Multiple Short Bouts of Walking Activity Attenuate Glucose Response in Obese Women

in Journal of Physical Activity and Health
Mynor Rodriguez-Hernandez, Jeffrey S. Martin, David D. Pascoe, Michael D. Roberts, and Danielle W. Wadsworth
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DOI:
https://doi.org/10.1123/jpah.2017-0251
Keywords:
sedentary behavior; physical activity; obesity
In Print:
Volume 15: Issue 4
Page Range:
279–286
Restricted access

Background: We sought to determine the effect of multiple walking breaks from sedentary behavior (SED) on glucose responses in sedentary obese women. Materials and Methods: Ten women [aged = 36 (5) y, body mass index = 38.0 (1.6) kg/m2, body fat = 49.6 (1.4)%] completed 3 conditions (48-h “washout” in-between conditions) following a standardized meal in random order: 4-hour SED, 4-hour SED with 2 minutes of moderate-intensity walking every 30 minutes (SED + 2 min), and 4-hour SED with 5 minutes of moderate-intensity walking every 30 minutes (SED + 5 min). Measurements included continuous interstitial glucose concentration monitoring immediately before and during standardized conditions and accelerometry for physical activity patterns during and in-between the standardized conditions. Repeated-measures 1-way analyses of variance (α = .05) with Bonferroni correction for post hoc comparisons were performed. Effect sizes (d [95% confidence interval]) were calculated as mean difference from SED/pooled standard deviation. Results: Sedentary time was similar in the 48 hours preceding each condition (P > .05). By design, sedentary time was different between conditions (P < .001). Compared with SED, 2-hour postprandial glucose positive incremental area under the curve was lower for SED + 5 minutes (P = .005; d = − 0.57 [−1.48, 0.40]), but not for SED + 2 minutes (P = .086; d = − 0.71 [−1.63, 0.27]). Four-hour postprandial glucose area under the curve was similar between conditions (P > .05). Conclusion: In sedentary obese women, 5 minutes of moderate-intensity walking breaks from SED each 30 minutes attenuate 2-hour postprandial glucose excursions.

Rodriguez-Hernandez, Pascoe, Roberts, and Wadsworth are with the School of Kinesiology, Auburn University, Auburn, AL. Martin is with the Dept of Cell Biology and Physiology, Edward Via College of Osteopathic Medicine, Auburn Campus, Auburn, AL.

Rodriguez-Hernandez (mynor.rodriguez@ucr.ac.cr) is corresponding author.

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