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一种利用训练负荷指标预测耐力运动期间碳水化合物和能量消耗的新方法。

A Novel Method to Predict Carbohydrate and Energy Expenditure During Endurance Exercise Using Measures of Training Load.

作者信息

Rothschild Jeffrey A, Hofmeyr Stuart, McLaren Shaun J, Maunder Ed

机构信息

High Performance Sport New Zealand (HPSNZ), 17 Antares Place, Mairangi Bay, Auckland, 0632, New Zealand.

Sports Performance Research Institute New Zealand (SPRINZ), Auckland University of Technology, Auckland, New Zealand.

出版信息

Sports Med. 2025 Mar;55(3):753-774. doi: 10.1007/s40279-024-02131-z. Epub 2024 Nov 1.

DOI:10.1007/s40279-024-02131-z
PMID:39487383
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11985602/
Abstract

BACKGROUND

Sports nutrition guidelines recommend carbohydrate (CHO) intake be individualized to the athlete and modulated according to changes in training load. However, there are limited methods to assess CHO utilization during training sessions.

OBJECTIVES

We aimed to (1) quantify bivariate relationships between both CHO and overall energy expenditure (EE) during exercise and commonly used, non-invasive measures of training load across sessions of varying duration and intensity and (2) build and evaluate prediction models to estimate CHO utilization and EE with the same training load measures and easily quantified individual factors.

METHODS

This study was undertaken in two parts: a primary study, where participants performed four different laboratory-based cycle training sessions, and a validation study where different participants performed a single laboratory-based training session using one of three exercise modalities (cycling, running, or kayaking). The primary study included 15 cyclists (five female; maximal oxygen consumption [ Omax], 51.9 ± 7.2 mL/kg/min), the validation study included 21 cyclists (seven female; Omax 53.5 ± 11.0 mL/kg/min), 20 runners (six female; Omax 57.5 ± 7.2 mL/kg/min), and 18 kayakers (five female; Omax 45.6 ± 4.8 mL/kg/min). Training sessions were quantified using six training load metrics: two using heart rate, three using power, and one using perceived exertion. Carbohydrate use and EE were determined separately for aerobic (gas exchange) and anaerobic (net lactate accumulation, body mass, and O lactate equivalent method) energy systems and summed. Repeated-measures correlations were used to examine relationships between training load and both CHO utilization and EE. General estimating equations were used to model CHO utilization and EE, using training load alongside measures of fitness and sex. Models were built in the primary study and tested in the validation study. Model performance is reported as the coefficient of determination (R) and mean absolute error, with measures of calibration used for model evaluation and for sport-specific model re-calibration.

RESULTS

Very-large to near-perfect within-subject correlations (r = 0.76-0.96) were evident between all training load metrics and both CHO utilization and EE. In the primary study, all models explained a large amount of variance (R = 0.77-0.96) and displayed good accuracy (mean absolute error; CHO = 16-21 g [10-14%], EE = 53-82 kcal [7-11%]). In the validation study, the mean absolute error ranged from 16-50 g [15-45%] for CHO models to 53-182 kcal [9-31%] for EE models. The calibrated mean absolute error ranged from 9-20 g [8-18%] for CHO models to 36-72 kcal [6-12%] for EE models.

CONCLUSIONS

At the individual level, there are strong linear relationships between all measures of training load and both CHO utilization and EE during cycling. When combined with other measures of fitness, EE and CHO utilization during cycling can be estimated accurately. These models can be applied in running and kayaking when used with a calibration adjustment.

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/dc4b/11985602/5117b026a21f/40279_2024_2131_Fig8_HTML.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/dc4b/11985602/149dd6a2567c/40279_2024_2131_Fig5_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/dc4b/11985602/726f0972dca9/40279_2024_2131_Fig6_HTML.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/dc4b/11985602/5117b026a21f/40279_2024_2131_Fig8_HTML.jpg
摘要

背景

运动营养指南建议碳水化合物(CHO)的摄入量应因人而异,并根据训练负荷的变化进行调整。然而,在训练期间评估CHO利用率的方法有限。

目的

我们旨在(1)量化运动期间CHO与总能量消耗(EE)之间的双变量关系,以及在不同持续时间和强度的训练课程中常用的非侵入性训练负荷测量方法;(2)构建和评估预测模型,以使用相同的训练负荷测量方法和易于量化的个体因素来估计CHO利用率和EE。

方法

本研究分为两个部分:一项初步研究,参与者进行了四次不同的基于实验室的自行车训练课程;一项验证研究,不同的参与者使用三种运动方式(骑自行车、跑步或皮划艇)之一进行了一次基于实验室的训练课程。初步研究包括15名自行车运动员(5名女性;最大摄氧量[ Omax],51.9±7.2 mL/kg/min),验证研究包括21名自行车运动员(7名女性; Omax 53.5±11.0 mL/kg/min)、20名跑步运动员(6名女性; Omax 57.5±7.2 mL/kg/min)和18名皮划艇运动员(5名女性; Omax 45.6±4.8 mL/kg/min)。使用六种训练负荷指标对训练课程进行量化:两种使用心率,三种使用功率,一种使用主观用力程度。分别通过有氧(气体交换)和无氧(净乳酸积累、体重和O乳酸当量法)能量系统测定CHO使用量和EE,并将其相加。采用重复测量相关性分析来检验训练负荷与CHO利用率和EE之间的关系。使用广义估计方程对CHO利用率和EE进行建模,使用训练负荷以及体能和性别的测量指标。在初步研究中建立模型,并在验证研究中进行测试。模型性能以决定系数(R)和平均绝对误差表示,使用校准测量指标进行模型评估和特定运动模型的重新校准。

结果

所有训练负荷指标与CHO利用率和EE之间均存在非常强到近乎完美的受试者内相关性(r = 0.76 - 0.96)。在初步研究中,所有模型解释了大量的方差(R = 0.77 - 0.96),并显示出良好的准确性(平均绝对误差;CHO = 16 - 21 g [10 - 14%],EE = 53 - 82 kcal [7 - 11%])。在验证研究中,CHO模型的平均绝对误差范围为16 - 50 g [15 - 45%],EE模型的平均绝对误差范围为53 - 182 kcal [9 - 31%]。校准后的平均绝对误差范围为CHO模型9 - 20 g [8 - 18%],EE模型36 - 72 kcal [6 - 12%]。

结论

在个体水平上,所有训练负荷测量指标与骑自行车期间的CHO利用率和EE之间均存在很强的线性关系。当与其他体能测量指标结合使用时,可以准确估计骑自行车期间的EE和CHO利用率。这些模型在进行校准调整后可应用于跑步和皮划艇运动。

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1
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BMJ. 2024 Apr 16;385:e078378. doi: 10.1136/bmj-2023-078378.
2
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J Sci Med Sport. 2024 Jun;27(6):430-434. doi: 10.1016/j.jsams.2024.03.005. Epub 2024 Mar 26.
3
Differential utilisation of subcellular skeletal muscle glycogen pools: a comparative analysis between 1 and 15 min of maximal exercise.
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J Physiol. 2024 Apr;602(8):1681-1702. doi: 10.1113/JP285762. Epub 2024 Mar 19.
4
Evaluation of clinical prediction models (part 1): from development to external validation.临床预测模型的评估(第 1 部分):从建立到外部验证。
BMJ. 2024 Jan 8;384:e074819. doi: 10.1136/bmj-2023-074819.
5
A practical guide to selecting and blending approaches for clustered data: Clustered errors, multilevel models, and fixed-effect models.聚类数据选择与融合方法实用指南:聚类误差、多层模型和固定效应模型。
Psychol Methods. 2023 Nov 13. doi: 10.1037/met0000620.
6
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J Appl Physiol (1985). 2023 Dec 1;135(6):1284-1299. doi: 10.1152/japplphysiol.00346.2023. Epub 2023 Oct 12.
7
An Update Of The Allen & Coggan Equation To Predict 60-Min Power Output In Cyclists Of Different Performance Levels.更新艾伦-科根方程以预测不同运动水平自行车运动员的 60 分钟功率输出。
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8
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Sports Med Open. 2023 May 20;9(1):35. doi: 10.1186/s40798-023-00579-3.
9
It is time to abandon single-value oxygen uptake energy equivalents.是时候摒弃单一值的摄氧量能量当量了。
J Appl Physiol (1985). 2023 Apr 1;134(4):887-890. doi: 10.1152/japplphysiol.00353.2022. Epub 2023 Feb 24.
10
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J Sports Sci. 2022 Dec;40(23):2578-2584. doi: 10.1080/02640414.2023.2176045. Epub 2023 Feb 20.