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

Spratley, E. Meade; Matheis, Erika A.; Hayes, Curtis W.; Adelaar, Robert S.; Wayne, Jennifer S.

doi:10.1007/s10439-014-1195-1

Cited by 14 publications

(17 citation statements)

References 53 publications

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“…Such models have been successful in examining high-frequency injuries or deformities such as ankle sprains, arch stability, and flatfoot deformity. [12][13][14][15] However, this has left other less common injuries without models or information on their biomechanical behavior. The goal of this study was to create a computational model and confirm it could replicate previously published biomechanics for Lisfranc injuries.…”

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confidence: 99%

“…Selection of the ligament insertion locations, as well as stiffness values, were informed by previous foot and ankle models as well as additional sources from the literature where the ligaments were modeled as linearly elastic with individual element stiffnesses ranging from 30 to 200 N/mm. 13,[15][16][17][18][19][20][21] To account for the in situ tension existing in these structures, a uniform 3% strain was assumed in the neutral scan position.…”

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confidence: 99%

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Computational analysis of the clinical presentation of a ligamentous Lisfranc injury

Perez

Owen

Wayne

2021

Journal Orthopaedic Research

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Lisfranc injuries in the midfoot disrupt key arches of the foot which, if left untreated, can progress to pain, dysfunction, and arthritis. A clinical challenge is that 30-40% of Lisfranc injuries are missed in initial evaluations. The objective of this study was to explore different conditions of limb loading that could influence the biomechanics of the Lisfranc joint in a validated computational model. A computational model was created using SolidWorks software to represent the bones and soft tissues of the lower leg and foot. The model was compared to a cadaveric study of healthy and injured Lisfranc joints. The model was then used to simulate weight-bearing radiographs and evaluate how muscle activity and foot position impacted the diastasis of the Lisfranc joint, a key indicator used to diagnose Lisfranc injuries. The computational model was within one standard deviation of the cadaveric study in all measurements for the healthy and injured foot. When simulating weight-bearing radiographs, the presence of muscle activity or inversion/eversion resulted in less joint separation for the model with ligamentous Lisfranc injuries. While previous research has noted that weight-bearing radiographs provide better conditions to assess Lisfranc injuries than nonweightbearing, this study suggests that in weight-bearing radiographs both altering the position of the foot, possibly due to pain, and the active contraction of the extrinsic flexor muscles can obfuscate indications of a Lisfranc injury.

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Computational analysis of the clinical presentation of a ligamentous Lisfranc injury

Perez

Owen

Wayne

2021

Journal Orthopaedic Research

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“…The challenge with having multiple surgical combinations available is to select the optimal procedure(s) for the individual patient. Computer Aided‐Design (CAD) modeling has been employed to recreate the anatomy and kinematics of the foot and ankle complex in both the intact and diseased states as well as replicating possible surgical procedures . While providing insight into function of the foot/ankle complex as a whole, the use of the CAD models also allowed for exploration into the variations in surgical techniques employed, specifically the amount of MCO translation, from 5 to 15 mm.…”

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confidence: 99%

“…While providing insight into function of the foot/ankle complex as a whole, the use of the CAD models also allowed for exploration into the variations in surgical techniques employed, specifically the amount of MCO translation, from 5 to 15 mm. More recently, rigid‐body kinematic analyses have been used to create patient specific models replicating both the diseased state at initial presentation and the corrected surgical state of each patient . The current work expands on these patient specific models by investigating the effects of adding lateral column treatments to the MCO and FHL tendon transfer, the treatment used by the surgeon for such patients, as these other surgical procedures would be considered clinically to treat a presenting patient.…”

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Patient specific computational models to optimize surgical correction for flatfoot deformity

2016

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Several surgically corrective procedures are considered to treat Adult Acquired Flatfoot Deformity (AAFD) patients, relieve pain, and restore function. Procedure selection is based on best practices and surgeon preference. Recent research created patient specific models of AAFD to explore their predictive capabilities and examine effectiveness of the surgical procedure used to treat the deformity. The models' behavior was governed solely by patient bodyweight, soft tissue constraints, muscle loading, and joint contact without the assumption of idealized joints. The current work expanded those models to determine if an alternate procedure would be more effective for the individual. All procedures incorporated first a tendon transfer and then included one hindfoot procedure, the Medializing Calcaneal Osteotomy (MCO), and one of three lateral column procedures: Evans osteotomy, Calcaneocuboid Distraction Arthrodesis (CCDA), Z osteotomy, and the combination procedures MCO & Evans osteotomy, MCO & CCDA, and MCO & Z osteotomy. The combination MCO & Evans and MCO & Z procedures were shown to provide the greatest amount of correction for both forefoot abduction and hindfoot valgus. However, these two procedures significantly increased joint contact force, specifically at the calcaneocuboid joint, and ground reaction force along the lateral column. With exception to the lateral bands of the plantar fascia and middle spring ligament, the strain present in the plantar fascia, spring, and deltoid ligaments decreased after all procedures. The use of patient specific computational models provided the ability to investigate effects of alternate surgical corrections on restoring biomechanical function in these flatfoot patients. © 2016 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 35:1523-1531, 2017.

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“…Subsequently, we developed pre-and postoperative subjectspecific models for patients planning to undergo an MCO [10][11][12]. An magnetic resonance imaging of each subject's lower leg was used for 3D anatomy capture and tissue assessment.…”

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confidence: 99%

Capturing the 2019 H. R. Lissner Medal Presentation With Jennifer S. Wayne

Wayne

2020

Journal of Biomechanical Engineering

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

Cited by 14 publications

References 53 publications

Computational analysis of the clinical presentation of a ligamentous Lisfranc injury

Computational analysis of the clinical presentation of a ligamentous Lisfranc injury

Patient specific computational models to optimize surgical correction for flatfoot deformity

Capturing the 2019 H. R. Lissner Medal Presentation With Jennifer S. Wayne

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