E. Meade Spratley scite author profile

A highly accurate and reproducible method for determining the orientation of the acetabulum's aperture will benefit both surgeons and patients, by further refining the distinctions between normal and abnormal hip characteristics. Enhanced understanding of the acetabulum could be useful in the diagnostic, planning, and execution stages for surgical procedures of the hip or in advancing the design of new implant systems.

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Validation of a population of patient‐specific adult acquired flatfoot deformity models

Spratley

Matheis

Hayes

et al. 2013

Journal Orthopaedic Research

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Adult acquired flatfoot deformity (AAFD) is a degenerative disease resulting in malalignment of the mid-and hindfoot secondary to posterior tibial tendon dysfunction and increasing implication of ligament pathologies. Despite the complex 3D nature of AAFD, 2D radiographs are still employed to diagnose and stage the disease. Computer modeling techniques allow for accurate 3D recreations of musculoskeletal systems for the investigation of biomechanical factors contributing to disease. Following Institutional Review Board approval, the lower limbs of six diagnosed AAFD sufferers were imaged with MRI, photographs, and X-ray. Next, a radiologist graded the MRI attenuation of eight soft-tissues implicated in AAFD. Six patient-specific rigid-body models were then created and loaded according to patient weight, graded soft-tissues, and extrinsic muscles. Model function was validated using clinically relevant kinematic measures in three planes. Agreement varied depending on the measure, with average absolute deviations of <7˚for angles and <4 mm for distances. Additionally, the clinically favored AP talonavicular coverage angle, ML talo-1st metatarsal angle, and ML 1st cuneiform height showed strong correlations of R 2 ¼ 0.63, 0.75, and 0.85, respectively. Thus, computer modeling offers a promising methodology for the non-invasive investigation of in vivo kinematic behavior in pathologic feet and, once validated, may further be used to investigate biomechanical parameters that are difficult to measure clinically. ß

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Computational Model of the Human Elbow and Forearm: Application to Complex Varus Instability

Spratley

Wayne

2010

Ann Biomed Eng

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Computational modeling is an effective way to predict the response of complex systems to perturbations that are difficult or impossible to measure experimentally. A computational model of the human elbow was developed wherein joint function was dictated by three-dimensional osteoarticular interactions, soft tissue constraints, muscle action, and external loading. The model was validated against two cadaveric experiments that examined the significance of coronoid process (CP) fractures, lateral ulnar collateral ligament (LUCL) ruptures, and radial head (RH) resection in varus stability. The model was able to accurately reproduce the trend of decreasing resistance to varus displacement with increased CP resection, with a significant drop in stability observed at >50% resection. In addition, the model showed that isolated repair of either the LUCL or RH conferred significant varus stability to the joint in the presence of a deficient coronoid, with the ligament responsible for the greatest increase in stability. Predicted magnitudes of joint contact force support claims that the ulnohumeral articulation is the most significant osseous stabilizer of the joint in varus, with the radiohumeral articulation having an increased role with increasing coronoid resection at low flexion angles. With confidence in the predictive ability of this computational model, future simulations could further investigate joint function under other loading scenarios and injury states.

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Plantar Forces in Flexor Hallucis Longus Versus Flexor Digitorum Longus Transfer in Adult Acquired Flatfoot Deformity

et al. 2013

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Effects of Degree of Surgical Correction for Flatfoot Deformity in Patient-Specific Computational Models

et al. 2014

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A cohort of adult acquired flatfoot deformity rigid-body models was developed to investigate the effects of isolated tendon transfer with successive levels of medializing calcaneal osteotomy (MCO). Following IRB approval, six diagnosed flatfoot sufferers were subjected to magnetic resonance imaging (MRI) and their scans used to derive patient-specific models. Single-leg stance was modeled, constrained solely through physiologic joint contact, passive soft-tissue tension, extrinsic muscle force, body weight, and without assumptions of idealized mechanical joints. Surgical effect was quantified using simulated mediolateral (ML) and anteroposterior (AP) X-rays, pedobarography, soft-tissue strains, and joint contact force. Radiographic changes varied across states with the largest average improvements for the tendon transfer (TT) + 10 mm MCO state evidenced through ML and AP talo-1st metatarsal angles. Interestingly, 12 of 14 measures showed increased deformity following TT-only, though all increases disappeared with inclusion of MCO. Plantar force distributions showed medial forefoot offloading concomitant with increases laterally such that the most corrected state had 9.0% greater lateral load. Predicted alterations in spring, deltoid, and plantar fascia soft-tissue strain agreed with prior cadaveric and computational works suggesting decreased strain medially with successive surgical repair. Finally, joint contact force demonstrated consistent medial offloading concomitant with variable increases laterally. Rigid-body modeling thus offers novel advantages for the investigation of foot/ankle biomechanics not easily measured in vivo.

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E. Meade Spratley

A Novel Approach for Determining Three-Dimensional Acetabular Orientation: Results from Two Hundred Subjects

Validation of a population of patient‐specific adult acquired flatfoot deformity models

Computational Model of the Human Elbow and Forearm: Application to Complex Varus Instability

Plantar Forces in Flexor Hallucis Longus Versus Flexor Digitorum Longus Transfer in Adult Acquired Flatfoot Deformity

Effects of Degree of Surgical Correction for Flatfoot Deformity in Patient-Specific Computational Models

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