The Best Choice of Oxygen Cost Prediction Equation for Computing Post-Stroke Walking Energy Expenditure Using an Accelerometer.

IF 3.7 2区医学 Q1 CLINICAL NEUROLOGY

Neurorehabilitation and Neural Repair Pub Date : 2022-04-01 Epub Date: 2022-02-15 DOI:10.1177/15459683221076469

Maxence Compagnat, Jean-Yves Salle, Maria Vinti, Romain Joste, Jean Christophe Daviet

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引用次数: 2

Abstract

Background: The integration of oxygen cost into the accelerometer's algorithms improves accuracy of total energy expenditure (TEE) values as post-stroke individuals walk. Recent work has shown that oxygen cost can be estimated from specific prediction equations for stroke patients.

Objective: The objective is to the validity of the different oxygen cost estimation equations available in the literature for calculating TEE using ActigraphGT3x as individuals with stroke sequelae walk.

Method: Individuals with stroke sequelae who were able to walk without human assistance were included. The TEE was calculated by multiplying the walking distance provided by an ActigraphGT3x worn on the healthy ankle and the patient's oxygen cost estimated from the selected prediction equations. The TEE values from each equation were compared to the TEE values measured by indirect calorimetry. The validity of the prediction methods was evaluated by Bland-Altman analysis (mean bias (MB) and limits of agreement (LoA) values).

Results: We included 26 stroke patients (63.5 years). Among the selected equations, those of Compagnat and Polese obtained the best validity parameters for the ActigraphGT3x: MB_Compagnat = 1.2 kcal, 95% LoA_Compagnat = [-12.0; 14.3] kcal and MB_Polese = 3.5 kcal, 95% LoA_Polese = [-9.2; 16.1] kcal. For comparison, the estimated TEE value according to the manufacturer's algorithm reported MB_Manufacturer = -15 kcal, 95% LoA_Manufacturer = [-52.9; 22.8] kcal.

Conclusion: The Polese and Compagnat equations offer the best validity parameters in comparison with the criterion method. Using oxygen cost prediction equations is a promising approach to improving assessment of TEE by accelerometers in post-stroke individuals.

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用加速度计计算中风后步行能量消耗的氧耗预测方程的最佳选择。

背景:将氧气消耗整合到加速度计的算法中，可以提高中风后个体行走时总能量消耗(TEE)值的准确性。最近的研究表明，脑卒中患者的氧耗可以通过特定的预测方程来估计。目的:目的是研究文献中使用ActigraphGT3x计算脑卒中后遗症患者TEE的不同氧耗估算方程的有效性。方法:中风后遗症患者不需人工辅助即可行走。TEE通过将佩戴在健康踝关节上的ActigraphGT3x提供的步行距离与根据所选预测方程估计的患者氧耗相乘来计算。将每个方程的TEE值与间接量热法测量的TEE值进行比较。采用Bland-Altman分析(平均偏倚(mean bias, MB)和一致限(limit of agreement, LoA))评价预测方法的有效性。结果:纳入脑卒中患者26例(63.5岁)。在所选方程中，Compagnat和Polese方程对ActigraphGT3x的效度参数最佳:MBCompagnat = 1.2 kcal, 95% LoACompagnat = [-12.0;14.3] kcal和MBPolese = 3.5 kcal, 95% LoAPolese = [-9.2;为了比较，根据制造商算法报告的估计TEE值MBManufacturer = -15 kcal, 95% loammanufacturer = [-52.9;结论:与标准法相比，Polese方程和Compagnat方程提供了最佳的效度参数。使用氧耗预测方程是改进脑卒中后加速计TEE评估的一种有前途的方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Neurorehabilitation and Neural Repair 医学-康复医学

CiteScore

8.30

自引率

4.80%

发文量

审稿时长

6-12 weeks

期刊介绍： Neurorehabilitation & Neural Repair (NNR) offers innovative and reliable reports relevant to functional recovery from neural injury and long term neurologic care. The journal''s unique focus is evidence-based basic and clinical practice and research. NNR deals with the management and fundamental mechanisms of functional recovery from conditions such as stroke, multiple sclerosis, Alzheimer''s disease, brain and spinal cord injuries, and peripheral nerve injuries.