Abstract: A femur cutting jig mechanism (FCJM) is provided having a number N1 of spaced apart FCJM contact points that correspond to a number N1 of spaced apart femur contact points on at least one of a medial condyle, a lateral condyle, and a trochlear groove on the patient's knee. The FCJM contact points are positioned in contact with the knee contact points, and a cut bar mechanism is positioned in contact with the FCJM to provide a location and an angular orientation of a cut bar plane that is to be used to resection and remove a selected portion of the patient's, knee. The FCJM is removed from the patient's knee, and a selected portion of the patent's knee is resectioned and removed. The number N1 is at most 12 in some embodiments.

Abstract: Systems and methods for performing an osteotomy are presented. Examples include forming a fusion osteotomy at a metatarsocuneiform joint of the first ray of a human foot.

Abstract: The invention discloses an osteotomy guide plate and a preparation method thereof. The osteotomy guide plate comprises a substrate, an osteotomy guide standardized part, a guide plate retention hole, a nail hole and a drainage channel; wherein the guide plate retention hole is distributed on the surface of the substrate; the outer end side of the nail hole is integrally formed with a standardized sleeve, and a detachably connected protective inner sleeve standardized part is provided within the standardized sleeve. The preparation method comprises parameter design and model printing, wherein an innovative nail hole positioning method is used in the parameter design. The invention is suitable for the osteotomy operation of different parts, with the advantages of convenient production, high precision and long service life; the preparation method improves the accuracy of opening a hole on the osteotomy guide plate.

Abstract: Biopsy needle guide with pointer for performing a biopsy in a tissue of a patient in conjunction with an imaging method for imaging the tissue and identification of a target volume to be examined, comprising a needle guide head (2), which is freely movable in a plane via at least two degrees of freedom and is mounted so as to be movable about an axis (S) that does not stand perpendicular to this plane, and has a needle passage opening (20, 29), a marker pin (4), which can be inserted in an opening (20, 29) of the head (2) and contains a marker part (41), which can be imaged by the imaging method with good contrast, wherein, when the marker pin (4) is inserted in the opening (20, 29), the marker part (41) lies in the pivot axis (S) of the head (2), as well as a use of such a biopsy needle guide.

Abstract: A patient specific shoulder guide is provided that includes a hub and a plurality of peripheral members. Each of the peripheral members has a peripheral member height dimension between the patient specific contact surface and a side of the peripheral member opposite the patient specific contact surface. At least one of the peripheral members is a low profile peripheral member in which the peripheral height dimension is less than the peripheral height dimension of at least one other of the peripheral members or is less than the hub height.

Abstract: An adjustable femoral pin guide assembly includes a base and a femoral extension rod assembly. The base may be rotated to align with the femoral shaft axis while the femoral extension rod assembly aligns with the leg mechanical axis. An adjustable distal femoral cut guide assembly may be adjusted to provide a range of varus/valgus angles for the distal femoral resection. An adjustable, single-use, disposable four-in-one cut guide may be adjusted to position saw slots for the anterior and posterior femoral resections and the anterior and posterior chamfer cuts for various size femoral components, then locked. A foot holder assembly includes an anterior tibial target that may be adjusted in three dimensions relative to the tibia. A femoral sizing guide includes a sliding drill guide to position a pin in the distal femur in a specific orientation relative to the leg mechanical axis.

Abstract: Aspects of the disclosure may involve a method of generating resection plane data for use in planning an arthroplasty procedure on a patient bone. The method may include: obtaining patient data associated with at least a portion of the patient bone, the patient data captured using a medical imaging machine; generating a three-dimensional patient bone model from the patient data, the patient bone model including a polygonal surface mesh; identifying a location of a posterior point on the polygonal surface mesh; creating a three-dimensional shape centered at or near the location; identifying a most posterior vertex of all vertices of the polygonal surface mesh that may be enclosed by the three-dimensional shape; using the most posterior vertex as a factor for determining a posterior resection depth; and generating resection data using the posterior resection depth, the resection data configured to be utilized by a navigation system during the arthroplasty procedure.

Abstract: A method and system for performing corrective surgery for pediatric or adult acquired flatfoot deformity (“AAFD”), namely, minimally invasive bone extra-articular reconstruction. The method and system comprises attaching a cutting guide to the bone to be operated wherein the cutting guide comprises two or more diverging K-wire channels and a slit configured to guide a burr used by a surgeon to perform osteotomy through the slit. Through the use of the cutting guide, the surgical procedure is simpler and reproducible. Patients will experience a quicker recovery, less pain, less operating room time, less narcotic use, and a better cosmetic result from smaller incisions. The present invention may also be applicable to intra-articular applications.

Abstract: The surgery of revision knee arthroplasty is complex one for both of one and two stages for constraint and hinged implants. The inventor create a method and device to overcome the difficulties of this surgery as determining the size of the revision prosthesis and position of it on the bone after cut and replacement of the failed primary prosthesis. This method enable the surgeons to overcome the abnormalities, distortions and artifacts on bone surface which resulted from the CT scan due to the primary implant. It enables the surgeons to detect the size and position of the implant, also uses land marks on bone surface to design and product the device which use to perform the bone cutting. The device enables the surgeon to determine and guiding the bone cuts below the cement plane in case of cemented implants. Also guiding to the bone cuts below the implant surface in case of cement-less implants.

Abstract: A device for preparing a femur of a patient for receipt of a knee implant in both extension and flexion relative to a resected tibia plateau based on applying tension to medial and lateral collateral ligaments of said patient, comprising a tibial baseplate, a tensioner, the tensioner comprising a tensioner body having a tensioner portion, the tensioner portion affixed to the tibial baseplate, and an expander arm comprising an elongated body portion, a superior side of the elongated body portion having a spiked tip adjacent a posterior end thereof. The spiked tip interacts with an intracondylar notch under tension. The expander arm is operatively connected to the tensioner body via the tensioner portion, the tensioner portion configured for use in selectively raising and lowering the expander arm relative to the tibial baseplate to apply tension to the medial and lateral collateral ligaments in extension or flexion.

Abstract: Alignment precision technology, in which a system accesses image data of a bone to which a reference marker array is fixed. The system generates a three-dimensional representation of the bone and the reference markers, defines a coordinate system for the three-dimensional representation, and determines locations of the reference markers relative to the coordinate system. The system accesses intra-operative image data that includes the bone and a mobile marker array that is attached to an instrument used in a surgical procedure. The system co-registers the intra-operative image data with the three-dimensional representation by matching the reference markers included in the intra-operative image data to the locations of the reference markers. The system determines locations of the mobile markers in the co-registered image and determines a three-dimensional spatial position and orientation of the instrument relative to the bone.

Abstract: A cutting guide and base are provided for use during a total ankle replacement surgical procedure. The cutting guide base includes a slot, a first set of holes and a second set of holes. The first set of holes are positioned along a first flange that extends away from the slot. The second set of holes are positioned along a second flange extending from the slot with a slit included along a wall defining the slot. A method of use of the cutting guide and base is also provided.

Abstract: Instrumentation sets and methods for preparing and implanting an osteochondral allograft to a bone lesion. Instrumentation sets include a pair of guide blocks, a recipient guide block and an allograft guide block, for preparing a cavity at the bone lesion matched by a similarly sized and shaped allograft. Guide blocks provide simple and direct techniques for preparing a matching cavity, formed at the bone lesion, to a bone implant, to be secured within the cavity. Methods include use of the instrumentation to restore bone surfaces for any number of sites using any allograft source. In some cases, the bone lesion is in a humeral head and the allograft source is a talus.

Abstract: Systems and methods facilitate the planning and performance of hip and other surgeries. A computer model of a hip may be generated and displayed. A template of a hip component that replaces a native portion of the hip may be superimposed on the model. Changes in leg length, offset, or anterior-posterior (AP) position as well as a virtual distance between a landmark on the model and a location on the template may be determined. During surgery, a physical distance corresponding to the virtual distance may be obtained. The template may be moved relative to the model to match the physical distance, and new change values in leg length, offset, or anterior-posterior (AP) position may be determined. The new change values may be evaluated, and the surgery may proceed, or the process may be repeated using templates corresponding to alternative components.

Abstract: A device comprises a base. A support is attached to the base. The support is shaped to receive a calf of a person and adapted to receive a wire or pin for securing a tibia of a person. A foot plate is attachable to the base. The foot plate has a plurality of attached members. The members are configured for receiving at least a first wire or pin to fix a foot of the person relative to the foot plate while the foot plate is oriented normal to a superior-inferior direction of the foot. The foot plate is rotatable relative to the base while the foot plate is attached to the base.

Abstract: A device to aid in performing a revision surgery on a joint can comprise: a body member having a bone facing bottom surface, an opposing top surface, a first end portion configured to be disposed on a bone, and a second end portion opposite the first end portion and configured to be disposed on the bone nearer to the joint relative to the first end portion; a connecting member attached to the body member and configured to extend beyond an end of the bone; and a guide member attached to the connecting member and including an opening configured to receive a cutting tool. The device can be sized and shaped based on a computed tomography scan of the bone, and the guide member can be configured so that when the device is installed on the bone, the longitudinal axis of the opening is aligned with a longitudinal direction of the bone.

Abstract: Surgical systems and methods of controlling a surgical instrument are provided. The system includes a surgical instrument having a cutting portion and a body, the body having a handle, a drive motor for driving the cutting portion in a rotating, a reciprocating or a vibrating motion, a plurality of adjustment motors for adjusting a cutting pose of the cutting portion relative to the handle; and, a controller configured to measure the deviations between the cutting pose and a desired pose of the cutting portion and to activate the adjustment motors to reduce those deviations. The method involves coupling a cutting portion of a surgical instrument to a plurality of adjustment motors; holding the handle of the surgical instrument; operating a controller to measure deviations between a cutting pose and a desired pose; and operating the adjustment motors to adjust the cutting pose relative to the handle to reduce the deviations.

Abstract: An orthopaedic surgical instrument includes a patella trial and drill guide that may be used to both perform a surgical trial of the patellofemoral joint and guide the surgeon in drilling a number of anchor holes in the patella of the patient. A method of using such an orthopaedic surgical instrument is also disclosed.

Abstract: The disclosure relates to a fibula bone material removal and transfer template including a center part with a central body each end of which has a separating tool guide portion, at least one of the bone separating tool guide portions being mounted such that it can be moved away from and pushed towards the center part.

Abstract: Systems and methods for generating a surgical plan for altering an abnormal bone using a generic normal bone model are discussed. For example, a system for planning a surgery on an abnormal bone can include a model receiver module configured to receive a generic normal bone model. The generic normal bone model, such as a parametric model derived from statistical shape data, can include a data set representing a normal bone having an anatomical origin comparable to the abnormal bone. An input interface can be configured to receive an abnormal bone representation including a data set representing the abnormal bone. A surgical planning module can include a registration module configured to register the generic normal bone model to the abnormal bone representation by creating a registered generic model. A surgical plan formation module can be configured to identify one or more abnormal regions of the abnormal bone using the registered generic model.

Abstract: A humeral guide is provided that has a first portion or member configured to be positioned on a portion of a proximal humerus. The first portion or member can be configured to rest in a complementary manner on the portion of the proximal humerus. The humeral guide can be configured with apertures defining trajectories through bone, the pin trajectories being diverging in some case and in some cases being selected to enhanced support. A second portion or member and a third portion or member of the humeral guide are configured to be positioned on first and second lateral portions of the humerus distal to a location intended for resection, e.g., between an anatomical neck and a distal end of the humerus. The second and third portions or members or portions are configured to rest in a complementary manner on the first and second lateral portions of the humerus. The humeral guide can be configured to avoid soft tissue between a bone facing side and the humerus. The humeral guide can have a removeable jig portion.

Abstract: The present invention has a simple structure which is convenient in preparation and easy to use. Moreover, in combination with three-dimensional preoperative analysis and rapid molding technology, the present invention has a high customized precision and clinical applicability, and is cost-effective. Based on the three-dimensional preoperative analysis and 3d printing model, the problems of high technical difficulty and cost of the customized accurate implantation of acetabular cup prosthesis in the total hip arthroplasty can be effectively solved, so that the learning curve of operator can be shortened. The present invention can realize the customized accurate implantation of acetabular cup prosthesis without fitting the positioning guiding module with the articular surface area, so that the assisted positioning and assisted reaming depth determination are realized without removing the guiding module when the acetabulum is being reamed, thus the accuracy of the assisted positioning can be guaranteed.

Abstract: A system for preparing an ankle bone to receive an ankle prosthesis is provided. The system includes a patient specific cutting guide that has an anterior surface, a posterior surface, and at least one cutting feature extending through the guide from the anterior surface. The posterior surface comprising a first protrusion or other member that extends from a first end fixed to the posterior surface to a second end disposed away from the first end of the first protrusion. The posterior surface has a second protrusion or other member that extends from a first end fixed to the posterior surface to a second end disposed away from the first end of the second protrusion. The first and second protrusions are spaced apart and have a length such that when the patient specific cutting guide is coupled with first and second bone references, which can include bushings implantable in bones, a clearance gap is provided between the posterior surface and the ankle bone.

Abstract: The present invention relates to a laser assisted surgical resection alignment guide for performing joint resection surgery. The present invention includes a base plate containing a switch which activates orthogonal laser assemblies when the laser assisted surgical resection alignment guide is inserted into a surgical block. The orthogonal laser assemblies each project beams which are each refracted by lenses to project two laser lines onto a human who has been prepared for surgery.

Abstract: Method and apparatus for performing an anterior distal femoral resection. A distal femoral resection is formed and used as a surface from which to base an anterior distal femoral resection cutting guide apparatus. The cutting guide apparatus may include a position block and an attached cutting guide. The position block is placed against the anterior distal femoral resection, and the orientation of the anterior cutting guide is set, at least in part, based on the anterior distal femoral resection.

Abstract: A computer assisted surgery system includes a controller configured to display images of the surgical procedure according to a workflow plan. The controller is configured to retrieve data and determine the workflow plan based on the data. The controller may also be configured to record and store data related to the surgical procedure on, for example, a hospital network.

Abstract: Patient-specific guides for a tibial tubercle osteotomy are provided. The guides include a guide body defining a portion with a bone-engaging surface that conforms as a negative surface to a corresponding surface of a specific patient's tibia, and a guide portion that guides a surgical instrument to a specific location on the specific patient's tibia, wherein the bone-engaging surface and guide portion are configured during a pre-operative planning stage. Methods for performing a tibial tubercle osteotomy with the patient-specific guides are also provided.

Abstract: A system for preparing a bone for receiving an implant is described. The system includes a cutting tool and a cutting guide. The cutting tool includes a cut guard configured to sheath at least a portion of a cutting surface of the cutting tool, and an engagement portion. The cutting guide includes a baseplate configured to be positioned onto the bone and a cut guide portion removably attached to the baseplate. The cut guide portion includes a cutting channel, the cutting channel being sized and shaped to receive the engagement portion of the cut guard and guide the cutting tool to cut a receiving channel into the bone, wherein the receiving channel includes a depth profile matching an implant to be inserted into the receiving channel.

Abstract: A chevron osteotomy guide for use in a minimally invasive bunionectomy procedure comprises an oblong base plate having a modified rectangular shape with two parallel longitudinal sides, and having a semi-circular proximal end and a chevron shaped distal end. The chevron shape is isosceles triangular in which a dorsal edge and a plantar edge intersect to form an apex angle that is less than 90 degrees and greater than 60 degrees. In the bunionectomy procedure, the chevron osteotomy guide is attached to the first metatarsal bone using two K wires or pins through proximal and distal apertures in the guide. The proximal aperture is surrounded by two concentric tubular projections which are orthogonal to the plane of the base plate. These projections consist of an inner tubular core, having a circumference that coincides with that of the proximal aperture, and an outer tubular haft, which serves as a handle by which the surgeon adjusts the position of the guide on the first metatarsal bone.

Abstract: Embodiments of the present application provide technologies related to adaptive surgeon-specific instrumentation, unique preparatory tools and procedures for bone resection and implant devices, and systems for selection of implantation preparatory tools for implantation procedures. The embodiments described herein may, for example, be utilized in connection with knee arthroplasty procedures.

Abstract: A surgical instrument having a first assembly with a first radio-opaque portion providing a profile of a first portion of an intramedullary implant or canal in a bone, and a second assembly having a second radio-opaque portion providing a profile of a second portion of the intramedullary implant or canal. The surgical instrument may also include a third radio-opaque portion providing an alignment feature to provide a fluoroscopic planar check for the surgical instrument.

Abstract: Embodiments of the invention include devices and methods for implanting arthroplasty devices. Some embodiments include designs that allow for use of x-ray images as the only images used to fully and accurately preoperatively and intraoperatively size and align arthroplasty device components and prepare all necessary tissue.

Abstract: Various patient-specific tibial guide housings, patient-specific tibial guide boxes, and methods of resecting the tibial plateau are disclosed herein.

Abstract: A humeral guide is provided that has a first portion or member configured to be positioned on a portion of a proximal humerus. The first portion or member can be configured to rest in a complementary manner on the portion of the proximal humerus. The humeral guide can be configured with apertures defining trajectories through bone, the pin trajectories being diverging in some case and in some cases being selected to enhanced support. A second portion or member and a third portion or member of the humeral guide are configured to be positioned on first and second lateral portions of the humerus distal to a location intended for resection, e.g., between an anatomical neck and a distal end of the humerus. The second and third portions or members or portions are configured to rest in a complementary manner on the first and second lateral portions of the humerus. The humeral guide can be configured to avoid soft tissue between a bone facing side and the humerus. The humeral guide can have a removeable jig portion.

Abstract: A knee arthroplasty assembly for use in a patient's knee joint including a tibia and a femur is disclosed. The assembly can include a tool, a first accessory, and a second accessory. The tool can include a tibial component configured for placement against the tibia and a femoral component configured for placement against the femur. The femoral component can be moveably coupled to the tibial component to place the patient's knee joint in tension by separating the tibia and the femur. The first accessory can be removeably coupled to the tibial component of the tool. The second accessory can be referenced to the first accessory and can have a reference indicator that references the femur for determining a size of the femur.

Abstract: Surgical instrumentation and methods for reaming a bone are disclosed. In some cases, the bone is a glenoid of a shoulder. The surgical instrumentation can include a bushing that acts as a guide for a reamer, which reams the bone.

Abstract: A bone cutting guide for preparing both donor and recipient bone, including one or more articular referencing platforms contoured to a bony surface to be prepared, fixation structure to secure the articular referencing platforms on an articular surface, cutting slots spaced apart from the articular referencing platforms at predetermined distances configured to allow the passage of a saw blade in such a way to remove a bone segment either from an allograft donor or from a graft recipient in such a way that both the removed donor and recipient grafts are of the same exact dimensions, whereby when the allograft is placed in the recipient site of the patient's joint, it completely restores the articular surface to the desired level with healthy articular cartilage from the donor.

Abstract: Embodiments of the invention include a cutting guide (360) and methods of using the cutting guide to prepare bone for one or more knee arthroplasty implants. Some embodiments include an alignment mechanism (200), a cutting head (300), and an ankle clamp (400).

Abstract: A method for placing a first guide wire in a patient is disclosed. The method can include locating a model axis in a model and placing a second guide wire at the model axis, the model axis corresponding to an anatomical axis of an anatomical feature. The method can include coupling a guide plate to the second guide wire and the model. The method can include coupling an axis guide to the guide plate. The method can include decoupling the guide plate and the axis guide as an alignment unit from the second guide wire and coupling the guide plate and the axis guide as an alignment unit to the anatomical feature of the patient. The method can include using the alignment unit to place the first guide wire in the anatomical feature of the patient at the anatomical axis of the anatomical feature.

Abstract: Various surgical devices and methods are disclosed herein. Also disclosed is multi-component prosthesis, which can be used as an ankle prosthesis. One of the disclosed surgical alignment systems includes a guide arm, a ratchet arm frame configured to be coupled slidably to the guide arm, a ratchet arm configured to be coupled to the ratchet arm frame, and a sagittal sizing guide body configured to be coupled to the ratchet arm. The sagittal sizing guide body includes a first radiopaque object disposed at a first position and a second radiopaque object disposed at a second position that is spaced apart from the first position.

Abstract: Guides, systems, and methods for maintaining, correcting and/or fusing joint deformities are disclosed. The guide system including a cut guide, an alignment guide, and at least one directional wire. The cut guide including a base portion, an extension member extending away from a bottom surface of the base portion, and at least one arm extending away from an end of the base portion. The alignment guide, including a base portion, a first extension member extending away from a bottom surface of the base portion in a first direction, and a second extension member extending away from the bottom surface of the base portion in a second direction. Methods of using a guide system for maintaining, correcting and/or fusing joint deformities are also disclosed.

Abstract: The present invention provides a surgical method of osteotomy device with an in-vitro alignment component comprises the steps of: placing a first body component and a second body component on the surface of a bone; engaging an engaging member with a connecting member; inserting at least one aiming bone pin in at least one aiming hole to confirm the cutting direction; inserting at least one fixation bone pins in a plurality of fixation holes to fix the osteotomy device with an in-vitro alignment component; cutting along a guide slot to produce an osteotomy; spreading the osteotomy; placing a bone plate to maintain the osteotomy.

Abstract: A joint alignment method comprises using imaging data of at least a portion of a leg to create a leg model, wherein the leg model includes a femur having medial and lateral condyles and a tibia having tibial plateaus that are configured to engage the medial and lateral condyles at a knee joint, displaying an image of the leg model for manipulation by a user, locating a pivot point within one of the medial or lateral condyles, and rotating, in the displayed image, the tibia with respect to the femur, about the pivot point, to obtain a desired knee joint articulation in a specified plane.

Abstract: An orthopaedic surgical instrument includes a polymer cutting block having a number of metallic cutting guides secured thereto. A pair of metallic bushings function as saw stops at the medial and lateral ends of the cutting slot during an orthopaedic surgical procedure.

Abstract: A method acquires a reconstructed tomographic volume image of anatomy of a patient and constructs a primary axis for a bone of interest in the imaged anatomy. The method forms a sectioned image of the bone in the volume image according to a first plane that is defined to extend along the bone and to extend through two or more articular surfaces. A primary axis for the bone is estimated, wherein the primary axis is midway between outer edges of the bone image that intersect the first sectioning plane. The bone is sectioned in the volume image by a second plane that is orthogonal to the first plane and that extends through the estimated primary axis. The method recalculates the position of the constructed primary axis according to the sectioning of the bone by the second plane. The recalculated constructed primary axis for the bone of interest is displayed.

Abstract: A limb sparring system for replacing a portion of a radius, the radius being adjacent to an ulna, the system comprising a cutting guide including a cut guiding portion for guiding a saw when making a predetermined cut in the radius to excise the portion of the radius, an opposed ulnar mounting portion mountable to the ulna, and a linking portion extending therebetween; and an endoprosthesis configured for replacing the portion of the radius after the portion of the radius has been excised. When the cutting guide is operatively mounted to the radius and ulna, the cut guiding portion and the ulnar mounting portion engage respectively the radius and the ulna in a predetermined spatial relationship relative thereto.

Abstract: The present invention provides an osteotomy device with an extracorporeal alignment component comprising a first body component, a second body component and an extracorporeal alignment component. The first body component has an upper guide edge for forming a cutting track. The second body component has a lower guide edge disposed below the upper guide edge. A guide slot is formed between the upper guide edge and the lower guide edge for guiding the saw blade to cut. The guide slot has a connecting member for connecting the upper guide edge and the lower guide edge. The extracorporeal alignment component has an engaging member and at least one aiming hole. The engaging member is engaged with the connecting member. The aiming hole is used to confirm the direction of cutting.

Abstract: A method of implanting a humeral component includes accessing a humerus and resecting a head portion of the humerus to form a resected surface. The method further includes selecting a first combination sizer and guide device having an outer surface sized complementary to a desired implant head size, positioning the selected first combination sizer and guide device on the resected surface, guiding placement of a guide pin in the humerus with the first combination sizer and guide device, guiding a reamer with the placed guide pin to form a reamed cavity in the humerus, positioning an anchoring portion of a humeral implant base portion in the reamed cavity, positioning the first combination sizer and guide device on the base portion, removing the first combination sizer and guide device from the base portion, and positioning an implant head on the base portion.

Abstract: A workstation having a pair of posts on either side of a clamping plate where a donor bone may be placed on sequentially cut in three separate cutting paths. Cutting gates are attached to the posts and used to provide cutting paths that can be precisely oriented with respect to the meniscus of the donor bone part using visual alignment without any manual measurements. The graft is affixed to a machining clamp and shaved to appropriately shape the sides and form a radius on the bottom of the graft. A tibia is then prepared by using a drill guide to form a pilot hole and then to drill out a large hole for the graft. The drilled hole is expanded and shaped using a rod guide and chisel and then a rasp. The shaped graft may then be implanted into the shaped hole and sutured in place.

Abstract: Systems and methods are disclosed herein. According to one example, the method can comprise imaging a target location of an anatomy of a patient to collect image data regarding at least one of a bone size, a bone orientation and a bone shape of the patient, displaying based upon the collected image data one or more patient-specific characteristics of the anatomy of the patient, and determining one or more of a size, a shape and an orientation for at least one bone graft based at least in part upon the one or more patient-specific characteristics of the anatomy of the patient. The method can convert the one or more patient-specific characteristics of the anatomy of the patient to a setting for a cutting instrument.