The present teachings generally relate to surgical repair systems (e.g., resection cut strategy, guide tools, and implant components) as described in, for example, U.S. patent application Ser. No. 13/397,457, entitled “Patient-Adapted and Improved Orthopedic Implants, Designs And Related Tools,” filed Feb. 15, 2012, and published as U.S. Patent Publication No. 2012-0209394, which is incorporated herein by reference in its entirety. In particular, the present teachings provide surgical tools, systems, methods, and techniques incorporating features to facilitate preparation of a patient's anatomical surfaces for installation of implant components.
The natural anatomical joint structures of an individual may undergo degenerative changes due to a variety of reasons, including injury, osteoarthritis, rheumatoid arthritis, or post-traumatic arthritis. When such damage or degenerative changes become far advanced and/or irreversible, it may ultimately become necessary to replace all or a portion of the native joint structures with prosthetic joint components. Joint replacement is a well-tolerated surgical procedure that can help relieve pain and restore function in injured and/or severely diseased joints, and a wide variety of prosthetic joints are well known in the art, with different types and shapes of joint replacement components commercially available to treat a wide variety of joint conditions.
As part of the surgical repair procedure, the underlying anatomical support structures are typically prepared to receive the joint implant components. For example, the placement of a femoral implant component can typically involve preparation of the caudad portion of the femoral bone (otherwise known as the distal head of the femur). This may include surgical resection (e.g., cutting, drilling, rongeuring, scraping) of portions of the medial and/or lateral condyles of the femur, as well as the resection of other anatomical features of the femur and/or surrounding soft tissues. This preparation will desirably create an anatomical support structure capable of accommodating and adequately supporting the femoral implant component or components, which is ultimately secured to the femur. Similar surgical steps can be performed to the tibia and/or the patella, as well as other anatomical structures, as necessary.
One or more surgical guide tools or jigs can be used to assist the surgeon in preparing the underlying anatomical support structure(s). There is a need, however, for improved surgical guide tools and jigs to improve the accuracy, reproducibility, and/or ease of preparing underlying anatomical support structure(s) for an implant and to minimize the invasiveness of such procedures.
Reference will now be made in detail to the present embodiments (exemplary embodiments) disclosed herein, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts.
In this application, the use of the singular includes the plural unless specifically stated otherwise. Furthermore, the use of the term “including,” as well as other forms, such as “includes” and “included,” is not limiting. Also, terms such as “element” or “component” encompass both elements and components comprising one unit and elements and components that comprise more than one subunit, unless specifically stated otherwise. Also, the use of the term “portion” may include part of a moiety or the entire moiety.
The section headings used herein are for organizational purposes only and are not to be construed as limiting the subject matter described.
A variety of traditional guide tools are available to assist surgeons in preparing a joint for an implant, for example, for resectioning one or more of a patient's biological structures during a joint implant procedure. However, these traditional guide tools typically are not designed to match the shape (contour) of a particular patient's biological structure(s). Moreover, these traditional guide tools typically are not designed to impart patient-optimized placement for the resection cuts. Thus, using and properly aligning traditional guide tools, as well as properly aligning a patient's limb (e.g., in rotational alignment, in varus or valgus alignment, or alignment in another dimension) in order to orient these traditional guide tools, can be an imprecise and complicated part of the implant procedure.
Various embodiments described herein include the use of a guide tool having at least one patient-adapted bone-facing surface portion that substantially negatively-matches at least a portion of a biological surface at the patient's joint. For example, as part of the surgical planning phase, patient-specific information (as well as modeling data associated therewith, etc.) can be utilized to create one or more surgical guide tools that can assist the surgeon in preparing the underlying anatomical support structure(s). Accordingly, the guide tool(s) can include registration features that correspond to various anatomical features of the patient's anatomy and, when properly oriented relative to the anatomy, provide one or more guides that the surgeon can follow to create a desired resection (e.g., cutting, drilling, rongeuring, scraping) path in the patient's anatomy. Additionally or alternatively, certain guide tools can be used for purposes other than guiding a drill or cutting tool. For example, balancing and trial guide tools can be used to assess knee alignment and/or fit of one or more implant components or inserts. Similarly, in some embodiments, alignment guide tools can provide anatomical registration and be utilized with a linkage to align another surgical tool or guide in a predetermined position and/or orientation based on the registration.
The use of patient-adapted (i.e., patient-specific and/or patient-engineered) jigs and associated surgical tools can provide a significant improvement in the surgical replacement of joints, and can greatly simplify the surgical procedure. By utilizing pre-operative image and/or other available data to plan the surgical procedure, a significant amount of surgical “guess-work” can be removed from the procedure. Moreover, the creation of alternative surgical plans, and the associated components to execute such alternative plans, can further facilitate the surgical execution of the procedure, allowing the surgeon to modify the procedure intraoperatively in one or more desired manners, yet significantly reducing the potential for surgical error.
Various embodiments of guide tools disclosed herein can include at least one patient-adapted bone-facing surface that substantially negatively-matches at least a portion of a biological surface at and/or adjacent to the patient's joint. The patient's biological surface can include cartilage, bone, tendon, skin, and/or other biological surfaces. For example, in certain embodiments, patient-specific data such as imaging data of a patient's joint can be used to model an area on the articular surface. A guide tool can be selected and/or designed to have one or multiple areas that substantially negatively-match one or multiple areas on the modeled articular surface.
In various embodiments described herein, one or more models of at least a portion of a patient's joint can be generated. Specifically, various patient-specific data and/or measurements can be used to generate a model that includes at least a portion of the patient's joint, and in some embodiments, at least a portion of tissue adjacent to the joint. Various methods to generate such models can be employed, including, for example, those described in U.S. Patent Publication No. 2012-0209394, which is incorporated herein by reference in its entirety. In some embodiments, such methods of generating a model of a patient's joint (and/or a resection cut, drill hole, guide tool, and/or implant component) or other biological feature (and/or a patient-adapted feature of a guide tool or implant component) can include the general steps of obtaining image data of a patient's biological feature; segmenting the image data; combining the segmented data; and presenting the data as part of a model. In various embodiments, this model can include irregular or unusual anatomical features or portions of the joint, which can include, without limitation, osteophytes, subchondral cysts, geodes or areas of eburnation, joint flattening, contour irregularity, and loss of normal shape. The model surface(s) or structure(s) can be or reflect any surface or structure in the joint and/or adjacent to the joint, including, without limitation, bone surfaces, ridges, plateaus, cartilage surfaces, ligament surfaces, skin surfaces, or other surfaces or structures.
As part of this process, one or more patient-adapted resection cuts, drill holes, guide tools, and/or implant components can be included in a model. In certain embodiments, a model of at least part of a patient's joint can be used to directly generate a patient-adapted resection cut strategy, a patient-adapted guide tool design, and/or a patient-adapted implant component design for a surgical procedure (i.e., without the model itself including one or more resection cuts, one or more drill holes, one or more guide tools, and/or one or more implant components). In certain embodiments, the model that includes at least a portion of the patient's joint also can include or display, as part of the model, one or more resection cuts and/or drill holes (e.g., on a model of the patient's tibia), one or more guide tools, and/or one or more implant components that have been designed for the particular patient using the model. Moreover, one or more resection cuts, one or more drill holes, one or more guide tools, and/or one or more implant components can be modeled and selected and/or designed separate from a model of a particular patient's biological features.
As discussed above, various embodiments of guide tools can include at least one guiding formation for directing movement of a surgical instrument, for example, a securing pin or a cutting tool. One or more of the guiding formations can be designed to guide the surgical instrument to deliver a patient-optimized placement for, for example, a securing pin or resection cut. In addition or alternatively, one or more of the guiding formations can be designed to guide the surgical instrument to deliver a standard placement for, for example, a securing pin or resection cut. As used herein, the terms “jig” and “guide” also can refer to guide tools. Guiding formations can comprise a variety of structures, such as, for example, surfaces, slots, holes, apertures, shielding elements, stops (e.g., depth stops), and/or any other structures intended to direct and/or limit movement of a surgical instrument. The term “slot” will be used herein to generally identify a captured guiding formation, which can have a variety of cross-sectional shapes (e.g., circular, square, rectangle, oblong, elliptical, U-shaped) and which can be configured to receive a variety of different types of surgical instruments (e.g., drill, saw, broach, pins, K-wires). The slots in a particular guide tool can be, for example, substantially horizontal, substantially diagonal, or substantially vertical as compared to the patient's mechanical axis and/or anatomical axis. Moreover, one or more of the resection cut slots can allow for a complete resection cut or a partial resection cut, e.g., scoring of the patient's bone to establish a resection cut that can be finished after removing the tool.
The various guide tools described herein can include any combination of patient-adapted features and/or standard features. For example, a patient-adapted guide tool can include at least one feature that is preoperatively designed and/or selected to substantially match one or more of the patient's biological features. A patient-engineered guide tool can include at least one feature that is designed or selected based on patient-specific data to optimize one or more of the patient's biological features to meet one or more parameters. A standard guide tool can include at least one feature that is selected from among a family of limited options, for example, selected from among a family of 5, 6, 7, 8, 9, or 10 options. Moreover, in certain embodiments a set or kit of guide tools can be provided in which certain guide tools in the set or kit include patient-specific, patient-engineered, and/or standard features.
In various exemplary embodiments, a series of guide tools can be designed, selected and/or modified to assist a surgeon in preparing a patient's tibia and/or other anatomical structure(s) to provide sufficient and proper anatomical support for one or more tibial implant components. For example, various embodiments can include one or more guide tools designed to guide the surgeon in performing one or more patient-adapted cuts to the bone so that those cut bone surface(s) negatively-match and/or are otherwise appropriate to bone cuts and/or other features of the implant component. Various sets of guide tools described herein can be designed for a “tibia-first” and/or a “femur-first” cut technique, although various other bones (such as the femur and/or patella, for example) can be prepared as part of and/or independently of the tibia-related procedures. In various embodiments, the tibial implant component suitable for use with such tools can comprise patient-adapted (i.e., patient-specific and/or patient-engineered) features, as well as standard (i.e., non-patient-specific) features. While the designs, procedures and tools are disclosed and described in combination with a patient-adapted implant component, the present disclosure may be employed with varying utility to prepare a patient's tibia to provide sufficient and proper anatomical support for standard and/or modular tibial implant components in a similar manner.
In various embodiments, a first tibial guide tool or jig can include features that correspond to specific anatomical features of a patient's anatomy, and this first jig can be aligned with the patient anatomy and used to prepare a tibial bone for a surgical procedure. In some embodiments, in a first step, the first jig can be used to identify soft tissue structures (e.g., articular cartilage structures) and/or other anatomical structures to be removed, modified and/or otherwise accommodated in some manner to receive a substantially matching or conforming surface of the first jig, which can then be used to establish peg holes and/or pin placements (or other known reference positions) to secure, guide and/or align various guide tools or jigs used to prepare the tibia for one or more implant components. The first jig can be designed to accommodate varying cartilage thickness, if desired, or the jig can be used to identify and/or verify the removal of interfering structures such as articular cartilage and/or osteophytes that may exist on relevant portions of the tibia. The first jig can include an inner surface that substantially conforms to or otherwise accommodates relevant and accessible portions of the outer surface of an uncut tibia, which may include surface features of the articular cartilage, osteophytes and/or other surface features, subchondral bone (e.g., where articular cartilage has been worn, degraded or previously removed by the surgeon) and/or one or more pre-existing implant components and/or cut surfaces (e.g., in the case of an implant revision procedure) or various combinations thereof.
In some embodiments, the first jig can fit onto or otherwise accommodate the tibia in a predetermined position and/or orientation. Optionally, the first jig can comprise a flexible or substantially non-rigid material (or portions thereof) which allows the first jig to deform, flex and/or “snap fit” around some or all of a proximal tibial head. In various embodiments, the inner surface of the first jig can be designed to accommodate, reference, and/or avoid various surface features on the tibia, such as the presence of osteophytes or other anatomical projections on the tibia. In various alternative embodiments, the first jig can include one or more features that align the jig using the aforementioned osteophytes or other anatomical projections.
In various embodiments, anatomical imaging data can be used to design and arrange cap surfaces 1220 and 1230 of first jig 1200 to rest against corresponding portions of subchondral bone surfaces on the proximal tibial head. Subchondral bone surfaces may be utilized to reference the jig, because such surfaces can be relatively easily imaged using X-ray or CT scan technology and segmented by an automated system. In contrast, softer tissues such as articular cartilage may be more difficult to image and/or segment by an operator and/or automated system, but where imaging such as MRI is utilized, the use of such surfaces for alignment is contemplated in various alternative embodiments.
Since the anterior face of the tibia typically does not include significant amounts of articular cartilage, this surface of the tibia can often be readily used as a reference surface. The articulating superior (or cephalad facing) surface of the tibia can be almost entirely covered with cartilage (at least in its healthy state). Where such subchondral bone surfaces are covered by articular cartilage, it may become desirable and/or necessary to remove various overlying articular cartilage (as well as any interfering osteophytes and/or other anatomical structures that may not be accounted for in the initial jig design) to facilitate the ultimate placement of first jig 1200.
To effectuate such placement and alignment using subchondral bone, in some embodiments, first jig 1200 can initially be placed adjacent tibial anterior surface 1300 in a desired orientation (see
Additionally or alternatively, in some embodiments, jig 1200 can include one or more patient-adapted surfaces for engaging a portion of the patient's skin. As illustrated in
A patient-adapted skin-referencing surface may be utilized with a jig in a variety of configurations. In some embodiments, a patient-adapted skin-referencing surface may be integrally formed in the body of a jig. For example, a tibial jig similar to jig 1200 described above, which includes one or more patient-adapted surfaces configured to engage surfaces of the tibia (e.g., 1210, 1220, 1230) and one or more slots (e.g., 1270, 1280, 1290, 1320) configured to guide surgical instruments in predetermined positions and/or orientations, can include a patient-adapted skin-referencing surface. For example, in some embodiments, the tibial jig can include an arm 1110, integrally formed with and extending from the jig and having a patient-adapted surface configured to engage a portion of a skin surface. Additionally or alternatively, a patient-adapted surface configured to engage a portion of a skin surface may be included as an integral surface of any portion of the tibial jig.
Additionally or alternatively, a patient-adapted skin-referencing surface may be formed as a modular component that is releasably attachable to a jig. For example, as depicted in
In various embodiments, a patient-adapted skin-referencing surface may be designed utilizing one or more of the processes described herein and/or in U.S. Patent Publication No. 2012-0209394 for producing patient-adapted features corresponding to other tissue types (e.g., bone, cartilage). For example, in various embodiments, patient-specific imaging data obtained regarding a patient's knee joint may include information regarding a skin surface adjacent to the knee joint.
A patient-adapted skin-referencing surface may be designed to engage a particular skin surface at a variety of different anatomical locations, depending on factors such as the particular tissue for which it is being used to prepare (e.g., knee, proximal tibia, distal femur, hip, shoulder, ankle), the surgical plan, location of skin captured in imagining acquired for designing the surgical system, and/or characteristics of skin surfaces and underlying soft tissue adjacent to the surgical site. For example, in the case of a skin-referencing surface for tibial jig 1200, a patient-adapted skin-referencing surface may be designed to engage a portion of the skin surface residing substantially anterior and adjacent to the shaft of the tibia and distal (inferior) to the incision that provides surgical access to the tibia. In some embodiments, the skin-referencing surface may be designed to be substantially centered in a coronal plane with respect to a ridge or convexity of the tibial shaft. Such a configuration may improve stability and/or registration of the skin-referencing surface when engaging the corresponding referenced skin surface. Accordingly, while in some embodiments, a skin-referencing surface may be substantially aligned in a coronal plane with a mechanical axis of the tibia and/or knee joint, in other embodiments, a skin-referencing surface may be medially or laterally displaced relative to a mechanical axis. In some instances, a skin surface located substantially anterior to the tibial shaft may provide a better (e.g., more stable) reference location than others because a relatively minimal amount of soft tissue may be found between the skin and the underlying bone at this location, thereby potentially reducing the amount of compression and/or movement of the skin surface relative to the tibia.
In various embodiments, identifying/selecting a portion of the skin to be referenced for a tibial jig may include selecting a location that is distal to the patellar ligament insertion and/or the tibial tuberosity. In some embodiments, such locations may be identified based on patient-specific information and/or estimated based on patient-specific information and/or general anatomical information. Additionally or alternatively, in some embodiments, the distalmost portion of skin included in available imaging information of the knee joint may be selected as a portion of skin to be referenced. In some cases, referencing a skin location that is relatively further away from the tissue to be treated may provide improved overall stability and/or accuracy of alignment of the jig. One advantage of utilizing various embodiments of skin-referencing surfaces disclosed herein with a jig can be referencing general anatomical locations that would otherwise be undesirable and/or impossible to reference using surfaces below the skin (e.g., bone surfaces, cartilage surfaces) from the surgical site due to the increased length of incisions and/or general invasiveness of the procedure necessary to provide access to such locations.
In some embodiments, the surgeon may choose to assess the alignment of tibial jig 1200 relative to an axis of the tibia 1305 and/or lower extremity. In some embodiments, this can include connecting an alignment rod extension 1330 to a corresponding fitting 1340 on a projecting arm 1345 of jig 1200 (see
In some embodiments, once jig 1200 has been properly positioned relative to the tibia, the surgeon can drill through openings 1270 and 1280 in the jig 1200 and introduce one or more alignment or anchoring pins into and through the jig, desirably anchoring the pins in the tibia. These pins can be introduced in a relatively parallel fashion, which can allow the jig 1200 to be removed from the tibia and replaced with subsequent jigs, sliding the new jig along the parallel alignment pins and, if desired, into contact with the tibia. Additionally or alternatively, once jig 1200 has been properly positioned relative to the tibia, the surgeon can saw through slot 1320, which can be configured to guide a surgeon's resection of some or all of the proximal head of the tibia along a predetermined cut plane 1190, as depicted in
In some embodiments, exemplary additional jigs that may be provided can include jigs with guide slots configured to guide resection of the tibia at different depths or heights. For example, as depicted in
In various alternative embodiments, tibial jigs may be provided to alter and/or modify the pre-planned surgical procedures in a variety of ways. For example, a single tibial jig can be provided that accommodates a more complex tibial resection, such as medial and lateral resections separated by a step-cut (e.g., vertical and/or angled) surface. In alternative embodiments, a complex tibial surface may be created using a plurality of tibial jigs, such as a first jig that incorporates one or more first cutting or guiding feature(s) (e.g., a lateral, substantially horizontal resection combined with a centrally-located step cut), in combination with a second tibial jig that incorporates one or more second cutting or guiding feature(s) (e.g., a medial, substantially tilted resection combined with a more centrally-located step vertical cut that desirably creates a complex step-cut geometry). The use of multiple tibial jigs, in combination with alignment and securement pins as described herein, can allow for significant improvement in the preparation of the tibial anatomical support surface, even in conditions of reduced visibility (e.g., minimally invasive procedures).
The various additional tibial jig options described herein can provide the surgeon with increased flexibility to assess the tibial anatomy and surgically resect various portions of the tibial head based on intraoperative observations. For example, if a patient has experienced significant or excessive wear on a medial tibial plateau, such as where the patient's varus deformity is greater than 10 degrees, this deformity might not be readily apparent from an initial anatomical assessment and/or non-invasive imaging study. Where tibial jigs have been created without accounting for such a deformity, the resulting planned resection could potentially result in an aggressive lateral resection (e.g., potentially greater than 7 mm), which may be undesirable. Where such a deformity becomes apparent to the surgeon during the procedure (e.g., by direct visualization and/or removal of the overlying articular cartilage, or misalignment of the previously described alignment rod extension), or where the imaging study indicates a potential for the existence of such a deformity (e.g., a greater than 7 mm depth resection identified on the pre-operative surgical plan), the surgeon may choose to utilize the −2 mm tibial cut jig for a primary cut on the tibia, which can desirably raise the tibial resection plane to a depth of 0 mm below the lowest point on the medial tibial plateau.
In various embodiments described herein, the knee rotation axis may be derived from various patient-specific data or combinations of patient-specific data, including from the imaged and/or derived and/or normalized medial/lateral J-curve data (e.g., medial or lateral or combinations of both). Moreover, the knee rotation axis can be derived from J-curve data from the femur and/or tibia or combinations thereof. Additionally or alternatively, the knee rotation axis may be derived from various other axes, including the transepicondylar axis and/or the posterior condylar axis. In a similar manner, the implant motion (e.g., flexion, extension, translation and/or rotation) can be derived from medial and/or lateral tibial slope of the patient and/or from an engineered design and/or combinations thereof, as well as from various combinations of the knee rotation axis and implant motion.
While various exemplary embodiments provided above are generally described with respect to treatment of a knee joint, various aspects and embodiments disclosed herein can be applied to treatment of any anatomical feature and/or joint. For example, patient-adapted skin-referencing surfaces may be designed to engage particular skin surfaces at a variety of different anatomical locations and for use in a variety of different applications. Patient-adapted skin-referencing surfaces may be designed for use with surgical guides for treatments such as, for example, total joint repair, partial joint repair, or ligament repair and in areas such as, for example, the hip, shoulder, or ankle. In various embodiments, patient-adapted skin-referencing surfaces may be designed to reference skin surfaces adjacent to the location of treatment (e.g., hip, shoulder, ankle) and/or to reference skin surfaces adjacent to anatomical features removed or distanced from the location of treatment. By way of example, a guide for use in hip replacements could be provided with a patient-adapted skin-referencing surface designed to reference a skin surface adjacent to the tibia. Such a guide could be used to help set or measure the rotational angle or anteversion of a femoral component being implanted in the hip (currently, surgeons often flex the knee 90 degrees and use the tibial axis to gauge the femoral component rotation in hip replacement procedures). Similarly, a guide referencing skin adjacent to the forearm could be provided for use in shoulder replacements and a guide configured to reference skin over the foot could be provided for use in knee replacements. As another example, surgical boots or extremity holders used during surgical procedures to rigidly hold a patient's extremity (e.g., leg, arm) could be provided with one or more patient-adapted skin-referencing surfaces to optimize the fit of the holder for the particular patient.
The various descriptions contained herein are merely exemplary in nature and, thus, variations that do not depart from the gist of the teachings are intended to be within the scope of the teachings. Such variations are not to be regarded as a departure from the spirit and scope of the teachings, and the mixing and matching of various features, elements and/or functions between various embodiments is expressly contemplated herein. One of ordinary skill in the art would appreciate from this disclosure that features, elements and/or functions of one embodiment may be incorporated into another embodiment as appropriate, unless described otherwise above. Many additional changes in the details, materials, and arrangement of parts, herein described and illustrated, can be made by those skilled in the art. Accordingly, it will be understood that the following claims are not to be limited to the embodiments disclosed herein, can include practices otherwise than specifically described, and are to be interpreted as broadly as allowed under the law.
This application claims the benefit of U.S. Provisional Application No. 61/930,878, entitled “Skin-Referencing Surgical Guides” and filed Jan. 23, 2014, the disclosure of which is incorporated herein by reference in its entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/US2015/012203 | 1/21/2015 | WO | 00 |
Number | Date | Country | |
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61930878 | Jan 2014 | US |