S mall cerebral arteries and arterioles (eg, pial vessels) respond rapidly to changes in their metabolic milieu and are highly sensitive to the partial pressure of arterial carbon dioxide (PaCO 2 ).1 Vasomotor responsiveness to PaCO 2 , termed CO 2 reactivity, is integral to stabilizing blood pH levels, and previous studies have associated lower CO 2 reactivity to increased cardiovascular and all-cause mortality.2 Recent magnetic resonance imaging studies in humans have revealed that vasomotor changes also occur in the middle cerebral artery (MCA) 3-5 and basilar artery 6 across the hypo-and hypercapnic range. These studies demonstrate the involvement of larger cerebral arteries in the PaCO 2 reactivity response, 7 findings consistent with well-controlled, animal studies. 8 Other recent studies using Duplex ultrasound have investigated extracranial artery responses during hypo-and hypercapnia.9,10 These studies provide direct evidence that changes in end-tidal CO 2 (PETCO 2 ) are associated with directionally similar, and dosedependent, changes in internal carotid artery (ICA) diameter. The mechanism(s), however, mediating these changes in extracranial ICA diameter remain unclear.Significant and rapid changes in extracranial artery blood flow occur across the hypo-and hypercapnic range. [9][10][11] In peripheral conduits such as the radial and brachial arteries, such changes in flow and attendant arterial shear stress represent potent vasoactive stimuli.12,13 Although Pohl et al 14 and Rubanyi et al 15 were the first to identify that flow-mediated dilation (FMD) is endothelium dependent, it is now well established that this phenomenon occurs in humans and that NO plays a significant role. [16][17][18][19] The widely used FMD test 13 relies on dilation of small arteries and arterioles in the limbs, as a consequence of cuff-induced ischemia, to induce an increase in upstream conduit artery shear stress and dilation. In the context of these studies, it is conceivable that rapid and profound dilation of intracranial vessels in response to hypercapnia induces extracranial (ICA) dilation as a consequence of increased shear stress. The aim of this study was to identify whether hypercapnia induces shear-mediated dilation in the carotid arteries. Using high-resolution Duplex ultrasound combined with novel, edge-detection software, we assessed simultaneous common Abstract-Increases in arterial carbon dioxide tension (hypercapnia) elicit potent vasodilation of cerebral arterioles. Recent studies have also reported vasodilation of the internal carotid artery during hypercapnia, but the mechanism(s) mediating this extracranial vasoreactivity are unknown. Hypercapnia increases carotid shear stress, a known stimulus to vasodilation in other conduit arteries. To explore the hypothesis that shear stress contributes to hypercapnic internal carotid dilation in humans, temporal changes in internal and common carotid shear rate and diameter, along with changes in middle cerebral artery velocity, were simultaneously assessed in 18 su...
The aim of this study was to examine the contribution of arterial shear to changes in flow-mediated dilation (FMD) during sympathetic nervous system (SNS) activation in healthy humans. Ten healthy men reported to our laboratory four times. Bilateral FMD, shear rate (SR), and catecholamines were examined before/after 10-min of -35-mmHg lower body negative pressure (LBNP10). On day 1, localized forearm heating (LBNP10+heat) was applied in one limb to abolish the increase in retrograde SR associated with LBNP. Day 2 involved unilateral cuff inflation to 75 mmHg around one limb to exaggerate the LBNP-induced increase retrograde SR (LBNP10+cuff). Tests were repeated on days 3 and 4, using 30-min interventions (i.e., LBNP30+heat and LBNP30+cuff). LBNP10 significantly increased epinephrine levels and retrograde SR and decreased FMD (all P < 0.05). LBNP10+heat prevented the increase in retrograde SR, whereas LBNP10+cuff further increased retrograde SR (P < 0.05). Heating prevented the decrease in percent FMD (FMD%) after LBNP10 (interaction effect, P < 0.05), whereas cuffing did not significantly exaggerate the decrease in FMD% (interaction effect, P > 0.05). Prolongation of the LBNP stimulus for 30-min normalized retrograde SR, catecholamine levels, and FMD (all P > 0.05). Attenuation of retrograde SR during 30 min (LBNP30+heat) was associated with increased FMD% (interaction effects, P < 0.05), whereas increased retrograde SR (LBNP30+cuff) diminished FMD% (interaction effects, P < 0.05). These data suggest that LBNP-induced SNS stimulation decreases FMD, at least in part due to the impact of LBNP on arterial shear stress. Prolonged LBNP stimulation was not associated with changes in SR or FMD%. Our data support a role for changes in SR to the impact of SNS stimulation on FMD.
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