The contribution made by adrenaline to the vasodilatation in the human forearm during emotional stress

The adrenal gland in stress - Adaptation on a cellular level

Human individuals are constantly confronted to various kinds of stressors and the body's response and adaptation is essential for human health. The adrenal gland as the main producer of stress hormones plays a major role in the response to physiological challenges and is able to adapt to these physiological needs. Proper adaptation is of particular importance since dysregulation of the stress system is the cause of various human diseases including obesity, depression, Parkinson's disease, and post-traumatic stress disorder. Therefore, it is fundamental to understand the physiological, cellular, and molecular underpinnings of the stress adaptation in humans. Because of ethical reasons it is problematic to study the plasticity of the human gland in stress. Hence, various experimental models have been established for the analysis of the functional and cellular role of the adrenal gland adaptation on a translational approach. Here, we summarize the insights of stress-induced adrenal plasticity gained from these models and discuss their relevance to clinical observations.

Sympathoneural and adrenomedullary responses to mental stress

This concept-based review provides historical perspectives and updates about sympathetic noradrenergic and sympathetic adrenergic responses to mental stress. The topic of this review has incited perennial debate, because of disagreements over definitions, controversial inferences, and limited availability of relevant measurement tools. The discussion begins appropriately with Cannon's "homeostasis" and his pioneering work in the area. This is followed by mental stress as a scientific idea and the relatively new notions of allostasis and allostatic load. Experimental models of mental stress in rodents and humans are discussed, with particular attention to ethical constraints in humans. Sections follow on sympathoneural responses to mental stress, reactivity of catecholamine systems, clinical pathophysiologic states, and the cardiovascular reactivity hypothesis. Future advancement of the field will require integrative approaches and coordinated efforts between physiologists and psychologists on this interdisciplinary topic.

Regulation of increased blood flow (hyperemia) to muscles during exercise: a hierarchy of competing physiological needs

This review focuses on how blood flow to contracting skeletal muscles is regulated during exercise in humans. The idea is that blood flow to the contracting muscles links oxygen in the atmosphere with the contracting muscles where it is consumed. In this context, we take a top down approach and review the basics of oxygen consumption at rest and during exercise in humans, how these values change with training, and the systemic hemodynamic adaptations that support them. We highlight the very high muscle blood flow responses to exercise discovered in the 1980s. We also discuss the vasodilating factors in the contracting muscles responsible for these very high flows. Finally, the competition between demand for blood flow by contracting muscles and maximum systemic cardiac output is discussed as a potential challenge to blood pressure regulation during heavy large muscle mass or whole body exercise in humans. At this time, no one dominant dilator mechanism accounts for exercise hyperemia. Additionally, complex interactions between the sympathetic nervous system and the microcirculation facilitate high levels of systemic oxygen extraction and permit just enough sympathetic control of blood flow to contracting muscles to regulate blood pressure during large muscle mass exercise in humans.

Catestatin has an unexpected effect on the intrathecal actions of PACAP dramatically reducing blood pressure

This study focuses on presympathetic neurons of the rostral ventrolateral medulla (RVLM) that regulate sympathetic vasomotor tone. Many neurotransmitters are colocalized in RVLM neurons and are released under specific conditions to modulate efferent homeostatic responses. Of particular interest here are two peptides colocalized in catecholaminergic RVLM neurons: catestatin and pituitary adenylate cyclase-activating polypeptide (PACAP). Chromogranin A-derived catestatin is a potent endogenous noncompetitive nicotinic and adrenoreceptor antagonist. Catestatin impairs adenylate cyclase and phospholipase C action: mechanisms engaged by PACAP. Although PACAP and catestatin are likely coreleased, the possible effects of this are unknown. We aimed to determine whether catestatin affects the normal sympathoexcitatory but isotensive responses to intrathecal PACAP. Urethane-anesthetized, vagotomized, ventilated Sprague-Dawley rats (n = 22) were given an intrathecal injection of catestatin at different times prior to intrathecal administration of PACAP-38. Arterial pressure, splanchnic sympathetic nerve activity, heart rate, and reflex responses to baroreceptor and chemoreceptor activation were recorded. The key findings of this study are that pretreatment with catestatin time dependently enhances the PACAP-38 effect on mean arterial pressure and enhances sympathetic barosensitivity and chemosensitivity. The time-scale of the effect of catestatin on the response to PACAP-38 strongly suggests that catestatin is either causing changes in gene expression to exert its effects, or modifying intracellular mechanisms normally engaged by PAC(1) receptors. The ability of catestatin pretreatment to enhance barosensitivity and chemosensitivity after PACAP-38 injection supports the hypothesis that catestatin manipulates the intracellular environment within sympathetic neurons in a way that increases responses to PACAP.

Beta-2 adrenergic receptor polymorphisms and the forearm blood flow response to mental stress

Circulating epinephrine plays an important role in skeletal muscle vasodilation during mental stress. Normotensive adults homozygous for glycine (Gly) of the Arg16/Gly beta2-adrenergic receptor polymorphism have a greater forearm beta2-receptor mediated vasodilation and a higher cardiac output response to isometric handgrip than arginine (Arg) homozygotes. To test the hypothesis that the Arg16/Gly beta2-adrenergic receptor polymorphism affects the forearm blood flow (FBF) and hemodynamic response to mental stress, and whether venous catecholamine concentrations predicted these responses, we measured venous epinephrine, norepinephrine, heart rate (HR), arterial pressure (Finapres), and FBF during mental stress in healthy subjects homozygous for Gly16 (n = 30; mean age +/- SE: 30 +/- 1.2, 13 women) and Arg16 (n = 17, age 30 +/- 1.6, 11 women). Resting HR, blood pressure, and FBF responses to mental stress were similar between genotype groups. There were positive correlations between epinephrine and peak FBF (r = 0.694, P < 0.001), peak forearm vascular conductance (r = 0.677, P < 0.001) and the change in epinephrine to the change in HR (r = 0.456, P = 0.002) in all subjects. These correlations were not significantly different in the Gly16 and Arg16 groups. We conclude that venous epinephrine predicts the FBF response to mental stress, and the increase in epinephrine is also correlated with the increase in HR. Furthermore, the Arg16/Gly beta2-receptor polymorphism has no significant influence on the FBF or cardiovascular responses to mental stress.

Neurogenic vasodilation in human skeletal muscle: possible role in contraction-induced hyperaemia

Whether or not neurally mediated vasodilation contributes to the rise in skeletal muscle blood flow during exercise in humans remains unknown. Such a mechanism might serve as an important 'feed-forward' regulatory signal causing blood flow to rise prior to the development of a metabolic demand. Research in animal species has identified three neurally mediated vasodilating mechanisms with the potential to increase skeletal muscle blood flow during exercise. These include sympathetic vasodilator nerves, the potential for substances released by motor nerves to evoke vasodilation and the possibility of an 'intrinsic' vasodilator nerve system within the walls of blood vessels. In humans, sympathetic vasodilator nerves are present in several vascular beds (e.g. cutaneous). However, more recent information suggests that the human skeletal muscle is not innervated by this class of nerves. Along these lines, the vasodilator response to exercise is unaffected by sympathectomy or by blockade of the traditional transmitters associated with neurally mediated vasodilation. The possibility that spillover of substances released from motor neurones evokes vasodilation is provocative. For example, acetylcholine could produce both skeletal muscle contraction via nicotinic receptors and vasodilation via endothelial muscarinic receptors. However, in many species including humans, atropine has no effect on exercise hyperaemia. While the concept of an 'intrinsic' vasodilator pathway within the walls of the skeletal muscle vascular bed is fascinating, limited information is available on this mechanism in animals and none is available in humans. Taken together, the current information suggests that neurally mediated vasodilating mechanisms may not exist in human skeletal muscle. Additionally, even if such mechanisms exist, they do not play an obligatory role in governing the rise in muscle blood flow during exercise in humans.

Forearm sympathetic withdrawal and vasodilatation during mental stress in humans

1. In humans, mental stress elicits vasodilatation in the muscle vascular beds of the forearm that may be neurally mediated. We sought to determine the extent to which this vasodilatation is due to sympathetic withdrawal, active neurogenic vasodilatation, or beta-adrenergically mediated vasodilatation. 2. We simultaneously measured forearm blood flow and muscle sympathetic nerve traffic to the forearm during mental stress in humans. In a second study, we measured forearm blood flow responses to mental stress after selective blockade of alpha-adrenergic neurotransmission in one forearm. In a final study, we measured forearm blood flow responses to mental stress after unilateral anaesthetic blockade of the stellate ganglion, alone or in combination with selective beta-adrenergic receptor blockade of the forearm. 3. During mental stress, muscle sympathetic nerve activity decreased from 5113 +/- 788 to 1509 +/- 494 total integrated activity min-1 (P < 0.05) and forearm vascular resistance decreased from 96 +/- 29 to 33 +/- 7 mmHg (dl of tissue) min ml-1 (P < 0.05). Considerable vasodilation was still elicited by mental stress after selective blockade of alpha-adrenergic neurotransmission. Vasodilatation also occurred during mental stress after stellate ganglion blockade. This dilatation was reduced by selective blockade of beta-adrenergic receptors in the forearm. 4. Our results support a role for both sympathetic withdrawal and beta-adrenergic vasodilatation as the major causes of the forearm vasodilatation during mental stress in humans.

Neurally mediated syncope and syncope due to autonomic failure: differences and similarities

Syncope is a transient loss of consciousness and postural tone caused by a global reduction of blood flow to the brain. Abnormalities in autonomic cardiovascular control can impair blood supply to the brain and produce syncope in two different disorders: autonomic failure and neurally mediated syncope. In autonomic failure, sympathetic efferent activity is chronically impaired so that vasoconstriction is deficient, upon standing blood pressure always falls (i.e., orthostatic hypotension), and syncope or presyncope occurs. Conversely, in neurally mediated syncope, the failure of sympathetic efferent vasoconstrictor traffic (and hypotension) occurs episodically and in response to a trigger. Between syncopal episodes, patients with neurally mediated syncope have normal blood pressure and orthostatic tolerance. This article reviews the characteristics of autonomic failure and describes in more detail the pathophysiology, diagnosis, and treatment of neurally mediated syncope.

The variance of forearm blood flow as an indicator of emotional stress

Forearm blood flow was measured four times per minute by venous occlusion plethysmography during rest and during a brief emotionally stressful mental task. During emotional stress not only was the mean forearm blood flow increased, but the single blood flow values fluctuated more than at rest. The greater fluctuation, expressed statistically as the variance, was an indicator of emotional stress, at least as sensitive as the mean increase in the blood flow. Both a tranquillizer (thioridazine) and a beta-blocker (toliprolol) reduced the greater variance during the emotionally stressful situation in doses insufficient to diminish the mean increase in forearm blood flow.

Defensive responses to phobic stimuli

Physiological recordings were made while nine females who were afraid of spiders (group P) and nine who were not (group N) viewed a random series of spider and neutral slides. Group P's responses to the spider slides included heart rate (HR) acceleration, cephalic vasoconstriction and an increase in palmer skin conductance (SC), a pattern considered to be part of a defensive response (DR). Group N's responses, on the other hand, were indicative of an orienting response (OR), and included HR deceleration, cephalic vasodilation and an increase in palmar SC. The neutral slides elicited little in the way of responses from group N. However, they elicited the cardiovascular and electrodermal components of an OR from group P, presumably because of their contrast with the feared spider slides. Although the DR pattern observed in group P was often accompanied by increased somatic activity, HR acceleration and cephalic vasoconstriction still occurred even when somatic activity did not appear to increase.

Forearm blood flow and phobic anxiety

The measurement of muscle blood flow using occlusive plethysmography has recently been proposed as an objective index of anxiety (Harper et al., 1965; Kelly, 1966, 1967). Although the method has been used by physiologists for many years, and its sensitivity to psychological stress has often been mentioned as an incidental finding in physiological studies, its application in psychiatric or psychological research has been slow to develop, perhaps because rather cumbersome apparatus is required. However, promising results were reported by Kelly (1966), who differentiated patients suffering from anxiety states from mixed neurotic patients and normal controls, and who showed changes after leucotomy in anxious patients.

Systemic circulatory response to stress of simulated flight and to physical exercise before and after propranolol blockade

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