Anterior cruciate ligament microfatigue damage detected by collagen autofluorescence in situ

Kim, Jinhee; Baek, So Young; Schlecht, Stephen H.; Beaulieu, Mélanie L.; Bussau, Lindsay; Chen, Junjie; Ashton‐Miller, James A.; Wojtys, Edward M.; Holl, Mark M. Banaszak

doi:10.1186/s40634-022-00507-6

Cited by 11 publications

(18 citation statements)

References 39 publications

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“…Thus, to mitigate ACL overuse injuries, we need a greater understanding of how the collagen physiologically, structurally, and functionally responds to repetitive submaximal loading during adolescence. Here, we showed that in vivo submaximal fatigue loading of the ACL in mice reproduces a similar damage signature to that reported in human cadaveric and patient ACLs, 4,8 and by many other research groups across musculoskeletal tissues. 26,28,29,33 Notably, in vivo submaximal fatigue loading generates molecular collagen damage within the ACL, which results in diminished mechanical properties with continued repetitive loading.…”

Section: Discussionsupporting

confidence: 82%

An Adolescent Murine In Vivo Anterior Cruciate Ligament Overuse Injury Model

et al. 2023

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Background: Overuse ligament and tendon injuries are prevalent among recreational and competitive adolescent athletes. In vitro studies of the ligament and tendon suggest that mechanical overuse musculoskeletal injuries begin with collagen triple-helix unraveling, leading to collagen laxity and matrix damage. However, there are little in vivo data concerning this mechanism or the physiomechanical response to collagen disruption, particularly regarding the anterior cruciate ligament (ACL). Purpose: To develop and validate a novel in vivo animal model for investigating the physiomechanical response to ACL collagen matrix damage accumulation and propagation in the ACL midsubstance, fibrocartilaginous entheses, and subchondral bone. Study Design: Controlled laboratory study. Methods: C57BL/6J adolescent inbred mice underwent 3 moderate to strenuous ACL fatigue loading sessions with a 72-hour recovery between sessions. Before each session, randomly selected subsets of mice (n = 12) were euthanized for quantifying collagen matrix damage (percent collagen unraveling) and ACL mechanics (strength and stiffness). This enabled the quasi-longitudinal assessment of collagen matrix damage accrual and whole tissue mechanical property changes across fatigue sessions. Additionally, all cyclic loading data were quantified to evaluate changes in knee mechanics (stiffness and hysteresis) across fatigue sessions. Results: Moderate to strenuous fatigue loading across 3 sessions led to a 24% weaker ( P = .07) and 35% less stiff ( P < .01) ACL compared with nonloaded controls. The unraveled collagen densities within the fatigued ACL and entheseal matrices after the second and third sessions were 38% ( P < .01) and 15% ( P = .02) higher compared with the nonloaded controls. Conclusion: This study confirmed the hypothesis that in vivo ACL collagen matrix damage increases with tissue fatigue sessions, adversely impacting ACL mechanical properties. Moreover, the in vivo ACL findings were consistent with in vitro overloading research in humans. Clinical Relevance: The outcomes from this study support the use of this model for investigating ACL overuse injuries.

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Section: Discussionsupporting

confidence: 82%

An Adolescent Murine In Vivo Anterior Cruciate Ligament Overuse Injury Model

et al. 2023

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“…The exact combination of recovery time, reduced or modified loading, and nutrition that is needed to decrease the potential for sustaining an overuse noncontact ACL injury is not currently known. 8,16 Taken in the aggregate, however, any combination of increased or enhanced recovery, reduced or modified loading, and improved nutrition has high potential to prevent fatigue failure from overuse-related noncontact ACL injury mechanisms. 16 Let's start these discussions.…”

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confidence: 99%

“…Within this scenario, focused attention solely on high volume skill or performance training and competition may get the better of the capacity of the ACL ECM to heal, replacing natural recovery homeostasis with progressive collagen fiber and crosslink degradation, leading to the ligament histopathology that precedes sudden noncontact fatigue rupture. 8,24 For any athlete who has ever experienced this, it remains a memorable event for the rest of their life and often is later recalled as the initial marker that led to the need for more knee surgery.…”

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confidence: 99%

“…Associated with a more wellness-based approach is the fact that, from a medical economics standpoint, society cannot continue to subsidize the growing burden of primary and secondary ACL injury, contralateral knee injuries, and associated surgical and rehabilitation treatment. We have much more to learn, but fatigue failure from overuse is likely associated with many noncontact ACL injuries, and this overuse is likely related to the accumulated training volume associated with early professionalism and specialization in youth and adolescent sports that has replaced what used to be called “play.” 8,13,16…”

mentioning

confidence: 99%

“…We have much more to learn, but fatigue failure from overuse is likely associated with many noncontact ACL injuries, and this overuse is likely related to the accumulated training volume associated with early professionalism and specialization in youth and adolescent sports that has replaced what used to be called "play." 8,13,16 Why not prevent what we can't completely fix? Perhaps in 2023, healthcare providers, coaches, event organizers, parents, and youth and adolescent athletes can resolve to better protect the ACL.…”

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confidence: 99%

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Overuse Noncontact ACL Injury in Young Athletes: Since We Can’t Completely Fix It, Why Not Prevent It?

Nyland¹

2023

Sports Health: A Multidisciplinary Approach

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Functional knee brace use for 21 h leads to a longer duration to achieve peak vertical ground reaction forces and the removal of the brace after 17.5 h results in faster loading of the knee joint

Rishiraj,

Taunton,

Lloyd‐Smith

et al. 2024

Knee surg. sports traumatol. arthrosc.

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PurposeTo investigate the landing strategies used after discontinuing and continuing the use of a functional knee brace (FKB) while performing a drop jump.MethodsFollowing published methodology and power analysis, 23 uninjured male athletes, mean age of 19.4 ± 3.0 years, performed seven tests, during three test conditions (nonbraced, braced and removed brace or continued brace use), over 6 days of 12 testing sessions (S) for a total of 38.5 h. Each subject was provided with a custom‐fitted FKB. This study focuses on the single leg drop jump kinetics during S12 when subjects were randomly selected to remove the FKB after 17.5 h or continued use of FKB. The time to peak vertical ground reaction forces (PVGRF) and PVGRF were recorded on landing in eight trials.ResultsAfter brace removal, a significantly shorter mean time to PVGRF was recorded (9.4 ± 22.9 msec (3.9%), p = 0.005, 95% confidence interval (95% CI): −168.1, 36.1), while continued brace use required a nonsignificant (n.s.) longer mean duration to achieve PVGRF (19.4 ± 53.6 msec (8.9%), n.s., 95% CI: −49.7, 73.4). No significant mean PVGRF difference was found in brace removal (25.3 ± 65.8 N) and continued brace use (25.1 ± 23.0 N).ConclusionRemoval of FKB after 17.5 h of use led to a significantly shorter time to achieve PVGRF, while continued brace use for 21 h required a longer duration to achieve PVGRF, suggesting faster and slower knee joint loading, respectively. Understanding the concerns associated with the use of FKB and the kinetics of the knee joint will assist clinicians in counselling athletes about the risks and benefits of using an FKB.Level of EvidenceLevel II.

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Anterior cruciate ligament microfatigue damage detected by collagen autofluorescence in situ

Cited by 11 publications

References 39 publications

An Adolescent Murine In Vivo Anterior Cruciate Ligament Overuse Injury Model

An Adolescent Murine In Vivo Anterior Cruciate Ligament Overuse Injury Model

Overuse Noncontact ACL Injury in Young Athletes: Since We Can’t Completely Fix It, Why Not Prevent It?

Functional knee brace use for 21 h leads to a longer duration to achieve peak vertical ground reaction forces and the removal of the brace after 17.5 h results in faster loading of the knee joint

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