一场公路赛中跑步生物力学与核心体温之间的关系
Relationship Between Running Biomechanics and Core Temperature Across a Competitive Road Race.
作者信息
DeJong Lempke Alexandra F, Szymanski Michael R, Willwerth Sarah B, Brewer Gabrielle J, Whitney Kristin E, Meehan William P, Casa Douglas J
机构信息
Department of Physical Medicine and Rehabilitation, School of Medicine, Virginia Commonwealth University, Richmond, Virginia.
Korey Stringer Institute, University of Connecticut, Storrs, Connecticut.
出版信息
Sports Health. 2025 Mar;17(2):351-358. doi: 10.1177/19417381241236877. Epub 2024 Mar 27.
BACKGROUND
Outdoor races introduce environmental stressors to runners, and core temperature changes may influence runners' movement patterns. This study assessed changes and determined relationships between sensor-derived running biomechanics and core temperature among runners across an 11.27-km road race.
HYPOTHESIS
Core temperatures would increase significantly across the race, related to changes in spatiotemporal biomechanical measures.
STUDY DESIGN
Cross-sectional cohort study.
LEVEL OF EVIDENCE
Level 3.
METHODS
Twenty runners (9 female, 11 male; age, 48 ± 12 years; height, 169.7 ± 9.1 cm; mass, 71.3 ± 13.4 kg) enrolled in the 2022 Falmouth Road Race were recruited. Participants used lightweight technologies (ingestible thermistors and wearable sensors) to monitor core temperature and running biomechanics throughout the race. Timestamps were used to align sensor-derived measures for 7 race segments. Observations were labeled as core temperatures generally within normal limits (<38°C) or at elevated core temperatures (≥38°C). Multivariate repeated measures analyses of variance were used to assess changes in sensor-derived measures across the race, with Bonferroni post hoc comparisons for significant findings. Pearson's correlations were used to assess the relationship between running biomechanics and core temperature measures.
RESULTS
Eighteen participants developed hyperthermic core temperatures (39.0°C ± 0.5°C); core temperatures increased significantly across the race ( < 0.01). Kinetic measures obtained from the accelerometers, including shock, impact, and braking , all significantly increased across the race ( < 0.01); other sensor-derived biomechanical measures did not change significantly. Core temperatures were weakly associated with biomechanics (| range|, 0.02-0.16).
CONCLUSION
Core temperatures and kinetics increased significantly across a race, yet these outcomes were not strongly correlated. The observed kinetic changes may have been attributed to fatigue-related influences over the race.
CLINICAL RELEVANCE
Clinicians may not expect changes in biomechanical movement patterns to signal thermal responses during outdoor running in a singular event.
背景
户外赛跑会给跑步者带来环境压力,核心体温变化可能会影响跑步者的运动模式。本研究评估了在一场11.27公里公路赛中跑步者的核心体温变化,并确定了传感器得出的跑步生物力学与核心体温之间的关系。
假设
随着比赛进行,核心体温会显著升高,这与时空生物力学指标的变化有关。
研究设计
横断面队列研究。
证据水平
3级。
方法
招募了20名参加2022年法尔茅斯路跑比赛的跑步者(9名女性,11名男性;年龄48±12岁;身高169.7±9.1厘米;体重71.3±13.4千克)。参与者使用了轻量化技术(可摄入式热敏电阻和可穿戴传感器)在整个比赛过程中监测核心体温和跑步生物力学。利用时间戳对7个比赛路段的传感器得出的指标进行校准。观察结果被标记为核心体温一般在正常范围内(<38°C)或核心体温升高(≥38°C)。使用多变量重复测量方差分析来评估整个比赛过程中传感器得出的指标变化,对显著结果进行Bonferroni事后比较。使用Pearson相关性分析来评估跑步生物力学与核心体温指标之间的关系。
结果
18名参与者出现了体温过高的核心体温(39.0°C±0.5°C);整个比赛过程中核心体温显著升高(<0.01)。从加速度计获得的动力学指标,包括震动、冲击和制动,在整个比赛过程中均显著增加(<0.01);其他传感器得出的生物力学指标没有显著变化。核心体温与生物力学之间的关联较弱(|范围|,0.02 - 0.16)。
结论
在一场比赛中,核心体温和动力学指标显著升高,但这些结果之间的相关性并不强。观察到的动力学变化可能归因于比赛过程中与疲劳相关的影响。
临床意义
临床医生可能不会预期在单次户外跑步过程中生物力学运动模式的变化会表明热反应。
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