Acute Exercise-Associated Skin Surface Temperature Changes after Resistance Training with Different Exercise Intensities

Weigert, Martin; Nitzsche, Nico; Kunert, Felix; Lösch, Christiane; Baumgärtel, Lutz; Schulz, Henry

doi:10.7575/aiac.ijkss.v.6n.1p.12

Cited by 19 publications

(18 citation statements)

References 28 publications

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“…So, this combination of exercises seems to have been responsible for the increase in temperature found in the aforementioned ROI. Our data is aligned with that in previous studies [37][38][39][40] , however, it is in disagreement with others 41,42 .…”

Section: Discussionsupporting

confidence: 77%

Superficial thermal response to CrossFit® workout

Neves¹,

Martinez

Meneck

et al. 2020

Motriz: rev. educ. fis.

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Section: Discussionsupporting

confidence: 77%

Superficial thermal response to CrossFit® workout

Neves¹,

Martinez

Meneck

et al. 2020

Motriz: rev. educ. fis.

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“…A sample size calculation was initially performed with G*Power software (Heinrich-Heine-Universität, Düsseldorf, Germany). The effect size of exercise on skin temperature changes reported in the literature is large [ 23 , 24 ], considering an effect size of 0.4, a statistical power of 0.80, and three repeated measurements for the repeated measures ANOVA assessing the effects of resistance training on skin temperature, a minimum sample size of 12 was calculated. To account for any dropouts and other unforeseen shortcomings, 20 healthy and trained male volunteers aged 25.39 ± 8.21 years (height: 178.88 ± 8.37 cm; weight: 82.38 ± 6.80 kg; BMI: 25.76 ± 1.45) were recruited.…”

Section: Methodsmentioning

confidence: 99%

“…Considering that the acute effects of the exercise on skin thermal response are different even after a short recovery time [ 23 ], a last set of thermograms, RPE scores (5.26 ± 1.81) and Omegawave ® were taken 20 min after completion of strength training. During this resting time, the subject remained seated on their gluteus, avoiding any contact of the posterior thigh with the chair to prevent any interference with the Tsk assessment.…”

Section: Methodsmentioning

confidence: 99%

Effects of Resistance Training on Skin Temperature and Its Relationship with Central Nervous System (CNS) Activation

et al. 2022

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The aim of this work was to relate the activation of the sympathetic and parasympathetic nervous systems with the skin temperature (Tsk) of the lower limbs after a resistance training exercise. Under controlled conditions, the average Tsk in the areas of the anterior and posterior thighs, knees and legs was obtained with a thermal imager and the parasympathetic and sympathetic activation was registered with an Omegawave® device on 20 healthy and trained male volunteers (25.39 ± 8.21 years) before exercise, immediately after standard resistance training (3 exercises (2 quadriceps + 1 hamstrings) × 4 sets × 10 repetitions (70% 1RM), 90-sec recovery) and after 20 min of recovery. The results showed a significant effect of exercise and recovery on Tsk in all regions of interest (ROIs) considered (p < 0.05) and strong inverse relationships between sympathetic and parasympathetic activation values. Significant results were found for the total variation of Tsk (p < 0.05) with highly positive values for subjects with lower sympathetic activation and almost null or even negative values for those with higher sympathetic activation. Sympathetic activity was a significant predictor of total Tsk variation in the anterior thigh, posterior thigh and anterior knee but not in the posterior knee, anterior leg, and posterior leg. Baseline Tsk was a significant predictor of total Tsk variation the all ROIs except in the posterior knee. Tsk measured by thermography could be used to estimate the level of participation of muscle areas in exercise and registering the level of sympathetic activation before exercise could be interesting in predicting the athlete’s physiological response to strength training.

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“…This thermographic pattern reflects the redistribution of the blood flow to muscles during exercise and back to the skin after it to promote heat dissipation (Zaïdi et al, 2007;Balci et al, 2016;Drzazga et al, 2018;Hillen et al, 2020). In contrast, resistance exercise produces an increased skin temperature pattern related to the stressed muscles which is more pronounced in trained athletes, compared to untrained individuals, and in younger people compared to older individuals (Weigert et al, 2018;dos Santos Bunn et al, 2020). These findings can be linked to local and systemic adaptations of myocutaneous blood flow and reflect the muscles' metabolism while under stress, as they have also been seen in individuals experiencing ergonomic injuries (Alexandre et al, 2017).…”

Section: Sports Medicinementioning

confidence: 99%

Infrared Thermography in Wound Care, Surgery, and Sports Medicine: A Review

Ramírez-GarcíaLuna

Bartlett²,

Arriaga-Caballero³

et al. 2022

Front. Physiol.

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For many years, the role of thermometry was limited to systemic (core body temperature) measurements (e.g., pulmonary catheter) or its approximation using skin/mucosa (e.g., axillary, oral, or rectal) temperature measurements. With recent advances in material science and technology, thermal measurements went beyond core body temperature measurements and found their way in many medical specialties. The article consists of two primary parts. In the first part we overviewed current clinical thermal measurement technologies across two dimensions: (a) direct vs. indirect and (b) single-point vs. multiple-point temperature measurements. In the second part, we focus primarily on clinical applications in wound care, surgery, and sports medicine. The primary focus here is the thermographic imaging modality. However, other thermal modalities are included where relevant for these clinical applications. The literature review identified two primary use scenarios for thermographic imaging: inflammation-based and perfusion-based. These scenarios rely on local (topical) temperature measurements, which are different from systemic (core body temperature) measurements. Quantifying these types of diseases benefits from thermographic imaging of an area in contrast to single-point measurements. The wide adoption of the technology would be accelerated by larger studies supporting the clinical utility of thermography.

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Acute Exercise-Associated Skin Surface Temperature Changes after Resistance Training with Different Exercise Intensities

Cited by 19 publications

References 28 publications

Superficial thermal response to CrossFit® workout

Superficial thermal response to CrossFit® workout

Effects of Resistance Training on Skin Temperature and Its Relationship with Central Nervous System (CNS) Activation

Infrared Thermography in Wound Care, Surgery, and Sports Medicine: A Review

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