Effect of ACL reconstruction graft size on simulated Lachman testing: a finite element analysis

Robert W Westermann; Brian R Wolf; Jacob M Elkins

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Effect of ACL reconstruction graft size on simulated Lachman testing: a finite element analysis

Journal article

Open access

Peer reviewed

Effect of ACL reconstruction graft size on simulated Lachman testing: a finite element analysis

Robert W Westermann, Brian R Wolf and Jacob M Elkins

The Iowa orthopaedic journal, Vol.33, pp.70-77

2013

PMCID: PMC3748896

PMID: 24027464

Appears in Diamond Open Access

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https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3748896/View

Published (Version of record) Open Access

Abstract

ACL reconstructions are frequently performed following ACL injury. The most common treatment is single bundle reconstruction. While ACL reconstructions have been studied clinically and experimentally, quantitative information regarding the local biomechanics the knee following ACL reconstruction is generally lacking. Specifically, the role of graft size on joint stability and soft tissue injury propensity is currently unknown. Therefore, a non-linear contact finite element model was developed to systematically evaluate the relationship between ACL graft size and knee joint biomechanics following ACL reconstruction. A simulated Lachman maneuver was utilized to assess knee joint laxity, meniscal stress, in situ graft loading, and peak articular cartilage contact pressure for ACL graft sizes between 5 and 9 mm, as well as an ACL-deficient knee. The model was validated by corroboration with previously published experimental (cadaveric) data on ACL reconstruction. The 5 mm graft resulted in 30% greater relative AP translation compared to the 9 mm graft; the ACL deficient knee resulted in 2.56-times greater AP translation than the average graft reconstruction. Contact pressure and peak meniscal stresses decreased monotonically for increased values of ACL graft diameter. For all graft diameters, soft tissue stress and articular contact pressure was reduced versus the ACL-deficient knee. ACL reconstruction dramatically affects the local biomechanics of the knee. Stresses occurring in the soft tissues, as well as contact pressure at the articular surfaces, were found to be highly sensitive to ACL graft size. Larger grafts were associated with lower meniscal stress, decreased joint laxity, and less articular cartilage contact stress. Therefore, the current data suggests that increased graft size confers a biomechanical advantage in the ACL reconstructed knee.

Finite Element Analysis

Joint Instability - surgery

Knee Joint - surgery

Biomechanical Phenomena

Anterior Cruciate Ligament - surgery

Anterior Cruciate Ligament Injuries

Computer Simulation

Humans

Anterior Cruciate Ligament Reconstruction

Models, Anatomic

Details

Title: Subtitle: Effect of ACL reconstruction graft size on simulated Lachman testing: a finite element analysis
Creators: Robert W Westermann - University of Iowa Department of Orthopaedics and Rehabilitation University of Iowa 200 Hawkins Drive Department of Orthopaedics and Rehabilitation Iowa City, IA 52242
Brian R Wolf
Jacob M Elkins
Resource Type: Journal article
Publication Details: The Iowa orthopaedic journal, Vol.33, pp.70-77
Publisher: Dept. of Orthopaedics, The University of Iowa; United States
PMID: 24027464
PMCID: PMC3748896
ISSN: 1541-5457
eISSN: 1555-1377
Grant note: T32 GM007337 / NIGMS NIH HHS UL1 RR024979 / NCRR NIH HHS
Language: English
Date published: 2013
Academic Unit: Roy J. Carver Department of Biomedical Engineering; Orthopedics and Rehabilitation; Physical Therapy and Rehabilitation Science; Athletic Training Program
Record Identifier: 9984040314002771

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