Endothelium‐dependent vasodilatation and exercise hyperaemia in ageing humans: impact of acute ascorbic acid administration
Age-related increases in oxidative stress impair endothelium-dependent vasodilatation in humans, leading to the speculation that endothelial dysfunction contributes to impaired muscle blood flow and vascular control during exercise in older adults. We directly tested this hypothesis in 14 young (22 ± 1 years) and 14 healthy older men and women (65 ± 2 years). We measured forearm blood flow (FBF; Doppler ultrasound) and calculated vascular conductance (FVC) responses to single muscle contractions at 10, 20 and 40% maximum voluntary contraction (MVC) before and during ascorbic acid (AA) infusion, and we also determined the effects of AA on muscle blood flow during mild (10% MVC) continuous rhythmic handgrip exercise. For single contractions, the peak rapid hyperaemic responses to all contraction intensities were impaired ∼45% in the older adults (all P < 0.05), and AA infusion did not impact the responses in either age group. For the rhythmic exercise trial, FBF (∼28%) and FVC (∼31%) were lower (P = 0.06 and 0.05) in older versus young adults after 5 min of steady-state exercise with saline. Subsequently, AA was infused via brachial artery catheter for 10 min during continued exercise. AA administration did not significantly influence FBF or FVC in young adults (1-3%; P = 0.24-0.59), whereas FBF increased 34 ± 7% in older adults at end-exercise, and this was due to an increase in FVC (32 ± 7%; both P < 0.05). This increase in FBF and FVC during exercise in older adults was associated with improvements in vasodilator responses to acetylcholine (ACh; endothelium dependent) but not sodium nitroprusside (SNP; endothelium independent). AA had no effect on ACh or SNP responses in the young. We conclude that acute AA administration does not impact the observed age-related impairment in the rapid hyperaemic response to brief muscle contractions in humans; however, it does significantly increase muscle blood flow during continuous dynamic exercise in older adults, and this is probably due (in part) to an improvement in endothelium-dependent vasodilatation.
Recent evidence suggests that adenosine triphosphate (ATP) can inhibit vasoconstrictor responses to endogenous noradrenaline release via tyramine in the skeletal muscle circulation, similar to what is observed in contracting muscle. Whether this involves direct modulation of postjunctional α-adrenoceptor responsiveness, or is selective for α 1 -or α 2 -receptors remains unclear. Therefore, in Protocol 1, we tested the hypothesis that exogenous ATP can blunt direct postjunctional α-adrenergic vasoconstriction in humans. We measured forearm blood flow (FBF; Doppler ultrasound) and calculated the vascular conductance (FVC) responses to local intra-arterial infusions of phenylephrine (α 1 -agonist) and dexmedetomidine (α 2 -agonist) during moderate rhythmic handgrip exercise (15% maximum voluntary contraction), during a control non-exercise vasodilator condition (adenosine), and during ATP infusion in eight young adults. Forearm hyperaemia was matched across all conditions. Forearm vasoconstrictor responses to direct α 1 -receptor stimulation were blunted during exercise versus adenosine ( FVC = −11 ± 3% versus −39 ± 5%; P < 0.05), and were abolished during ATP infusion (−3 ± 2%). Similarly, vasoconstrictor responses to α 2 -receptor stimulation were blunted during exercise versus adenosine (−13 ± 4% versus −40 ± 8%; P < 0.05), and were abolished during ATP infusion (−4 ± 4%). In Prototol 2 (n = 10), we tested the hypothesis that graded increases in ATP would reduce α 1 -mediated vasoconstriction in a dose-dependent manner compared with vasodilatation evoked via adenosine. Forearm vasoconstrictor responses during low dose adenosine (−38 ± 3%) and ATP (−33 ± 2%) were not significantly different from rest (−40 ± 3%; P > 0.05). In contrast, vasoconstrictor responses during moderate (−22 ± 6%) and high dose ATP (−8 ± 5%) were significantly blunted compared with rest, whereas the responses during adenosine became progressively greater (moderate = −48 ± 4%, P = 0.10; high = −53 ± 6%, P < 0.05). We conclude that exogenous ATP is capable of blunting direct postjunctional α-adrenergic vasoconstriction, that this involves both α 1 -and α 2 -receptor subtypes, and that this is graded with ATP concentrations. Collectively, these data are consistent with the conceptual framework regarding how muscle blood flow and vascular tone are regulated in contracting muscles of humans.
We tested the hypothesis that mechanical deformation of forearm blood vessels via acute increases in extravascular pressure elicits rapid vasodilatation in humans. In healthy adults, we measured forearm blood flow (Doppler ultrasound) and calculated forearm vascular conductance (FVC) responses to whole forearm compressions and isometric muscle contractions with the arm above heart level. We used several experimental protocols to gain insight into how mechanical factors contribute to contraction-induced rapid vasodilatation. The findings from the present study clearly indicate that acute increases in extravascular pressure (200 mmHg for 2 s) elicit a significant rapid vasodilatation in the human forearm (peak ΔFVC∼155%). Brief, 6 s sustained compressions evoked the greatest vasodilatation (ΔFVC∼260%), whereas the responses to single (2 s) and repeated compressions (five repeated 2 s compressions) were not significantly different (ΔFVC∼155% versus ∼115%, respectively). This mechanically induced vasodilatation peaks within 1-2 cardiac cycles, and thus is dissociated from the temporal pattern normally observed in response to brief muscle contractions (∼4-7 cardiac cycles). A non-linear relation was found between graded increases in extravascular pressure and both the immediate and peak rapid vasodilatory response, such that the responses increased sharply from 25 to 100 mmHg, with no significant further dilatation until 300 mmHg (maximal ΔFVC∼185%). This was in contrast to the linear intensity-dependent relation observed with muscle contractions. Our collective findings indicate that mechanical influences contribute largely to the immediate vasodilatation (first cardiac cycle) observed in response to a brief, single contraction. However, it is clear that there are additional mechanisms related to muscle activation that continue to cause and sustain vasodilatation for several more cardiac cycles after contraction. Additionally, the potential contribution of mechanical influences to the total contraction-induced hyperaemia appears greatest for low to moderate intensity single muscle contractions, and this contribution becomes less significant for sustained and repeated contractions. Nevertheless, this mechanically induced vasodilatation could serve as a feedforward mechanism to increase muscle blood flow at the onset of exercise, as well as in response to changes in contraction intensity, prior to alterations in local vasodilating substances that influence vascular tone.
Shock is an often lethal syndrome of diminished or insuffi cient perfusion that impairs organ function. Generally associated with decreased arterial blood pressure, shock results most commonly from sepsis, hemorrhage, or primary cardiac failure. 1 Vasopressor medications, largely vasoactive catecholamine hormones, have been used for many decades in the treatment of hypotensive shock. These medications have not been subjected to rigorous, placebo-controlled studies, and consensus from clinical experience suggests that there is not equipoise for such a study in most cases of shock. 2 When vascular tone is profoundly diminished (eg, vasoplegic syndrome or distributive shock), patients may require high-dose vasopressor therapy (HDV).Background: Some patients with hypotensive shock do not respond to usual doses of vasopressor therapy. Very little is known about outcomes after high-dose vasopressor therapy (HDV). We sought to characterize survival among patients with shock requiring HDV. We also evaluated the possible utility of stress-dose corticosteroid therapy in these patients.
Evidence for impaired skeletal muscle contraction-induced rapid vasodilation in aging humans
We tested the hypothesis that aging is associated with an impaired contraction-induced rapid vasodilation in healthy adults. We reasoned that employing single contractions of a small muscle mass would allow us to isolate the local rapid vasodilatory responses independent of systemic hemodynamic and sympathetic neural influences on forearm hemodynamics. We measured forearm blood flow (Doppler ultrasound) and arterial blood pressure (Finapres) on a beat-by-beat basis and calculated the changes in forearm vascular conductance (DeltaFVC) in response to forearm contractions in 18 young (24 +/- 1 yr) and 13 older (62 +/- 2 yr) healthy subjects. Single, 1-s dynamic forearm contractions were performed with the experimental arm slightly above heart level at 5, 10, 20, and 40% of the subjects' maximal voluntary contraction (MVC) in random order. In general, muscle contractions evoked a rapid increase in FVC that reached a peak within approximately four to five cardiac cycles postcontraction in both age groups. At 5% MVC, there were no significant age-related differences in contraction-induced forearm vasodilation. However, the peak vasodilatory responses were impaired approximately 40-45% in older adults at 10, 20, and 40% MVC, as were the total vasodilatory responses (area under curve approximately 40-50%; all P < 0.05). Additionally, the immediate vasodilation (first cardiac cycle postcontraction) for the 20% and 40% MVC trials was also impaired approximately 50% with age (P < 0.05). There were no significant age-group differences in MVC or forearm fat-free mass, and these variables were not correlated with local vasodilation within a given exercise intensity. Under the experimental conditions employed, the blunted responses with age reflect impaired local contraction-induced rapid vasodilation.
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