Automatic determination of anatomical coordinate systems for three-dimensional bone models of the isolated human knee

Miranda, Daniel L.; Rainbow, Michael J.; Leventhal, Evan L.; Crisco, Joseph J.; Fleming, Braden C.

doi:10.1016/j.jbiomech.2010.01.036

Cited by 95 publications

(105 citation statements)

References 12 publications

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“…The medial-lateral (M-L) axis of the femur was defined by fitting a cylinder to the posterior aspect of the femoral condyles (Fig. 2) using a method described by Miranda et al 39 The axis of the cylinder extends from the most medial to the most lateral aspect of the posterior femoral condyles and the femoral coordinate system origin is Anatomic coordinate systems were created in the femur (left image) and tibia (right image). A cylinder was fit to the posterior femoral condyles to define the femoral medial-lateral axis and a plane was fit to the tibial plateau to define the tibial superior-inferior axis.…”

Section: Methodsmentioning

confidence: 99%

Variations in the three‐dimensional location and orientation of the ACL in healthy subjects relative to patients after transtibial ACL reconstruction

Scanlan

Lai

Donahue³

et al. 2011

Journal Orthopaedic Research

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Recent reports have indicated that anatomical placement of the anterior cruciate ligament (ACL) graft is an important factor for restoration of joint function following ACL reconstruction. The objective of this study was to address a need for a better understanding of anatomical variations in ACL position and orientation within the joint. Specifically, variations in the ACL anatomy were assessed by testing for side-to-side ACL footprint location symmetry in a healthy population relative to the operative and contralateral knee in a patient population after traditional transtibial single-bundle ACL reconstruction. MRI and three-dimensional modeling techniques were used to determine the in vivo tibiofemoral ACL footprint centers and the resulting ACL orientations in both knees of 30 healthy subjects and 30 subjects after transtibial ACL reconstruction. While there were substantial inter-subject variations in ACL anatomy, the side-to-side RMS differences in the ACL footprint center were 1.20 and 1.34 mm for the femur and tibia, respectively, for the healthy subjects and no clinically meaningful intra-subject differences were measured. However, there were large intrasubject side-to-side differences after transtibial ACL reconstruction, with ACL grafts placed 5.63 and 7.64 mm from the center of the contralateral femoral and tibial ACL footprint centers, respectively. Grafts were placed more medial, anterior, and superior on the femur and more posterior on the tibia; producing grafts that were more vertical in the sagittal and coronal planes. Given the large variation among subjects, these findings advocate the use of the contralateral ACL morphology for retrospectively evaluating patientspecific anatomic graft placement. ß

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Section: Methodsmentioning

confidence: 99%

Variations in the three‐dimensional location and orientation of the ACL in healthy subjects relative to patients after transtibial ACL reconstruction

Scanlan

Lai

Donahue³

et al. 2011

Journal Orthopaedic Research

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“…Alternatively, one might choose axes that most accurately depict the interaction among articular surfaces comprising a joint. To describe human knee kinematics, for example, the LAR axis is sometimes oriented normal to the tibial plateau (Miranda et al, 2010;Scanlan et al, 2012;Kaiser et al, 2013). This standard allows the femoral condyles to remain articulated during LAR.…”

Section: Comparison With Previous 3d Kinematic Analysesmentioning

confidence: 99%

“…Distally, polygons forming the two femoral condyles (not including the tibiofibular crest) were isolated and fitted with cylinders, following a method used in human biomechanics (e.g. Miranda et al, 2010). Each cylinder's centroid formed the origin of a distal ACS.…”

Section: Femoral Acssmentioning

confidence: 99%

Long-axis rotation: a missing degree of freedom in avian bipedal locomotion

Kambic

Roberts

Gatesy

2014

Journal of Experimental Biology

104

191

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Ground-dwelling birds are typically characterized as erect bipeds having hind limbs that operate parasagittally. Consequently, most previous research has emphasized flexion/extension angles and moments as calculated from a lateral perspective. Three-dimensional (3D) motion analyses have documented non-planar limb movements, but the skeletal kinematics underlying changes in foot orientation and transverse position remain unclear. In particular, long-axis rotation of the proximal limb segments is extremely difficult to measure with topical markers. Here, we present six degree of freedom skeletal kinematic data from maneuvering guineafowl acquired by markerbased XROMM (X-ray Reconstruction of Moving Morphology). Translations and rotations of the hips, knees, ankles and pelvis were derived from animated bone models using explicit joint coordinate systems. We distinguished sidesteps, sidestep yaws, crossover yaws, sidestep turns and crossover turns, but birds often performed a sequence of blended partial maneuvers. Long-axis rotation of the femur (up to 38 deg) modulated the foot's transverse position. Longaxis rotation of the tibiotarsus (up to 65 deg) also affected mediolateral positioning, but primarily served to either re-orient a swing phase foot or yaw the body about a stance phase foot. Tarsometatarsal long-axis rotation was minimal, as was hip, knee and ankle abduction/adduction. Despite having superficially hinge-like joints, birds coordinate substantial long-axis rotations of the hips and knees to execute complex 3D maneuvers while striking a diversity of non-planar poses.

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“…New methods incorporate historical information and contributions from our work using CT, MR, and live kinematic data of divergent geometric bone patterns, joint contact, and movement to predict contact pressures between general 3-D surfaces or to predict functional movement and wear. We are pursuing these with collaborations at Brown University and University of Auckland, including the potential use of high-resolution registration with dual fluoroscopy [73,104]. The computational methods employ either statistical shape modeling [5,41,66] or rigid body dynamics [41], integrating 3-D data to develop subject-specific models to predict changes over time, such as patterns of joint degeneration, response to fracture, or ligament disruption.…”

Section: Next Stepsmentioning

confidence: 99%

The 2014 ABJS Nicolas Andry Award: The Puzzle of the Thumb: Mobility, Stability, and Demands in Opposition

Ladd

Crisco

Hagert

et al. 2014

Clin Orthop Relat Res

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Automatic determination of anatomical coordinate systems for three-dimensional bone models of the isolated human knee

Cited by 95 publications

References 12 publications

Variations in the three‐dimensional location and orientation of the ACL in healthy subjects relative to patients after transtibial ACL reconstruction

Variations in the three‐dimensional location and orientation of the ACL in healthy subjects relative to patients after transtibial ACL reconstruction

Long-axis rotation: a missing degree of freedom in avian bipedal locomotion

The 2014 ABJS Nicolas Andry Award: The Puzzle of the Thumb: Mobility, Stability, and Demands in Opposition

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