Brachial artery flow-mediated dilation during handgrip exercise: evidence for endothelial transduction of the mean shear stimulus

Abstract

Exercise elevates shear stress in the supplying conduit artery. Although this is the most relevant physiological stimulus for flow-mediated dilation (FMD), the fluctuating pattern of shear that occurs may influence the shear stress-FMD stimulus response relationship. This study tested the hypothesis that the brachial artery FMD response to a step increase in shear is influenced by the fluctuating characteristics of the stimulus, as evoked by forearm exercise. In 16 healthy subjects, we examined FMD responses to step increases in shear rate in three conditions: stable shear upstream of heat-induced forearm vasodilation (FH_Stable); fluctuating shear upstream of heat-induced forearm vasodilation and rhythmic forearm cuff inflation/deflation (FH_Fluctuating); and fluctuating shear upstream of exercise-induced forearm vasodilation (FE_{Step Increase}). The mean increase in shear rate (±SD) was the same in all trials (FH_Fluctuating: 51.69 ± 15.70 s⁻¹; FH_Stable: 52.16 ± 14.10 s⁻¹; FE_{Step Increase}: 50.14 ± 13.03 s⁻¹ P = 0.131). However, the FH_Fluctuating and FE_{Step Increase} trials resulted in a fluctuating shear stress stimulus with rhythmic high and low shear periods that were 96.18 ± 24.54 and 11.80 ± 7.30 s⁻¹, respectively. The initial phase of FMD (phase I) was followed by a second, delayed-onset FMD and was not different between conditions (phase I: FH_Fluctuating: 5.63 ± 2.15%; FH_Stable: 5.33 ± 1.85%; FE_{Step Increase}: 5.30 ± 2.03%; end-trial: FH_Fluctuating: 7.76 ± 3.40%; FH_Stable: 7.00 ± 3.03%; FE_{Step Increase}: 6.68 ± 3.04%; P = 0.196). Phase I speed also did not differ ( P = 0.685). In conclusion, the endothelium transduced the mean shear when exposed to shear fluctuations created by a typical handgrip protocol. Muscle activation did not alter the FMD response. Forearm exercise may provide a viable technique to investigate brachial artery FMD in humans.