Mechanical properties and microstructural organization of common ulnar collateral ligament grafts: Palmaris longus and gracilis tendons

Solon, Lorenzo F.; Castile, Ryan M.; Smith, Matthew V.; Lake, Spencer P.

doi:10.1002/jor.25209

Cited by 4 publications

(7 citation statements)

References 32 publications

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“…2 Stress-strain graph of one of the kMCL samples depicting outcomes measures analyzed, including: toe region Young's modulus (slope of the toe region line), linear region Young's modulus (slope of the linear region line), yield stress, maximum stress, and maximum toughness (the area under the curve) to increase with increasing strain for tendons [6,9-11 16]. The strain used in the present study was 5%, which demonstrated a similar decrease in stress compared to previous findings for both PL and kMCL [6,28].…”

Section: Discussionsupporting

confidence: 74%

“…From this sample, a 5 × 50 mm measured section was dissected from the mid-substance of the tendon. Previous research has demonstrated there is no significant difference in the material properties of the distal, proximal, and middle sections of the PL tendon [28].…”

Section: Tissue Preparationmentioning

confidence: 79%

“…Furthermore, the average age of patients undergoing UCLR is 19.1 ± 4.1 years, demonstrating a significantly lower age of PL autografts used surgically [17]. The 50 mm mid-substance graft was selected to fit the customized jig to ensure consistency during mechanical testing and as a result we were unable to characterize the entire graft length, although Solon et al previously demonstrated that the distal, mid, and proximal third of the PL tendon demonstrate similar mechanical properties [28]. The uniaxial tensile test performed in this study was subjected to a constant strain rate of 1% per second and may not characterize the tissues for all loading conditions, although strain rate dependence is relatively weak over physiological loading rates for ligaments and soft-tissues [5].…”

Section: Discussionmentioning

confidence: 99%

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Biomechanical Properties of Knee Medial Collateral Ligament Compared to Palmaris Longus for Ulnar Collateral Ligament Reconstruction

et al. 2023

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Ulnar collateral ligament reconstruction (UCLR) is frequently performed among injured overhead-throwing athletes. One of the most common graft choices when performing a UCLR is the ipsilateral palmaris longus tendon (PL). The purpose of this study was to investigate the material properties of aseptically processed cadaveric knee collateral ligaments (kMCL) as a potential graft source for UCLR and compare them to the gold standard PL autograft. Each PL and kMCL cadaveric sample was subjected to cyclic preconditioning, stress relaxation, and load-to-failure testing, and the mechanical properties were recorded. PL samples exhibited a greater average decrease in stress compared to the kMCL samples during the stress-relaxation test (p < 0.0001). PL samples also demonstrated a greater average Young’s modulus in the linear region of the stress–strain curve compared to the kMCL samples (p < 0.01). The average yield strain and maximum strain of kMCL samples were significantly greater than the PL, p = 0.03 and 0.02, respectively. Both graft materials had comparable maximum toughness and demonstrated a similar ability to deform plastically without rupture. The clinical significance of our result is that prepared knee medial collateral ligament allografts may provide a viable graft material for use in the reconstruction of elbow ligaments.

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Section: Discussionsupporting

confidence: 74%

Section: Tissue Preparationmentioning

confidence: 79%

Section: Discussionmentioning

confidence: 99%

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Biomechanical Properties of Knee Medial Collateral Ligament Compared to Palmaris Longus for Ulnar Collateral Ligament Reconstruction

et al. 2023

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“…33,34 In contrast, recent microstructural and mechanical characterization of the palmaris graft showed that it had an increased modulus, a higher baseline strength of fiber alignment, and greater change in fiber alignment during tensile loading compared with the native UCL. 36 It is possible that the addition of the suture tape in the augmented reconstruction could offer an additional checkrein to share the load and deformation on the palmaris graft, resulting in a lessened potential dynamic realignment and greater similarity of native collagen architecture dynamics to the native UCL. Future studies examining changes in dynamic collagen realignment with and without suture tape could investigate this potential advantage of the augmented reconstruction procedure.…”

Section: Discussionmentioning

confidence: 99%

Biomechanical Effect of Differential Tensioning on Suture-Augmented Ulnar Collateral Ligament Reconstruction of the Elbow

et al. 2022

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Background: Medial ulnar collateral ligament (mUCL) reconstructions are becoming increasingly prevalent among the overhand throwing population. Suture tape augmentation has the potential to provide biomechanical advantages over standard docking reconstruction. However, the optimal tensioning of the suture augmentation technique has not yet been evaluated. Purpose: To compare the subfailure biomechanical performance and graft strain of a standard docking mUCL reconstruction to an mUCL reconstruction using suture tape augmentation tensioned with 1 mm or 3 mm of laxity. Study Design: Controlled laboratory study. Methods: A total of 18 cadaveric elbows were dissected to the mUCL anterior band and biomechanically assessed via a valgus torque protocol to failure. Elbows were randomly assigned to be reconstructed via (1) a standard docking technique, (2) a suture-augmented reconstruction with 1-mm laxity, or (3) a suture-augmented reconstruction with 3-mm laxity. Reconstructed elbows were then subjected to the same loading protocol. Subfailure mechanical properties, failure mode, and mUCL/palmaris strain were assessed. Results: All reconstruction groups had decreased rotational stiffness, torque at 5° of angular rotation, and resilience compared with matched native controls. There were no differences in transition torque between groups. The failure mode of suture-augmented specimens was most often due to bone tunnel failure or reaching the maximum allowable angular displacement. In native controls or docking reconstructions, the primary failure mechanism was in the ligament or graft midsubstance. There were no significant differences in strain on the reconstructed or suture-augmented groups at any laxity compared with native controls. Conclusion: Suture augmentation results in similar subfailure joint biomechanical properties as the standard docking reconstruction procedure at both laxity levels in a cadaveric model. There are improvements in the failure mode of suture-augmented specimens compared with standard docking. Graft strain may be modestly reduced in the 1-mm laxity group compared with other reconstruction groups. Clinical Relevance: Suture augmentation at both 1-mm and 3-mm laxity appears to offer similar advantages in subfailure biomechanics to standard docking reconstruction of the mUCL, with some improvements associated with failure mode. Strain data suggest a potential avoidance of graft stress shielding when tensioning the suture augmentation to 3-mm laxity, which is not as apparent with 1-mm laxity.

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“…Dynamic changes in microstructural organization can be recorded and analyzed via the creation of collagen fiber alignment maps (Figure 2D) (Quinn and Winkelstein, 2008;Lake et al, 2010;Buckley et al, 2013;Skelley et al, 2015;Shah et al, 2016;Zhang et al, 2016;Barnum et al, 2017;Wu et al, 2018;Smith et al, 2019). These spatial maps of collagen organization then can be correlated with tissue microstructural and mechanical properties to link structure-function relationships (Skelley et al, 2015;Skelley et al, 2016;Wright et al, 2016;Smith et al, 2019;Solon et al, 2021).…”

Section: Polarization Imaging and Microscopymentioning

confidence: 99%

Optical Imaging of Dynamic Collagen Processes in Health and Disease

et al. 2022

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Collagen is a major structural component of nearly every tissue in the human body, whose hierarchical organization imparts specific mechanical properties and defines overall tissue function. Collagenous soft tissues are dynamic structures that are in a constant state of remodeling but are also prone to damage and pathology. Optical techniques are uniquely suited for imaging collagen in these dynamic situations as they allow for non-invasive monitoring with relatively high spatiotemporal resolution. This review presents an overview of common collagen dynamic processes associated with human health and disease and optical imaging approaches that are uniquely suited for monitoring, sensing, and diagnosing these changes. This review aims to 1) provide researchers with an understanding of the underlying optical properties of collagen that can be leveraged for extracellular matrix visualization and 2) present emerging opportunities for machine learning approaches to drive multiscale and multimodality solutions.

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Mechanical properties and microstructural organization of common ulnar collateral ligament grafts: Palmaris longus and gracilis tendons

Cited by 4 publications

References 32 publications

Biomechanical Properties of Knee Medial Collateral Ligament Compared to Palmaris Longus for Ulnar Collateral Ligament Reconstruction

Biomechanical Properties of Knee Medial Collateral Ligament Compared to Palmaris Longus for Ulnar Collateral Ligament Reconstruction

Biomechanical Effect of Differential Tensioning on Suture-Augmented Ulnar Collateral Ligament Reconstruction of the Elbow

Optical Imaging of Dynamic Collagen Processes in Health and Disease

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