Paper # 179: Biomechanical Analysis of a Single Bundle PCL Graft Tension Pattern at Various Femoral Tunnel with Knee Flexion-Extension Using an In Vivo Finite Element Model

A large spectrum of medical devices exists; it aims to correct deformities associated with spinal disorders. The development of a detailed volumetric finite element model of the osteoligamentous spine would serve as a valuable tool to assess, compare, and optimize spinal devices. Thus the purpose of the study was to develop and initiate validation of a detailed osteoligamentous finite element model of the spine with simulated correction from spinal instrumentation. A finite element of the spine from T1 to L5 was developed using properties and geometry from the published literature and patient data. Spinal instrumentation, consisting of segmental translation of a scoliotic spine, was emulated. Postoperative patient and relevant published data of intervertebral disc stress, screw/vertebra pullout forces, and spinal profiles was used to evaluate the models validity. Intervertebral disc and vertebral reaction stresses respected publishedin vivo,ex vivo, andin silicovalues. Screw/vertebra reaction forces agreed with accepted pullout threshold values. Cobb angle measurements of spinal deformity following simulated surgical instrumentation corroborated with patient data. This computational biomechanical analysis validated a detailed volumetric spine model. Future studies seek to exploit the model to explore the performance of corrective spinal devices.

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Biomechanical analysis of a newly developed interspinous process device conjunction with interbody cage based on a finite element model

PLoS ONE ◽

10.1371/journal.pone.0243771 ◽

2020 ◽

Vol 15 (12) ◽

pp. e0243771

Author(s):

In-Suk Bae ◽

Koang-Hum Bak ◽

Hyoung-Joon Chun ◽

Je Il Ryu ◽

Sung-Jae Park ◽

...

Keyword(s):

Finite Element ◽

Lumbar Spine ◽

Finite Element Model ◽

Element Model ◽

Axial Rotation ◽

Biomechanical Analysis ◽

Interbody Cage ◽

Lateral Bending ◽

Flexion Extension ◽

Interspinous Process Device

Purpose This study aimed to investigate the biomechanical effects of a newly developed interspinous process device (IPD), called TAU. This device was compared with another IPD (SPIRE) and the pedicle screw fixation (PSF) technique at the surgical and adjacent levels of the lumbar spine. Materials and methods A three-dimensional finite element model analysis of the L1-S1 segments was performed to assess the biomechanical effects of the proposed IPD combined with an interbody cage. Three surgical models—two IPD models (TAU and SPIRE) and one PSF model—were developed. The biomechanical effects, such as range of motion (ROM), intradiscal pressure (IDP), disc stress, and facet loads during extension were analyzed at surgical (L3-L4) and adjacent levels (L2-L3 and L4-L5). The study analyzed biomechanical parameters assuming that the implants were perfectly fused with the lumbar spine. Results The TAU model resulted in a 45%, 49%, 65%, and 51% decrease in the ROM at the surgical level in flexion, extension, lateral bending, and axial rotation, respectively, when compared to the intact model. Compared to the SPIRE model, TAU demonstrated advantages in stabilizing the surgical level, in all directions. In addition, the TAU model increased IDP at the L2-L3 and L4-L5 levels by 118.0% and 78.5% in flexion, 92.6% and 65.5% in extension, 84.4% and 82.3% in lateral bending, and 125.8% and 218.8% in axial rotation, respectively. Further, the TAU model exhibited less compensation at adjacent levels than the PSF model in terms of ROM, IDP, disc stress, and facet loads, which may lower the incidence of the adjacent segment disease (ASD). Conclusion The TAU model demonstrated more stabilization at the surgical level than SPIRE but less stabilization than the PSF model. Further, the TAU model demonstrated less compensation at adjacent levels than the PSF model, which may lower the incidence of ASD in the long term. The TAU device can be used as an alternative system for treating degenerative lumbar disease while maintaining the physiological properties of the lumbar spine and minimizing the degeneration of adjacent segments.

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Differences in Anatomy and Kinematics in Asian and Caucasian TKA Patients: Influence on Implant Positioning and Subsequent Loading Conditions in Mobile Bearing Knees

BioMed Research International ◽

10.1155/2014/612838 ◽

2014 ◽

Vol 2014 ◽

pp. 1-10 ◽

Cited By ~ 6

Author(s):

Allan Maas ◽

Tae Kyun Kim ◽

Rolf K. Miehlke ◽

Thomas Hagen ◽

Thomas M. Grupp

Keyword(s):

Finite Element ◽

Finite Element Model ◽

Knee Flexion ◽

Failure Modes ◽

Mobile Bearing ◽

Element Model ◽

Floating Platform ◽

Implant Positioning ◽

Roll Back

The objective of our study was to determine the mechanical stress conditions under tibiofemoral loading with an overlay of knee kinematics in deep flexion on two different mobile bearing designs in comparison to in vivo failure modes. This study investigates the seldom but severe complication of fatigue failure of polyethylene components at mobile bearing total knee arthroplasty designs. Assuming a combination of a floor-based lifestyle and tibial malrotation as a possible reason for a higher failure rate in Asian countries we developed a simplified finite element model considering a tibiofemoral roll-back angle of 22° and the range of rotational motion of a clinically established floating platform design (e.motion FP) at a knee flexion angle of 120° in order to compare our results to failure modes found in retrieved implants. Compared to the failure mode observed in the clinical retrievals the locations of the occurring stress maxima as well as the tensile stress distribution show analogies. From our observations, we conclude that the newly introduced finite element model with an overlay of deep knee flexion (lateral roll-back) and considerable internally rotated tibia implant positioning is an appropriate analysis for knee design optimizations and a suitable method to predict clinical failure modes.

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Biomechanical characteristics of tibio-femoral joint after partial medial meniscectomy in different flexion angles: a finite element analysis

BMC Musculoskeletal Disorders ◽

10.1186/s12891-021-04187-8 ◽

2021 ◽

Vol 22 (1) ◽

Author(s):

Xiaohui Zhang ◽

Shuo Yuan ◽

Jun Wang ◽

Bagen Liao ◽

De Liang

Keyword(s):

Finite Element ◽

Articular Cartilage ◽

Finite Element Model ◽

Medial Meniscus ◽

Lateral Meniscus ◽

Element Model ◽

Magnetic Resonance Images ◽

Biomechanical Analysis ◽

Joint Stress ◽

Tibiofemoral Joint

Abstract Background Recent studies have pointed out that arthroscopy, the commonly-used surgical procedure for meniscal tears, may lead to an elevated risk of knee osteoarthritis (KOA). The biomechanical factors of KOA can be clarified by the biomechanical analysis after arthroscopic partial meniscectomy (APM). This study aimed to elucidate the cartilage stress and meniscus displacement of the tibiofemoral joint under flexion and rotation loads after APM. Methods A detailed finite element model of the knee bone, cartilage, meniscus, and major ligaments was established by combining computed tomography and magnetic resonance images. Vertical load and front load were applied to simulate different knee buckling angles. At the same time, by simulating flexion of different degrees and internal and external rotations, the stresses on tibiofemoral articular cartilage and meniscus displacement were evaluated. Results Generally, the contact stress on both the femoral tibial articular cartilage and the meniscus increased with the increased flexion degree. Moreover, the maximum stress on the tibial plateau gradually moved backward. The maximum position shift value of the lateral meniscus was larger than that of the medial meniscus. Conclusion Our finite element model provides a realistic three-dimensional model to evaluate the influence of different joint range of motion and rotating tibiofemoral joint stress distribution. The decreased displacement of the medial meniscus may explain the higher pressure on the knee components. These characteristics of the medial tibiofemoral joint indicate the potential biomechanical risk of knee degeneration.

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FEBio finite element model of a pediatric cervical spine

Journal of Neurosurgery Pediatrics ◽

10.3171/2021.7.peds21276 ◽

2021 ◽

pp. 1-7

Author(s):

Sean M. Finley ◽

J. Harley Astin ◽

Evan Joyce ◽

Andrew T. Dailey ◽

Douglas L. Brockmeyer ◽

...

Keyword(s):

Finite Element ◽

Cervical Spine ◽

Finite Element Model ◽

Material Properties ◽

Surgical Simulation ◽

Element Model ◽

Axial Stiffness ◽

Published Data ◽

Axial Tension ◽

Flexion Extension

OBJECTIVE The underlying biomechanical differences between the pediatric and adult cervical spine are incompletely understood. Computational spine modeling can address that knowledge gap. Using a computational method known as finite element modeling, the authors describe the creation and evaluation of a complete pediatric cervical spine model. METHODS Using a thin-slice CT scan of the cervical spine from a 5-year-old boy, a 3D model was created for finite element analysis. The material properties and boundary and loading conditions were created and model analysis performed using open-source software. Because the precise material properties of the pediatric cervical spine are not known, a published parametric approach of scaling adult properties by 50%, 25%, and 10% was used. Each scaled finite element model (FEM) underwent two types of simulations for pediatric cadaver testing (axial tension and cardinal ranges of motion [ROMs]) to assess axial stiffness, ROM, and facet joint force (FJF). The authors evaluated the axial stiffness and flexion-extension ROM predicted by the model using previously published experimental measurements obtained from pediatric cadaveric tissues. RESULTS In the axial tension simulation, the model with 50% adult ligamentous and annulus material properties predicted an axial stiffness of 49 N/mm, which corresponded with previously published data from similarly aged cadavers (46.1 ± 9.6 N/mm). In the flexion-extension simulation, the same 50% model predicted an ROM that was within the range of the similarly aged cohort of cadavers. The subaxial FJFs predicted by the model in extension, lateral bending, and axial rotation were in the range of 1–4 N and, as expected, tended to increase as the ligament and disc material properties decreased. CONCLUSIONS A pediatric cervical spine FEM was created that accurately predicts axial tension and flexion-extension ROM when ligamentous and annulus material properties are reduced to 50% of published adult properties. This model shows promise for use in surgical simulation procedures and as a normal comparison for disease-specific FEMs.

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Biomechanical Effect of Lumbar Disc Degeneration Under Flexion/Extension: A Finite Element Model Study

ASME 2007 Summer Bioengineering Conference ◽

10.1115/sbc2007-176190 ◽

2007 ◽

Author(s):

Lissette M. Ruberté ◽

Raghu Natarajan ◽

Gunnar B. J. Andersson

Keyword(s):

Finite Element ◽

Lumbar Spine ◽

Finite Element Model ◽

Disc Degeneration ◽

Pathological Condition ◽

Lumbar Disc ◽

Element Model ◽

Adjacent Segment ◽

Lumbar Disc Degeneration ◽

Flexion Extension

Degenerative disc disease (DDD) is a progressive pathological condition observed in 60 to 80% of the population [1]. It involves changes in both the biochemistry and morphology of the intervertebral disc and is associated with chronic low back pain, sciatica and adult scoliosis [2,3]. The most accepted theory of the effects of DDD on the kinematics of the spine is that proposed by Kirkaldy-Willis and Farfan which states that the condition initiates as a temporary dysfunction, followed by instability and then re-stabilization as the disease progresses [4]. Although there is no clear relationship between disc degeneration and the mechanical behavior of the lumbar spine, abnormal motion patterns either in the form of increased motion or erratic motion have been reported from studies on human cadaveric motion segments [5,6]. To date however no study has looked at how disc degeneration affects the adjacent segment mechanics. IN vivo testing is difficult for these purposes given that specimens are generally obtained from people at the later stages of life and consequently often display multiple pathologies. A finite element model is a viable alternative to study the mechanics of the segments adjacent to the diseased disc. It is hypothesized that moderate degeneration at one level will alter the kinematics of the whole lumbar spine.

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Finite Element Model of the Human Knee Joint to Study Tibio-Femoral Contact Mechanics

10.1115/imece2000-2562 ◽

2000 ◽

Author(s):

Tammy Haut Donahue ◽

Maury L. Hull ◽

Mark M. Rashid ◽

Christopher R. Jacobs

Keyword(s):

Finite Element ◽

Finite Element Model ◽

Degrees Of Freedom ◽

Soft Tissues ◽

Element Model ◽

Human Knee ◽

Human Knee Joint ◽

Solid Models ◽

Flexion Extension ◽

A New Technique

Abstract A finite element model of the tibio-femoral joint in the human knee was created using a new technique for developing accurate solid models of soft tissues (i.e. cartilage and menisci). The model was used to demonstrate that constraining rotational degrees of freedom other than flexion/extension when the joint is loaded in compression markedly affects the load distribution between the medial and lateral sides of the joint. The model also was used to validate the assumption that the bones can be treated as rigid.

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The Distribution of the Periacetabular Strain After THA in Relation to Preservation or Removal of the Subchondral Bone and the Change in Hip Joint Position and the Amount of the Load: Biomechanical Analysis using Cadaver Pelves and Finite Element Model

The Journal of the Korean Orthopaedic Association ◽

10.4055/jkoa.2003.38.6.560 ◽

2003 ◽

Vol 38 (6) ◽

pp. 560

Author(s):

Chul Won Ha ◽

Kye Young Han ◽

Young Min Kim

Keyword(s):

Finite Element ◽

Finite Element Model ◽

Subchondral Bone ◽

Hip Joint ◽

Element Model ◽

Biomechanical Analysis ◽

Joint Position

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Finite element and biomechanical analysis of risk factors for implant failure during tension band plating

Journal of International Medical Research ◽

10.1177/0300060520972075 ◽

2020 ◽

Vol 48 (11) ◽

pp. 030006052097207

Author(s):

Jing Ding ◽

Fei Wang ◽

Fangchun Jin ◽

Zhen-kai Wu ◽

Pin-quan Shen

Keyword(s):

Residual Stress ◽

Finite Element ◽

Finite Element Model ◽

Three Dimensional ◽

Biomechanical Model ◽

Element Model ◽

Tension Band ◽

Biomechanical Analysis ◽

Implant Failure ◽

Element Analysis

Objective Tension band plating has recently gained widespread acceptance as a method of correcting angular limb deformities in skeletally immature patients. We examined the role of biomechanics in procedural failure and devised a new method of reducing the rate of implant failure. Methods In the biomechanical model, afterload (static or cyclic) was applied to each specimen. The residual stress of the screw combined with different screw sizes and configurations were measured and compared by X-ray diffraction. With regard to static load and similar conditions, the stress distribution was analyzed according to a three-dimensional finite element model. Results The residual stress was close to zero in the static tension group, whereas it was very high in the cyclic load group. The residual stress of screws was significantly lower in the convergent group and parallel group than in the divergent group. The finite element model showed similar results. Conclusions In both the finite element analysis and biomechanical tests, the maximum stress of the screw was concentrated at the position where the screws enter the cortex. Cyclic loading is the primary cause of implant failure.

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