, and in contact with, the separating wall 226 of the base member 210 of the external fixation stabilizer 200. The first terminal surface 316 of the base portion 310 of the spacer 300 is disposed away from, and free of contact with, the upper surface 220 of the base member 210 of the external fixation stabilizer 200. As such, the spacer 300 is positioned on the connector member 212 with the extension portion 310 disposed substantially within the upper cavity 240 of the base member 210 of the external fixation stabilizer 200. The base portion 310 is disposed such that the shoulder 326 is in contact with the upper surface 220 of the base member 210 of the external fixation stabilizer 200.
External fixation system 700 can include one or more additional components, including conventional external fixation components, including, but not limited to, foot plates, rings, connecting elements such as rods, struts and bone fixation wires.
External fixation system 800 can include one or more additional components, including conventional external fixation components, including, but not limited to, foot plates, rings, connecting elements such as rods, struts and bone fixation wires.
The modular nature of the external fixation systems, such as external fixation system 700 and external fixation system 800, is considered advantageous at least because it allows a caregiver to easily remove an external fixation stabilizer from an external fixation plate when it shows signs of wear. This provides significant advantage in the correction of deformities. For example, in the correction of a foot and/or ankle deformity, a caregiver can easily remove and replace external fixation stabilizers as a new ground contact plane is desired.
Any suitable number, types, and relative numbers of different types of external fixation stabilizers can be included in an external fixation kit according to a particular embodiment and the total number, types, and relative numbers of different types of external fixation stabilizers 100a, 100b, 200a, 200b illustrated in
Packaging substrate 910 can comprise any substrate considered suitable for packaging a kit that contains medical device components. Examples of suitable packaging substrates include a box or other member that defines a cavity into which some or all of the components of the kit can be placed. The box or other member can include one or more parts, such as a cavity defining portion and a movable flap that provides access to the cavity. Alternatively, the body portion can define a cavity and a separable lid portion can be provided as part of the packaging substrate. Alternatively, the packaging substrate can simply define a surface onto which the components of the kit can be placed and secured, such as a backing and a shrink wrap element.
The components of the various external fixation stabilizers according to all embodiments can be made of any suitable material. The inventors have determined that it is advantageous to fabricate the base member of an external fixation stabilizer out of a relatively hard plastic material. Examples of suitable materials for the base member include, but are not limited to, polyamide, polycarbonate, acrylonitrile butadiene styrene (ABS), ABS polycarbonate blends, polyether ether ketone (PEEK), polypropylene, and polyurethane. Also, the inventors have determined that is advantageous to fabricate the footing member of an external fixation stabilizer out of a relatively soft material. Examples of suitable materials for the footing member include, but are not limited to, polypropylene, high density polyethylene, a thermoplastic elastomer (TPE), bromobutyl, chlorobutyl, polyurethane, polyvinyl chloride, and rubber. The inventors have determined that the base member and footing member can be advantageously fabricated using a two-shot overmold process.
Also, the inventors have determined that it is advantageous to fabricate the spacer out of a resilient plastic material at least because such materials absorb a portion of a mechanical load applied to the spacer during use, such as when a patient is walking with an external fixation system applied to his or her foot. Examples of suitable materials for the footing member include, but are not limited to, polypropylene, high density polyethylene, and rubber. Also, the inventors have determined that it is advantageous to fabricate the connector member of an external fixation stabilizer out of a metal, such as stainless steel, aluminum, titanium, zinc, or other suitable metal. Also, the inventors have determined that is advantageous to fabricate the external fixation plates out of a metal, such as stainless steel, aluminum, titanium, zinc, or other suitable metal.
In the method 2000, any suitable external fixation stabilizer according to an embodiment can be used, including the external fixation stabilizer 100 described above and illustrated in
An optional step 2006 comprises attaching another external fixation stabilizer according to an embodiment to the external fixation plate. This step 2006 can be repeated any desirable number of times.
In the method 3000, any suitable external fixation stabilizer according to an embodiment can be used, including the external fixation stabilizer 100 described above and illustrated in
An optional step 3008 comprises attaching a spacer to the second external fixation stabilizer. This step 3008, if included, should be performed before step 3006.
Any suitable number of additional optional steps of attaching another external fixation stabilizer to the external fixation plate can be included if desired. Also, for each additional step of attaching another external fixation stabilizer to the external fixation plate included in a particular method, an optional step of attaching a spacer to the external fixation stabilizer can be included and should be performed before the particular step of attaching another external fixation stabilizer to the external fixation plate.
Those with ordinary skill in the art will appreciate that various modifications and alternatives for the described and illustrated examples can be developed in light of the overall teachings of the disclosure, and that the various elements and features of one example described and illustrated herein can be combined with various elements and features of another example without departing from the scope of the invention. Accordingly, the particular examples disclosed herein have been selected by the inventors simply to describe and illustrate examples of the invention and are not intended to limit the scope of the invention or its protection, which is to be given the full breadth of the appended claims and any and all equivalents thereof.
This application claims priority to U.S. provisional application No. 62/749,936, filed on Oct. 24, 2018. This related application is incorporated by reference into this disclosure in its entirety.
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