Optimization of Serum and Salivary Cortisol Interpolation for Time-Dependent Modeling Frameworks in Healthy Adult Males.

IF 2.2 Q2 SPORT SCIENCES

Sports Pub Date : 2025-04-09 DOI:10.3390/sports13040112

Nathaniel T Berry, Travis Anderson, Christopher K Rhea, Laurie Wideman

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Abstract

Cortisol is an important marker of hypothalamic-pituitary-adrenal function and follows robust circadian and diurnal rhythms. However, biomarker sampling protocols can be labor-intensive and cost-prohibitive.

Objectives: Explore analytical approaches that can handle differing biological sampling frequencies to maximize these data in more detailed and time-dependent analyses.

Methods: Healthy adult males [N = 8; 26.1 (±3.1) years; 176.4 (±8.6) cm; 73.1 (±12.0) kg)] completed two 24 h admissions: one at rest and one including a high-intensity exercise session on the cycle ergometer. Serum and salivary cortisol were sampled every 60 and 120 min, respectively. Six alternative sampling profiles were defined by downsampling from the observed data and creating two intermittent sampling profiles. A polynomial (1-6 degrees) validation process was performed, and interpolation was conducted to match the observed data. Model fit and performance were assessed using the coefficient of determination (R²) and the root mean square error (RMSE), as well as an examination of the equivalence, via two one-sided t-tests (TOST), of 24 h cortisol output between the observed and interpolated data.

Results: Mean serum cortisol output was higher than salivary cortisol (p < 0.001), and no effect was observed for condition (p = 0.61). Second- and third-degree polynomial regressions were determined to be the optimal models for fitting salivary. TOST tests determined that serum data and estimated 24 h output from these models (with interpolation) provided statistically similar estimates to the observed data (p < 0.05).

Conclusions: Second- and third-degree polynomial fits of salivary and serum cortisol provide a reasonable means for interpolation without introducing bias into estimates of 24 h output. This allows researchers to sample biomarkers at biologically relevant frequencies and subsequently match necessary sampling frequencies during the data processing stage of various machine learning workflows.

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健康成年男性血清和唾液皮质醇插值的时间依赖模型框架优化。

皮质醇是下丘脑-垂体-肾上腺功能的重要标志，遵循强烈的昼夜节律。然而，生物标志物取样方案可能是劳动密集型的，成本过高。目的：探索可以处理不同生物采样频率的分析方法，以便在更详细和时间相关的分析中最大化这些数据。方法：健康成年男性[N = 8；26.1（±3.1）年；176.4（±8.6）cm；73.1（±12.0）kg)]完成了两次24小时入院：一次休息，另一次包括在循环计力器上进行高强度运动。血清和唾液皮质醇分别每60分钟和120分钟采样一次。通过对观测数据进行下采样并创建两个间歇采样曲线，定义了六个可选采样曲线。进行多项式（1-6度）验证，并进行插值匹配观测数据。使用决定系数（R2）和均方根误差（RMSE）评估模型拟合和性能，并通过两次单侧t检验（TOST）检查观察数据和内插数据之间24小时皮质醇输出的等效性。结果：平均血清皮质醇分泌量高于唾液皮质醇分泌量（p < 0.001），且对病情无影响（p = 0.61）。二次和三次多项式回归被确定为拟合唾液的最佳模型。TOST测试确定，这些模型（带插值）的血清数据和估计的24小时输出提供了与观察数据相似的统计估计（p < 0.05）。结论：唾液和血清皮质醇的二次和三次多项式拟合提供了合理的插值方法，而不会在24小时输出的估计中引入偏差。这使得研究人员能够以生物学相关的频率对生物标志物进行采样，并随后在各种机器学习工作流程的数据处理阶段匹配必要的采样频率。

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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