J Sports Sci Med. 2013 Sep 1;12(3):502-11. eCollection 2013.

The effects of aerobic exercise intensity and duration on levels of brain-derived neurotrophic factor in healthy men.

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1: Department of Psychology, Neuroscience Program, Weber State University , Ogden, UT, USA.

Abstract

This study examined the combined effects of aerobic exercise intensity and duration on serum brain-derived neurotrophic factor (sBDNF) levels in healthy human adult males aged 18-25 years. Forty five participants were randomly assigned to one of six exercise conditions based on varying intensity (80% or 60% of heart rate reserve, or control) and duration (20 or 40 min). Vigorous (80% heart rate reserve, "Vig") and moderate (60% heart rate reserve, "Mod") exercise was carried out on cycle ergometers. Control subjects remained seated and at rest during the exercise period. Pre- and post-exercise blood draws were conducted and sBDNF measured. Physical exercise caused an average ~ 32% increase in sBDNF levels relative to baseline that resulted in concentrations that were 45% higher than control conditions. Comparing the six conditions, sBDNF levels rose consistently among the four exercise conditions (Vig20 = 26.38 ± 34.89%, Vig40 = 28.48 ± 19.11%, Mod20 = 41.23 ± 59.65%, Mod40 = 30.16 ± 72.11%) and decreased consistently among the controls (Con20 = -14.48 ± 16.50, Con40 = -10.51 ± 26.78). Vig conditions had the highest proportion of subjects that experienced a significant (? 10%) increase in sBDNF levels, followed by Mod and control conditions. An analysis of modeled sBDNF integrals (area under the curve) demonstrated substantially greater values for Vig40 and Mod40 conditions compared to Vig20 and Mod20 conditions. Collectively, these results demonstrate that neither duration (20 vs. 40 min) nor intensity (60 vs. 80% HR reserve) significantly affects the benefits of exercise if only the sBDNF increase at a single post-exercise time point is considered. However, when comparing either the probability of achieving a significant BDNF gain or the integral (i.e. the volume of circulating BDNF over time) the Vig40 condition offers maximal benefits. Thus, we conclude that the future study of aerobic exercise effects on BDNF-mediated neuroprotection should take the volume of BDNF release over time into account. Key PointsAerobic exercise caused a ~32% increase in serum BDNF in adult human males while serum BDNF decreased 13% in sedentary control subjects.Vigorous intensity (80% heart rate reserve), long duration (40 min) exercise offered the greatest probability of a significant BDNF elevation.Long duration exercise offered the greatest numerical benefits in terms of BDNF integral.Neither intensity nor duration affected the mean elevation in BDNF amplitude caused by exercise.

KEYWORDS:

Aerobic; brain-derived neurotrophic factor (BDNF); exercise; human; neurotrophins

PMID:: 24149158
PMCID:: PMC3772595

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Figure 1.

Baseline sBDNF levels, heart rate during exercise, and change in sBDNF levels due to physical exercise. (A) The cumulative frequency distribution for baseline sBDNF levels for all subjects (n=45). Note that baseline BDNF levels show substantial variability (10.84 ng/ml to 39.01 ng/ml) even in this intentionally homogenous subject sample. (B) To ensure subject compliance to the assigned experimental condition (Vig20, Vig40, Mod20, or Mod40), heart rate (HR) was sampled for each subject during and just after the exercise period.HR data for each subject was transformed to a percentage of the target HR for that subject during exercise and deviation scores (expressed in %) were then calculated.The vast majority of subjects were able to quickly reach, and then maintain, their target HR for the 20 or 40 min period they were assigned. To be included in data analysis, subjects' actual HR could not be more than ± 5% of their calculated target HR for more than three consecutive minutes, with the exception of the first three minutes of exercise. Due to experimenter error, two participants exercised for an additional two minutes. Blood draws were time-locked at 2 minutes post-exercise and, therefore, their heart rate data was frame shifted to the left by two minutes to match exercise cessation and blood draw times within and between regimens. (C) The percent of change in sBDNF levels post-exercise.A 2X2 between factors ANOVA revealed no significant difference between the four exercise conditions when considering either the Intensity or Duration main effect, or the Intensity x Duration interaction.However, the average sBDNF level was greater in three of the conditions compared to baseline and two of the conditions compared to the control condition. (D) Because there was no significant difference between exercise conditions or control conditions, data was collapsed across conditions to allow for an exercise to control comparison of the percent change in sBDNF levels. Exercisers experienced an ~30% increase in sBDNF relative to basal values, which represents a concentration that was nearly 45% greater than controls immediately post-exercise. Panels B, C, and D show mean ± SEM. * indicates significantly different relative to control (p < 0.05); ‡ indicates significant increase relative to baseline (p < 0.05)

The Effects of Aerobic Exercise Intensity and Duration on Levels of Brain-Derived Neurotrophic Factor in Healthy Men

J Sports Sci Med. 2013 Sep;12(3):502-511.

Figure 2.

Probability of substantial sBDNF increase, and integral assumptions and values. (A) The percentage of participants that experienced a significant (≥ 10%) increase in sBDNF levels comparing post-exercise to pre-exercise values. Note that subjects in the Vig40 condition were most likely to show significant BDNF gains.Subjects in the Mod conditions and Vig20 condition had a 60-70% chance of showing a significant gain while the probability of a BDNF elevation in the sedentary control condition was 10%. (B) Graphical representation of sBDNF integral assumptions for a 20 min exercise duration and two models with alternative assumptions. The model can be divided into three distinct phases: the rise phase (which corresponds to beginning of exercise when heart rate is increasing), the peak phase (which corresponds to the portion of exercise when heart rate is maintained at the assigned level), and the falling phase (which corresponds to the post exercise return of heart rate to resting baseline levels). The primary model assumes a rise phase of 5 min, a peak phase of 15 or 35 min, depending on 20 or 40 min exercise assignment, respectively, and a 10 min falling phase. Model 2 assumes a rise phase of 7 min, a peak phase of 13 min or 33 min, depending on exercise assignment, respectively, and a falling phase of 15 min. Model 3 assumes a rise phase of 3 min, a peak phase of 17 or 37 min depending on 20 or 40 min exercise assignment, respectively, and a falling phase of 5 min. (C) As there were no significant differences between Vig20 and Vig40 conditions, between Mod20 and Mod40 conditions, nor control conditions, integral data was collapsed to allow for a comparison between 40 min, 20 min and control conditions. There were no significant differences between the collapsed 40 and 20 min conditions; however, integrals were significantly greater in both exercise conditions than in the control condition. Panel C shows mean ± SEM. * indicates significantly different from control (p < 0.05).

The Effects of Aerobic Exercise Intensity and Duration on Levels of Brain-Derived Neurotrophic Factor in Healthy Men

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The effects of aerobic exercise intensity and duration on levels of brain-derived neurotrophic factor in healthy men.

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