定制适合的3d打印踝足矫形器在行走过程中的刚度和挠度，以及人体测量变异性的影响

IF 5.2 2区医学 Q2 ENGINEERING, BIOMEDICAL

IEEE Transactions on Neural Systems and Rehabilitation Engineering Pub Date : 2025-08-26 DOI:10.1109/TNSRE.2025.3602709

Jacquelyn R. Brokamp;Ryan S. Pollard;Iván E. Nail-Ulloa;Michael E. Zabala

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引用次数: 0

摘要

增材制造能够快速生产和定制踝足矫形器（afo），与传统制造方法相比具有显著优势。了解这些设备的机械特性，特别是在移动过程中的刚度和挠度，对于它们的有效部署至关重要，因为它可以为未来的台式性能测试提供信息，例如疲劳寿命分析。然而，先前的研究似乎忽略了被动和主动踝关节对行走时刚度的共同影响，限制了机械性能测试的预测准确性。因此，本研究探讨了AFO-踝关节复合准刚度（AFO和踝关节的联合刚度）和参与者特定的人体测量指标（身高和体重）在整个步态周期中如何影响AFO挠度。9名健康，未受损的参与者单侧安装了使用XO-Armor®3d扫描和3d打印技术制造的定制afo。在AFO和非AFO条件下进行步态分析，重点研究了站立的三个亚阶段：可控跖屈（CPF）、可控背屈（CDF）和动力跖屈（PPF）。结果显示，人体测量值与整个站立阶段的AFO-踝关节复合准刚度和背屈时的峰值AFO挠度之间存在显著正相关（$\theta _{\textit {DF}, \textit {max}}$）。CDF (${k}_{\textit {AFO}, \textit {CDF}}\text{)}$与$\theta _{\textit {DF}, \textit {max}}$之间呈反比关系。在CPF期间，跖屈最大挠度（$\theta _{\textit {PF}, \textit {max}}\text{）}$与人体测量值或AFO-踝关节复合准刚度（${k}_{\textit {AFO}, \textit {CPF}}\text{）}$之间没有显著关系。本研究的结果表明，在为定制的AFO制定标准化协议时，应考虑身高、体重和${k}_{\textit {AFO}、\textit {CDF}}$，以提高台式测试的预测准确性，特别是在估计$\theta _{\textit {DF}、\textit {max}}$时。

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Stiffness and Deflection of Custom-Fit, 3D-Printed Ankle-Foot Orthoses During Walking, and the Influence of Anthropometric Variability

Additive manufacturing enables the rapid production and customization of ankle-foot orthoses (AFOs), offering substantial advantages over traditional fabrication methods. Understanding the mechanical properties of these devices, particularly stiffness and deflection during ambulation, is essential for their effective deployment as it may inform future benchtop performance tests, such as fatigue life analysis. However, previous studies seemingly disregard the combined effects of the passive and active ankle joint contributions to stiffness during ambulation, limiting the predictive accuracy of the mechanical performance tests. Accordingly, this study investigates how the AFO-ankle complex quasi-stiffness (the combined stiffness of the AFO and the ankle joint) and participant-specific anthropometric measures (height and body mass) influence AFO deflection throughout the gait cycle. Nine healthy, unimpaired participants were fitted unilaterally with custom-fit AFOs fabricated using XO-Armor® 3D-scanning and 3D-printing technology. Gait analyses were conducted under AFO and no-AFO conditions, focusing on three subphases of stance: controlled plantarflexion (CPF), controlled dorsiflexion (CDF), and powered plantarflexion (PPF). The results revealed significant positive correlations between anthropometric measures and both AFO-ankle complex quasi-stiffness throughout stance phase and peak AFO deflection in dorsiflexion (

$\theta _{\textit {DF}, \textit {max}}$

). Additionally, AFO-ankle complex quasi-stiffness during CDF (

${k}_{\textit {AFO}, \textit {CDF}}\text {)}$

exhibited an inverse relationship with

$\theta _{\textit {DF}, \textit {max}}$

. No significant relationships were identified between maximum deflection in plantarflexion (

$\theta _{\textit {PF}, \textit {max}}\text {)}$

and either anthropometric measures or AFO-ankle complex quasi-stiffness during CPF (

${k}_{\textit {AFO}, \textit {CPF}}\text {)}$

. The findings of this study suggest that height, weight, and

${k}_{\textit {AFO}, \textit {CDF}}$

should be considered when developing standardized protocols for custom-fit AFOs to enhance the predictive accuracy of benchtop testing, particularly when estimating

$\theta _{\textit {DF}, \textit {max}}$

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来源期刊

IEEE Transactions on Neural Systems and Rehabilitation Engineering 医学-工程：生物医学

CiteScore

8.60

自引率

8.20%

发文量

479

审稿时长

6-12 weeks

期刊介绍： Rehabilitative and neural aspects of biomedical engineering, including functional electrical stimulation, acoustic dynamics, human performance measurement and analysis, nerve stimulation, electromyography, motor control and stimulation; and hardware and software applications for rehabilitation engineering and assistive devices.