BONE RESECTION APPARATUS AND METHOD FOR KNEE SURGERY

Abstract

A bone resection apparatus and its method of use for knee surgery are presented. In one aspect of the invention, the apparatus includes a spacer and a tibial cut guide. The spacer has a first surface engageable with the cut distal femoral bone and a second surface opposite the first surface engageable with the uncut proximal tibial bone in joint articulating relationship. The spacer further includes a cut guide support. The tibial cut guide has a cutter guide defining a cut plane and a support engaging element engageable with the cut guide support. The cut guide support and support engaging element cooperate to position the cut plane in relative to the first surface.

Description

FIELD OF THE INVENTION

The invention relates to a bone resection apparatus and method for knee surgery. In particular, the invention relates to an apparatus for spacing and resecting a tibial bone during knee replacement surgery.

BACKGROUND

Degenerative and traumatic damage to the articular cartilage of the knee joint can result in pain and restricted motion. Knee replacement surgery is frequently utilized to alleviate the pain and restore joint function. An incision is made into the knee joint to expose the bones comprising the joint. Cutting guides are used to guide the removal of the articular surfaces that are to be replaced. Artificial joint components are positioned to replace the resected bone ends in order to establish the desired alignment and mechanics of the joint. In a total knee replacement, all of the articulating compartments of the joint are repaired with prosthetic components. However, often only one compartment of the knee joint, typically the medial compartment, is impaired. Thus, in a unicondylar knee replacement, only the damaged compartment is repaired with prosthetic bearing components.

FIGS. 1-3 illustrate several aspects of implant orientation. FIG. 1 illustrates various axes of the lower limb in the frontal plane. Axes can be defined for each segment of the lower limb. For example, the femur 1 has an anatomic axis 2 coinciding generally with its intramedullary canal. It also has a mechanical axis 4, or load axis, running from the center of the femoral head to the center of the knee. The angle 6 between these two axes 2, 4 in the frontal plane varies within the patient population but is on the order of 4-9′. The two axes 2, 4 are approximately superimposed in the sagittal plane (FIG. 2). Likewise, the tibia 3 has a mechanical axis 5 coinciding generally with its intramedullary canal. The mechanical axis 5 of the tibia runs from the center of the knee to the center of the ankle. The transverse axis, or joint line 8, about which the knee flexes, is parallel to a line through the medial and lateral femoral condyles and parallel to the tibial plateau. Typically, the distal femur and proximal tibia are resected to be parallel to the joint line 8, and thus perpendicular to the mechanical axes 4, 5 as indicated at 10 and 12. The intersection of the femoral and tibial mechanical axes 4, 5 may subtend a small angle relative to one another. However, the angle is small such that the axes 4,5 are approximately collinear ay be treated as collinear for most purposes.

FIG. 2 illustrates the knee joint from the side or sagittal view and various bone cuts that may be made to align implant components. The distal femoral cut 10 is typically made perpendicular to the femoral axes 2, 4 in the sagittal plane. The proximal tibial resection 12 is typically cut to match the natural posterior slope, or rotation, 16 of the proximal tibia relative to the mechanical axes 4, 5. The amount of posterior slope 16 relative to a reference line 18 perpendicular to the mechanical axes 4, 5 varies in the patient population but is on the order of T. The distance between the distal femoral cut 10 and proximal tibial cut 12 along the mechanical axes 4, 5 is the extension gap. Other cuts may be made depending on the components that are to be implanted. These include an anterior femoral cut 20, anterior femoral chamfer cut 22, posterior femoral chamfer cut 24, and posterior femoral cut 26. The patella 7 may also be cut 28 to allow for replacement of the patellar articular surface. In a unicondylar knee replacement, only the medial or lateral side of the knee joint is resurfaced. Furthermore, the trochlear, or patellar bearing, surface of the femur is typically left intact in a unicondylar procedure. Unicondylar implant designs vary, but typically only the distal femoral cut 10, posterior femoral chamfer cut 24, and posterior femoral cut 26 are needed to accommodate the unicondylar femoral implant.

FIG. 3 depicts six aspects of component positioning relative to a coordinate system in which the x-axis 30 corresponds approximately to the joint line 8, the z-axis 34 corresponds approximately to the mechanical axes 4 and 5, and the y-axis 32 is normal to the other two. Position along each of thee axes is depicted by arrows. Position along the x, y, and z axes determines the medial/lateral (dx) 36, anterior/posterior (dy) 38, and proximal/distal (dz) 40 positioning of components respectively. Rotation about each of these axes is also depicted by arrows. Rotation about the z-axis (rz) 42 corresponds anatomically to external rotation of the femoral component, rotation about the x-axis (rx) 44 corresponds to extension plane rotation, and rotation about the y-axis (ry) 46 corresponds to varus/valgus rotation.

SUMMARY

The present invention provides a bone resection apparatus and method for knee surgery.

In one aspect of the invention, the apparatus includes a spacer and a tibial cut guide. The spacer has a first surface engageable with the cut distal femoral bone and a second surface opposite the first surface engageable with the uncut proximal tibial bone in joint articulating relationship. The spacer further includes a cut guide support. The tibial out guide has a cutter guide defining a cut plane and a support engaging element engageable with the cut guide support. The cut guide support and support engaging element cooperate to position the cut plane in predetermined posterior slope angular relationship to the first surface.

In another aspect of the invention, the apparatus includes an implant, a spacer, and a tibial cut guide. The implant has a femoral component thickness, a tibial component thickness, and an overall implant thickness which is the sum of the femoral component thickness, the tibial component thickness, and an additional joint laxity distance corresponding to a desired amount of joint laxity. The spacer has a body including a planar seating surface, an arcuate condylar surface arching away from the seating surface generally in the shape of an anatomic femoral condyle, and an elongated support having a longitudinal axis. The spacer has a spacer thickness normal to the planar seating surface. The tibial cut guide has a body with a front surface, a back surface, and an aperture through the body from the front surface to the back surface having a longitudinal axis. The aperture is engageable with the support for linear translation parallel to the aperture longitudinal axis. A cutler guide slot extends through the body from the front surface to the back surface. The cutter guide slot defines a cut plane oriented parallel to the aperture longitudinal axis. The cut plane is spaced a predetermined distance from the aperture such that with the aperture engaged with the support the cut plane is spaced from the arcuate condylar surface a tibial resection distance.

In another aspect of the invention, a method of performing knee surgery includes: resecting a portion of the distal femoral bone; inserting a spacer into the knee joint to abut the cut surface of the femoral bone, the spacer having an arcuate condylar portion facing away from the cut surface; abutting the arcuate condylar portion with the proximal tibial surface; mounting a tibial cut guide on the spacer to position a cut plane at a predetermined posterior slope angle and depth relative to the cut surface of the femoral bone; and guiding a cutter in the cut plane with the cut guide to form a planar surface on the tibia.

BRIEF DESCRIPTION OF THE DRAWINGS

Various examples of the present invention will be discussed with reference to the appended drawings. These drawings depict only illustrative examples of the invention and are not to be considered limiting of its scope.

FIG. 1 is a front elevation view of a tibia and a femur showing axes of the knee joint;

FIG. 2 is a side section view of a knee joint showing typical bone cuts used in replacing the joint surfaces;

FIG. 3 is a perspective view of knee joint showing aspects of component positioning;

FIG. 4 is a side elevation view of a knee joint with a distal condyle resected according to the present invention;

FIG. 5 is a side elevation view of the knee joint of FIG. 4 showing a spacer according to the present invention and the knee being articulated into extension;

FIG. 6 is a side elevation view of the spacer of FIG. 5;

FIG. 7 is a front elevation view of the spacer of FIG. 5;

FIGS. 8-9 are front elevation views of an alternative anatomically shaped spacers;

FIG. 10 is a side elevation view of the knee joint of FIG. 4 showing a cut guide in use with the spacer of FIG. 5;

FIG. 11 is a front elevation view of the knee joint, cut guide, and spacer of FIG. 10;

FIG. 12 is a side elevation view of a unicondylar knee implant;

FIG. 13 is a side elevation view of the cut guide and spacer of FIG. 10;

FIG. 14 is a side elevation view of the cut guide of FIG. 10 shown in use with a thicker spacer;

FIG. 15 is a front elevation view of a tibia and femur showing a varus knee joint;

FIG. 16 is a front elevation view of a tibia and femur showing a normal knee joint; and

FIG. 17 is a front elevation view of a tibia and femur showing a valgus knee joint.

DESCRIPTION OF THE ILLUSTRATIVE EXAMPLES

Embodiments of the present invention include a spacer sized and shaped to temporarily replace a resected femoral condyle to permit noinial articulation of the knee joint intraoperatively. The spacer includes a seating portion for seating on the cut surface of the bone and a condylar portion arching away from the seating portion generally in the shape of an anatomic femoral condyle. The seating portion may engage the bone surface in a simple frictional engagement. The seating portion may include a roughened surface, barbs, spikes, pins, and/or other fixation enhancement features to fix it in position on the bone surface. Separate fasteners such as pins, screws, clips, clamps, and/or other fasteners may also be used to fix the spacer in position. Separate fasteners may engage surfaces, grooves, slots, holes and/or other features of the spacer to hold it in position. For example, the seating portion may include a flat surface frictionally engageable with the cut surface of the femur. The condylar portion of the spacer may be curved in the sagittal plane to match the anterior/posterior curvature of the femoral condyle. The condylar portion may be curved in the frontal plane to match the medial/lateral curvature of the femoral condyle. The spacer may be provided in a variety of sizes and curvatures to permit selection of a spacer that best matches the patient's anatomy. For example, the spacer may be provided in a variety of sizes to permit selection of a spacer that blends smoothly with the resected femur anteriorly, posteriorly, medially, and laterally to permit a gapless, or approximately gapless, fit to the bone and smooth anatomic articulation of the knee joint. The spacer may have a condylar thickness parallel to the mechanical axis of the femur. The spacer may be provided in different condylar thicknesses to permit selection of a spacer thickness to replace the same thickness of bone that was resected to restore pre-surgical kinematics. The spacer thickness may also be chosen to be larger or smaller than the bone removed to correct a varus or valgus abnomiality of the pre-surgical knee.

The spacer may include a cut guide support. The support may include a hole, slot, groove, rail, beam, stem, handle, and/or other structure for supporting a cut guide relative to the spacer. The support may form a predetermined angle relative to the seating portion to position the cut guide at a predetermined angle relative to the seating portion in the sagittal plane. For example the support may incorporate a predetermined posterior slope angle relative to the seating portion. The spacer may be provided in different versions with different posterior slope angles. For example, the posterior slope angle may vary from zero degrees to ten degrees. For example, versions may be provided with three degrees, five degrees, and seven degrees of posterior slope. The cut guide support may engage the cut guide to permit varus/valgus rotation of the cut guide relative to the seating portion in the frontal plane. For example, the cut guide support may have a circular cross section to permit varus/valgus rotation of the cut guide about the support axis. The support may engage the cut guide to restrain the cut guide from rotating relative to the support. For example, the support may have a non-circular cross section to rotationally constrain the cut guide with respect to varus/valgus rotation. For example, the support may have a “T”-shaped, “D”-shaped, “I”-shaped, and/or other non-circularly shaped cross section. For example, the support may include a “T”-shaped stern projecting away from the support at an angle to the seating portion.

A tibial cut guide for use with the spacer may include a body having a support engaging element and a cutter guide. The support engaging element may be positionable at various positions along the support to allow the distance between the cut guide and the bone to be adjusted. The support engaging element may include a hole, slot, groove, rail, beam, stem, handle, and/or other structure for engaging the support. For example, where the support includes a stem extending away from the spacer, the support engaging element may include a complimentary shaped aperture through the cut guide body. The cut guide may be slidable along the support to position the cut guide adjacent to the tibia. The cutter guide may include a planar surface, slot, rail, and/or other suitable cutter guide defining a cut plane and able to guide a saw blade, burr, mill, and/or other suitable cutter within the cut plane. For example, the cutter guide may include a slot defining a cut plane. The slot may receive a saw blade and constrain the saw blade to motion within the cut plane to produce a planar surface on the tibia. The cut plane defined by the slot may be oriented parallel to the support engaging element in the sagittal plane such that adjustment of the cut guide along the support does not change the cut plane location relative to the tibia.

The cut guide may further include a fixation element to accommodate attaching the cut guide to the tibia. The fixation element may include a roughened surface, barbs, spikes, pins, and/or other fixation enhancement features to fix the cut guide in position on the tibia. Separate fasteners such as pins, screws, clips, clamps, and/or other fasteners may also be used to fix the cut guide in position. Separate fasteners may engage the bone and surfaces, grooves, slots, holes and/or other features of the cut guide to hold it in position. For example, the cut guide may include fixation holes for receiving pins to attach the cut guide to the tibia. The fixation element may be oriented parallel to the cut plane and support engaging element so that the cut guide may be removed and repositioned easily on the bone. For example, where the fixation element includes holes for receiving pins, the holes may be parallel to the cut plane and support engaging element so that the cut guide can be slipped off of the pins and support, the knee repositioned, e.g. from extension to flexion, and the cut guide slipped back onto the pins. For example, this may be advantageous where it is desirable to set the cut guide with the knee in extension but where it may be safer or more convenient to cut the tibia with the knee in flexion.

FIG. 4 illustrates a knee joint 50 defined by a distal femur 52 and a proximal tibia 54. The invention will be illustrated in use to perform a unicondylar knee surgery in which a single compartment of the knee is replaced including a portion of one femoral condyle and a portion of the proximal tibia 54. However, it is contemplated that instruments and methods according to the present invention ay also be used in a total knee replacement in which both the medial and lateral portions of the knee are resurfaced. In FIG. 4 a distal portion 56 of the medial femoral condyle has been resected using conventional techniques such as guiding a saw blade to resect the portion 56 while the knee is in flexion. FIGS. 5-7 illustrate a spacer 60 according to the present invention positionable on the cut surface 58 of the distal femur 52 to temporarily replace the resected portion 56. The spacer permits the knee joint 50 to be articulated between flexion and extension to check the joint kinematics and adjust the soft tissue balancing and limb alignment. If adjustments are necessary, the surgeon can recut the femur, release soft tissues, and/or try different thickness spacers 60 until the desired kinematics are achieved. The spacer 60 includes a generally arcuate body 62 having a planar ng portion 64 for seating on the cut surface 58 of the bone and an arcuate condylar portion 66 arching away from the seating portion generally in the shape of an anatomic femoral condyle. In the illustrative spacer, the seating portion 64 engages the bone surface in a simple frictional engagement. The condylar portion 66 is curved both in the sagittal plane (FIG. 6) to match the anterior/posterior curvature of the femoral condyle and the frontal plane (FIG. 7) to match the medial/lateral curvature of the femoral condyle. The spacer 60 is provided in a variety of sizes and curvatures to permit selection of a spacer that best matches the patient's anatomy. As best seen in FIGS. 5 and 11, the spacer 60 blends with the distal femur 52 to provide an approximately gapless fit to the bone and smooth articulation of the joint. The spacer 60 has a condylar thickness 68 parallel to the mechanical axis 4 of the femur. The spacer 60 is provided in different condylar thicknesses 68 to permit selection of a spacer thickness 68 to replace the same thickness of bone 56 that was resected to resto p surgical kinematics or a different thickness 68 to correct a varus or valgus abnormality of the presurgical knee. FIG. 7 illustrates a universal spacer 60 that has a generic projected frontal shape allowing it to be used on both medial and lateral sides of the knee joint 50. FIGS. 8 and 9 illustrate optional spacers 60a and 60b having anatomical frontal shapes that may provide a better fit to the medial and lateral sides of the knee 50. The universal spacer 60 of FIG. 7 reduces the required inventory of spacers while the spacers 60a and 60b of FIGS. 8 and 9 improve the medial/lateral fit of the spacer to the bone.

The spacer 60 includes a cut guide support 70 formed as a “T”-shaped stem projecting anteriorly from the body 62. The support forms a predetermined posterior slope angle 72 with the seating portion 64 to position the cut guide 100 to cut the proximal tibia 54 at a desired posterior slope angle. The spacer 60 is provided in different versions with different posterior slope angles that vary from zero degrees to ten degrees. Preferably, a plurality of spacers 60 is provided with a few representative angles including three degrees, five degrees, and seven degrees of posterior slope.

The cut guide 100 includes a body 102 having a front surface 104, a back surface 106, a top 108, a bottom 110, and side walls 112, 114. A “T”-shaped aperture 116 extends through the body 102 from the front surface 104 to the back surface 106. The aperture 116 engages the support 70 and constrains the cut guide 100 to linear translational adjustment along the support 70 so that the cut guide 100 can be slipped onto the support 70 and slid along the support 70 until it abuts the proximal tibia 54. The engagement of the aperture 116 and support 70 maintain a fixed posterior slope angular relationship between the cut guide 100 and the seating portion 64 and a fixed varus/valgus angular relationship between the cut guide 100 and the seating portion 64. Typically, it is desirable to have the tibial and femoral cut planes oriented at the same varus/valgus angle relative to the knee to avoid femoral component edge loading during articulation of the reconstructed joint. The illustrative resection apparatus maintains parallel varus/valgus rotation by way of the rotationally keyed support 70 and aperture 116. The parallelism of the slot 118 and the cut distal femoral surface 58 of the illustrative resection apparatus can be seen in FIG. 11.

However, there may be surgical situations in which it is desirable to vary the varus/valgus angular relationship of the femoral and tibial cut planes. By providing an optional keyless support 70 and aperture 116 the tibial cut plane 120 may be angled in varus/valgus rotation relative to the seating surface 64 and thus relative to the cut distal femoral surface 58. For example, the support 70 and aperture 116 may be circular to allow varus/valgus rotation about the support 70 axis.

A saw slot 118 extends through the body 102 from the front surface to the back surface 106. The saw slot 118 defines a cut plane 120 (FIG. 10) and guides a saw blade 119 within the cut plane to form a planar surface on the proximal tibia 54. The cut plane 120 is oriented parallel to the aperture 116 such that adjustment of the cut guide 100 along the support 70 does not change the cut plane location on the proximal tibia 54. Fixation holes 122 are formed through the body 102 from the front surface 104 to the back surface 106 to receive fixation pins 123 to maintain the cut guide's 100 position on the proximal tibia 54. The fixation holes 122 are oriented parallel to the cut plane 120 and aperture 116 so that the cut guide 100 may be removed from the support 70 and fixation pins 123 and then replaced on the fixation pins 123 during surgery if desired by the surgeon. For example, after establishing the cut guide 100 position, the surgeon may desire to remove the spacer 60 and/or reposition the knee before making the tibial cut. With the fixation pin holes 122 parallel to the support aperture 116, the cut guide 100 may easily be slid off of the pins 123 and support 70 and subsequently replaced on the pins 123 in the same position.

In knee replacement surgery, an incision is made to expose a portion of the knee. The illustrative unicondylar implants and instruments are suitable for a minimally invasive approach to the knee in which the incision is minimized to reduce trauma to the patient and speed recovery from the surgery. In particular, the simple, streamlined design of the spacers 60 and cut guides 100 permits them to be positioned through narrow incisions. The support 70 also is convenient as a handle for manipulating the spacers into and out of the incision. In an illustrative procedure, the knee 50 is flexed to approximately ninety degrees of flexion (FIG. 4) and a portion 56 of the distal femur 52 is resected. The resection is oriented so that the cut surface 58 of the distal femur 52 is perpendicular to the mechanical axis of the 4 of the femur 1. A spacer 60 is chosen that fits the cut surface 58 of the distal femur 52 and is positioned with the support 70 facing anteriorly (FIG. 5). The knee 50 is articulated through its range of motion with the tibia bearing on the condylar surface 66 of the spacer 60 while the surgeon assesses the limb alignment and soft tissue balancing. If adjustments are necessary, the surgeon may recut the femur, release soft tissues, and/or try a different thickness of spacer. When the surgeon is satisfied with the knee 50 kinematics, he returns the knee 50 to full extension and slides a cut guide 100 onto the support 70 (FIG. 10) until the back surface 106 of the cut guide 100 abuts the proximal tibia 54. The angle of the support 70 relative to the seating portion 64 establishes the posterior slope of the proximal tibia 54 relative to the mechanical axis of the femur. With the knee 50 in full extension, the saw slot 118 defines a cut plane 120 corresponding to the desired posterior slope angle. The cut guide 100 is fixed to the tibia by inserting pins through the fixation holes 122 and into the proximal tibia 54. With the cut guide 100 fixed to the proximal tibia 54, a saw blade 119 is guided through the saw slot 118 to resect a portion 55 of the proximal tibia in the cut plane 120. Optionally, the cut guide 100 can be removed from the fixation pins before the tibial resection performed to permit the spacer 60 to be removed and/or the knee to be repositioned into a more convenient or safer position for the cut. The cut guide 100 can then be replaced over the pins to restore the desired orientation of the cut guide 100 and the resection performed. Additional femoral bone cuts are made as necessary to finish the femur to receive the femoral implant.

An illustrative implant 200 is shown in FIG. 12. The implant 200 includes a femoral component 202 having a femoral component thickness 204 and a tibial component 206 having a tibial component thickness 208. The components 202, 206 are shown spaced apart a small amount corresponding to a desired joint laxity 210. A smaller spacing results in a tighter knee and a larger spacing results in a looser knee. The total of the femoral component thickness 204, the tibial component thickness 208, and the joint laxity 210 is represented by an overall implant thickness 212.

As seen in FIGS. 13 and 14, the thickness 68 of the spacer 60 and the relationship of the saw slot 118 to the support aperture 116 determines the depth of the tibial cut 124. The cut depth 124 is shown being measured at approximately one-half the anterior/posterior distance of the tibial plateau as indicated by the centerline 126. The distance 128 from the seating portion 64 to the cut plane 120 corresponds to the overall implant thickness 212. For surgery on a knee with normal pre-surgical limb alignment (FIG. 16), the spacer thickness 68 is chosen to correspond to the femoral component thickness 204 plus the desired joint laxity 210. This is evaluated during the articulation and adjustment discussed relative to FIG. 5. The resulting tibial cut depth 124 will then correspond to the tibial component thickness 208 and the post-surgical limb alignment will match the pre-surgical alignment. However, for correction of a varus knee (FIG. 15), the spacer thickness 68 is chosen to correct the limb alignment and will be different from the femoral component thickness 204. For unicondylar replacement of the medial compartment, increasing the bone spacing on the medial side 220 of the knee 50 will correct the limb alignment. Thus, inserting a thicker spacer 60 during the articulation and adjustment step (FIG. 5) of the operation will correct the alignment. During the tibial resection step of the surgery, the increased spacer 60 thickness 68 decreases the tibial cut depth 124 as seen in FIG. 14. When the implant components are inserted into the prepared knee, the tibial component will be positioned higher and thus the joint line 8 on the medial side of the knee 50 is raised and the varus deformity is corrected. For a valgus deformity (FIG. 17), a thinner spacer can be used to increase the tibial cut depth 124 and lower the joint line 8 on the medial side of the knee 50.

Although examples of a bone resection apparatus and its use have been described and illustrated in detail, it is to be understood that the same is intended by way of illustration and example only and is not to be taken by way of limitation. The invention has been illustrated in the context of a spacer and resection guide for spacing and resecting the medial side of the tibial plateau during unicondylar knee replacement surgery. However, the bone resection apparatus may be configured in other shapes and for use at other locations within a patient's body. Accordingly, variations in and modifications to the bone resection apparatus and its use will be apparent to those of ordinary skill in the art, and the following claims are intended to cover all such modifications and equivalents.

Claims

1. A system for guiding a bone cut comprising:

at least one spacer having a first surface configured to engage a surface of a cut distal femoral bone, a second surface opposite the first surface configured to engage an uncut proximal tibial bone and to reestablish a joint articulating relationship between the cut femoral bone and the uncut tibial bone;

a tibial cut guide defining a cut plane and a support engaging element; and

a cut guide support engageable with the at least one spacer and the tibial cut guide to position the cut plane at a predetermined posterior slope angle relative to the first surface.

2. The system of claim 1, wherein the surface is planar.

3. The system of claim 1, wherein the second surface comprises an arcuate condylar surface generally in the shape of an anatomic femoral condyle.

4. The system of claim 1, wherein the second surface is curved in a sagittal plane to correspond to an anterio/posterior curvature of an anatomic femoral condyle.

5. The system of claim 4, wherein the second surface is curved in a frontal plane to correspond to a medial/lateral curvature of an anatomic femoral condyle.

6. The system of claim 4, wherein the at least one spacer comprises a plurality of spacers having a convexly curved second surface, each one of the second surfaces having a different curvatures to permit selection of a spacer that best matches a patient's anatomy or that best corrects an anatomical defect in the patient.

7. The system of claim 3, wherein the at least one spacer has a condylar thickness, the at least one spacer comprising a plurality of spacers each having a different condylar thickness.

8. The system of claim 1, wherein the cut guide support comprises an elongated member having a longitudinal axis and in an assembled configuration the cut guide support projects outwardly from the at least one spacer.

9. The system of claim 1, wherein in an assembled configuration with the at least one spacer a longitudinal axis of the cut guide support forms a predetermined tibial posterior slope angle relative to the first surface.

10. The system of claim 1, wherein the at least one spacer comprises a plurality of spacers and wherein in an assembled configuration with the cut guide support each one of the plurality of spacers has a different posterior slope angle between zero and ten degrees.

11. The system of claim 1, wherein the cut support comprises a non-circular cross section and the tibial cut guide comprises a an aperture having a non-circular cross section configured to receive the support, and wherein in an assembled configuration the aperture and cut guide support permit linear translation of the cut guide relative to the at least one spacer and maintain a fixed posterior slope angle between the cut guide and the at least one spacer.

12. The system of claim 1, wherein the cut guide support comprises a circular cross section and the tibial cut guide comprises an aperature having a circular cross section configured to receive the cut guide support, and wherein in an assembled configuration the aperture and the cut guide support permit linear translation of the cut guide relative to the at least one spacer, varus/valgus rotation of the cut guide relative to the at least one spacer, and maintain a fixed posterior slope angle between the cut guide and the at least one spacer.

13. The system of claim 1, wherein the cut guide includes a saw slot defining the cut plane, and wherein in an assembled configuration the cut plane is oriented parallel to the longitudinal axis of the cut guide support.

14. The system of claim 1, wherein the cut guide includes at least one fixation hole having a longitudinal axis, the at least one fixation hole being oriented such that in an assembled configuration the longitudinal axis of the fixation hole is parallel to the longitudinal axis of the cut guide support.

15. A system comprising:

an implant system including a femoral component having a femoral component thickness and a tibial component having a tibial component thickness, the implant system having an overall implant thickness which is the sum of the femoral component thickness, the tibial component thickness; and an additional joint laxity distance corresponding to a desired amount of joint laxity;

at least one spacer having a body including a planar seating surface, an arcuate condylar surface arching away from the seating surface generally in the shape of an anatomic femoral condyle, and an elongated support having a longitudinal axis, the spacer having a spacer thickness normal to the planar seating surface; and

a tibial cut guide including an aperture having a longitudinal axis, the aperture configured to engage the cut guide support for linear translation of the cut guide parallel to the aperture longitudinal axis, a cutter guide slot defining a cut plane oriented parallel to the aperture longitudinal axis, the cut plane being spaced a predetermined distance from the aperture such that in an assembled configuration the cut plane is spaced from the arcuate condylar surface by a tibial resection distance.

16. The apparatus of claim 15, wherein the at least one spacer comprises a plurality of spacers, each one of the plurality of spacers having a different spacer thickness, wherein in an assembled configuration each one of the pluarlaity of spacers establishes a different tibial resection distance.

17. The apparatus of claim 15, wherein in an assembled configuration the cut plane is spaced from the planar seating surface a distance equal to the overall implant thickness.

18. A method of performing knee surgery comprising:

resecting a portion of a distal femoral bone;

inserting a spacer into the knee joint to abut a cut surface of the distal femoral bone, the spacer having an arcuate condylar portion facing away from the cut surface;

abutting the arcuate condylar portion with a surface of a proximal tibial bone:

mounting a tibial cut guide on the spacer to position a cut plane at a predetermined posterior slope angle and at a depth relative to the cut surface of the distal femoral bone; and

guiding a cutter in the cut plane to form a planar surface on the proximal tibial bone.

19. The method of claim 18, further comprising, before the step of mounting the tibial cut guide, the steps of:

articulating the knee joint between flexion and extension such that the surface of the proximal tibial bone articulates with the arcuate condylar portion of the spacer to evaluate knee kinematics; and

placing the knee joint in extension.

20. The method of claim 18, further comprising, after guiding a cutter, mounting a femoral implant component on the resected distal femoral bone and mounting a tibial implant component on the proximal tibial bone, wherein inserting a spacer comprises inserting a spacer having a thickness corresponding to the femoral implant component thickness plus an additional thickness corresponding to a desired joint laxity such that the cut guide guides the cutter to remove a portion of proximal tibial bone equal in thickness to the tibial implant component thickness.