The variability in nociceptive flexion reflex threshold measurement is mostly caused by probabilistic effects of the estimation algorithms: a simulation study.

IF 1.7 4区医学 Q4 NEUROSCIENCES

International Journal of Neuroscience Pub Date : 2025-05-01 Epub Date: 2024-02-09 DOI:10.1080/00207454.2024.2312991

Carlo Jurth, Gregor Lichtner, Thomas Bienert, Falk von Dincklage

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引用次数: 0

Abstract

Objectives: The nociceptive flexion reflex (NFR) and its threshold are frequently used to investigate spinal nociception in humans. Since this threshold (NFRT) is a probabilistic measure, specific algorithms are used for NFRT estimation based on the stochastic occurrence of reflexes at different stimulus intensities. We used a validated simulation model of the NFR to investigate the amount of NFRT measurement variability induced by different estimation algorithms in a steady setting of reduced external influences.

Methods: We simulated the behavior of different estimation algorithms in subjects with an artificially steady baseline NFRT variability (standard deviation: 0 mA) or low baseline NFRT variability (standard deviation: 0.156 mA), equaling a quiet experimental setting. The obtained data were analyzed for NFRT measurement variability caused by the algorithms compared to the baseline variability reflecting other physiological influences.

Results: The standard deviation of the NFRT estimated by the different algorithms ranged between 0.381 and 3.464 mA with 96.8% to 99.6% of the measurement variability attributed to the algorithm used. Out of the investigated algorithms the dynamic staircase algorithm was most precise.

Conclusion: The NFRT measurement variability observed during quiet and steady experimental sessions is mostly caused by the properties of the estimation algorithms, due to the probabilistic nature of the reflex occurrence. Our results give reference for choosing the optimal estimation algorithm to improve measurement precision.

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痛觉屈曲反射阈值测量的变异性主要是由估计算法的概率效应引起的：一项模拟研究。

研究目的痛觉屈曲反射（NFR）及其阈值经常被用于研究人类脊柱痛觉。由于该阈值（NFRT）是一种概率测量方法，因此要根据不同刺激强度下反射的随机发生率来使用特定算法估算 NFRT。我们使用经过验证的 NFR 模拟模型，研究了在外部影响较小的稳定环境下，不同估算算法引起的 NFRT 测量变异性：我们模拟了不同估算算法在受试者中的行为，受试者的基线NFRT变异性人为保持稳定（标准偏差：0mA）或基线NFRT变异性较低（标准偏差：0.156mA），相当于安静的实验环境。对所获得的数据进行了分析，以确定与反映其他生理影响的基线变异性相比，由算法引起的 NFRT 测量变异性：结果：不同算法估算的 NFRT 标准偏差在 0.381mA 至 3.464mA 之间，96.8% 至 99.6% 的测量变异性归因于所使用的算法。在所研究的算法中，动态阶梯算法最为精确：结论：由于反射发生的概率性，在安静和稳定的实验过程中观察到的 NFRT 测量变异性主要是由估计算法的特性造成的。我们的结果为选择最佳估计算法以提高测量精度提供了参考。

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

International Journal of Neuroscience 医学-神经科学

CiteScore

5.10

自引率

0.00%

发文量

132

审稿时长

2 months

期刊介绍： The International Journal of Neuroscience publishes original research articles, reviews, brief scientific reports, case studies, letters to the editor and book reviews concerned with problems of the nervous system and related clinical studies, epidemiology, neuropathology, medical and surgical treatment options and outcomes, neuropsychology and other topics related to the research and care of persons with neurologic disorders. The focus of the journal is clinical and transitional research. Topics covered include but are not limited to: ALS, ataxia, autism, brain tumors, child neurology, demyelinating diseases, epilepsy, genetics, headache, lysosomal storage disease, mitochondrial dysfunction, movement disorders, multiple sclerosis, myopathy, neurodegenerative diseases, neuromuscular disorders, neuropharmacology, neuropsychiatry, neuropsychology, pain, sleep disorders, stroke, and other areas related to the neurosciences.