Speeding Up or Slowing Down: The Effect of Decoupling Speed on Knee Biomechanics and Limb Loading During Split-Belt Treadmill Training in Persons With ACL Reconstruction.

IF 4.5 1区医学 Q1 ORTHOPEDICS

American Journal of Sports Medicine Pub Date : 2025-09-01 Epub Date: 2025-08-18 DOI:10.1177/03635465251365035

Alexa K Johnson, Reagan Recchia, Abdulhamit Tayfur, Chandramouli Krishnan, Riann M Palmieri-Smith

{"title":"Speeding Up or Slowing Down: The Effect of Decoupling Speed on Knee Biomechanics and Limb Loading During Split-Belt Treadmill Training in Persons With ACL Reconstruction.","authors":"Alexa K Johnson, Reagan Recchia, Abdulhamit Tayfur, Chandramouli Krishnan, Riann M Palmieri-Smith","doi":"10.1177/03635465251365035","DOIUrl":null,"url":null,"abstract":"Background: Surgical limb underloading is a common biomechanical adaptation after anterior cruciate ligament reconstruction (ACLR) and has been linked to early degenerative changes in knee cartilage, which are considered precursors to posttraumatic osteoarthritis. Split-belt treadmill training is an emerging rehabilitation approach that modifies load through asymmetric gait behavior, in which one limb walks faster than the other. While previous research has indicated that split-belt treadmill training can modify limb loading, its effects on post-ACLR biomechanics remain unexplored.Purpose/hypothesis: The purpose of this study was to examine the effects of decoupling speed on knee biomechanics and limb loading and model their relationship. It was hypothesized that at faster decoupling speeds, knee loads would increase, and at slower speeds, they would decrease.Study design: Controlled laboratory study.Methods: Knee joint biomechanics were evaluated while 24 participants (15 females; mean age, 23.5 ± 6.5 years; mean height, 1.72 ± 0.08 m; mean mass, 75.61 ± 13.83 kg; mean postoperative time, 7.94 ± 1.74 months) with ACLR walked on an instrumented treadmill (2000 Hz) synced with a 12-camera motion capture system (200 Hz). Participants completed 5 minutes of baseline walking at 1.1 m/s on tied treadmill belts. Afterward, the authors manipulated the speed of the belt under the ACL-reconstructed leg with 8 randomized 5-minute decoupled speed configurations (ACL-reconstructed limb at 30%-170% of 1.1 m/s in 20% increments) with 2 minutes of tied-belt walking between each speed. Bilateral sagittal plane knee moments, angles, and vertical ground-reaction forces were calculated. Statistical parametric mapping was used to evaluate the effects of decoupling speed on the dependent variables during the stance phase of the gait.Results: A clear dose-response relationship between decoupling speed and knee/limb loading was found. Specifically, faster decoupling speeds (130%-170% of 1.1m/s) generally increased peak loads and slower speeds (30% and 50% of 1.1 m/s) decreased peak loads during early stance compared with tied-belt walking for both limbs. In contrast, slower decoupling speeds (30%-90% of 1.1 m/s) led to higher bilateral knee/limb loads at midstance, while faster decoupling speeds (130%-170% of 1.1 m/s) resulted in less knee/limb loading during midstance.Conclusion: These findings suggest that split-belt treadmill training offers a promising method for modulating knee/limb loading post-ACLR.Clinical relevance: Split-belt treadmill training could be a viable intervention to target the loading asymmetry that is prevalent in persons post-ACLR.","PeriodicalId":55528,"journal":{"name":"American Journal of Sports Medicine","volume":" ","pages":"2591-2599"},"PeriodicalIF":4.5000,"publicationDate":"2025-09-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"American Journal of Sports Medicine","FirstCategoryId":"3","ListUrlMain":"https://doi.org/10.1177/03635465251365035","RegionNum":1,"RegionCategory":"医学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"2025/8/18 0:00:00","PubModel":"Epub","JCR":"Q1","JCRName":"ORTHOPEDICS","Score":null,"Total":0}

引用次数: 0

Abstract

Background: Surgical limb underloading is a common biomechanical adaptation after anterior cruciate ligament reconstruction (ACLR) and has been linked to early degenerative changes in knee cartilage, which are considered precursors to posttraumatic osteoarthritis. Split-belt treadmill training is an emerging rehabilitation approach that modifies load through asymmetric gait behavior, in which one limb walks faster than the other. While previous research has indicated that split-belt treadmill training can modify limb loading, its effects on post-ACLR biomechanics remain unexplored.

Purpose/hypothesis: The purpose of this study was to examine the effects of decoupling speed on knee biomechanics and limb loading and model their relationship. It was hypothesized that at faster decoupling speeds, knee loads would increase, and at slower speeds, they would decrease.

Study design: Controlled laboratory study.

Methods: Knee joint biomechanics were evaluated while 24 participants (15 females; mean age, 23.5 ± 6.5 years; mean height, 1.72 ± 0.08 m; mean mass, 75.61 ± 13.83 kg; mean postoperative time, 7.94 ± 1.74 months) with ACLR walked on an instrumented treadmill (2000 Hz) synced with a 12-camera motion capture system (200 Hz). Participants completed 5 minutes of baseline walking at 1.1 m/s on tied treadmill belts. Afterward, the authors manipulated the speed of the belt under the ACL-reconstructed leg with 8 randomized 5-minute decoupled speed configurations (ACL-reconstructed limb at 30%-170% of 1.1 m/s in 20% increments) with 2 minutes of tied-belt walking between each speed. Bilateral sagittal plane knee moments, angles, and vertical ground-reaction forces were calculated. Statistical parametric mapping was used to evaluate the effects of decoupling speed on the dependent variables during the stance phase of the gait.

Results: A clear dose-response relationship between decoupling speed and knee/limb loading was found. Specifically, faster decoupling speeds (130%-170% of 1.1m/s) generally increased peak loads and slower speeds (30% and 50% of 1.1 m/s) decreased peak loads during early stance compared with tied-belt walking for both limbs. In contrast, slower decoupling speeds (30%-90% of 1.1 m/s) led to higher bilateral knee/limb loads at midstance, while faster decoupling speeds (130%-170% of 1.1 m/s) resulted in less knee/limb loading during midstance.

Conclusion: These findings suggest that split-belt treadmill training offers a promising method for modulating knee/limb loading post-ACLR.

Clinical relevance: Split-belt treadmill training could be a viable intervention to target the loading asymmetry that is prevalent in persons post-ACLR.

查看原文本刊更多论文

加速或减速：前交叉韧带重建者在分离带跑步机训练中解耦速度对膝关节生物力学和肢体负荷的影响。

背景：手术肢体负荷不足是前交叉韧带重建（ACLR）后常见的生物力学适应，与膝关节软骨的早期退行性改变有关，这被认为是创伤后骨关节炎的前兆。分带跑步机训练是一种新兴的康复方法，通过不对称的步态行为来改变负荷，其中一条腿比另一条腿走得快。虽然先前的研究表明，分带跑步机训练可以改变肢体负荷，但其对aclr后生物力学的影响仍未被探索。目的/假设：本研究的目的是研究解耦速度对膝关节生物力学和肢体负荷的影响，并建立它们之间的关系模型。假设在更快的解耦速度下，膝关节载荷会增加，而在更慢的速度下，它们会减少。研究设计：实验室对照研究。方法：24例患者（15例女性，平均年龄23.5±6.5岁，平均身高1.72±0.08 m，平均体重75.61±13.83 kg，平均术后时间7.94±1.74个月）在带ACLR的器械跑步机上（2000 Hz）行走，并同步使用12个摄像头运动捕捉系统（200 Hz），对膝关节生物力学进行评估。参与者在绑好的跑步机上以1.1米/秒的速度完成5分钟的基线步行。随后，作者用8个随机的5分钟解耦速度配置来操纵acl重建腿下的皮带速度（acl重建腿以30%-170% 1.1 m/s的速度以20%的增量进行），在每个速度之间进行2分钟的系带行走。计算双侧矢状面膝关节力矩、角度和垂直地面反作用力。采用统计参数映射来评估解耦速度对步态站立阶段的因变量的影响。结果：解耦速度与膝关节/肢体负荷之间存在明显的剂量-反应关系。具体来说，更快的解耦速度（1.1m/s的130%-170%）通常会增加峰值负载，而较慢的解耦速度（1.1m/s的30%和50%）与双腿系带行走相比，会降低早期站立时的峰值负载。相比之下，较慢的解耦速度（1.1 m/s的30%-90%）导致中站时双侧膝关节/肢体负荷增加，而较快的解耦速度（1.1 m/s的130%-170%）导致中站时膝关节/肢体负荷减少。结论：这些研究结果表明，分离带跑步机训练为调节aclr后膝关节/肢体负荷提供了一种很有前途的方法。临床相关性：裂带跑步机训练可能是针对aclr后人群中普遍存在的负荷不对称的一种可行的干预措施。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

American Journal of Sports Medicine 医学-运动科学

CiteScore

9.30

自引率

12.50%

发文量

425

审稿时长

3 months

期刊介绍： An invaluable resource for the orthopaedic sports medicine community, _The American Journal of Sports Medicine_ is a peer-reviewed scientific journal, first published in 1972. It is the official publication of the [American Orthopaedic Society for Sports Medicine (AOSSM)](http://www.sportsmed.org/)! The journal acts as an important forum for independent orthopaedic sports medicine research and education, allowing clinical practitioners the ability to make decisions based on sound scientific information. This journal is a must-read for: * Orthopaedic Surgeons and Specialists * Sports Medicine Physicians * Physiatrists * Athletic Trainers * Team Physicians * And Physical Therapists