Baroreceptor

Phenylephrine. Phenylephrine hydrochloride is an a -adrenoceptor agonist. Phenylephrine produces powerful vasoconstrictor and hypertensive responses. This results in baroreceptor activation of a reflex bradycardia and thus is useful in the treatment of supraventricular tachyarrhythmias. Unlike epinephrine [51-43-4] the actions of which are relatively transient, phenylephrine responses are more sustained (20 min after iv dosing and 50 min after subcutaneous dosing) (86). 

Logically, ADH receptor antagonists, and ADH synthesis and release inhibitors can be effective aquaretics. ADH, 8-arginine vasopressin [113-79-17, is synthesized in the hypothalamus of the brain, and is transported through the supraopticohypophyseal tract to the posterior pituitary where it is stored. Upon sensing an increase of plasma osmolaUty by brain osmoreceptors or a decrease of blood volume or blood pressure detected by the baroreceptors and volume receptors, ADH is released into the blood circulation it activates vasopressin receptors in blood vessels to raise blood pressure, and vasopressin V2 receptors of the nephrons of the kidney to retain water and electrolytes to expand the blood volume. 

That is, the pressure is adjusted automatically in response to signals from various baroreceptors. Control of abnormally high pressure can, at least in theory, be achieved by interfering with the chain of transmission of the neural signals that lead to elevation of pressure. Initial success in control of hypertension was met with the ganglionic blocking agents which in effect in-... 

Baroreceptor. Specialized pressure-sensitive tissue located in carotid arteries. Nerve impulses proportional to arterial blood pressure are conducted from this tissue to the brain which in turn exerts control over the blood pressure. 

The baroreceptor reflex is a central reflex mechanism, which reduces heart rate following an increase in blood pressure. Each change in blood pressure is sensed by baroreceptors in the carotid arteries, which activate the autonomic nervous system to alter heart rate and thereby readjust blood pressure. 

The regulation of the total peripheral resistance also involves the complex interactions of several mechanisms. These include baroreflexes and sympathetic nervous system activity response to neurohumoral substances and endothelial factors myogenic adjustments at the cellular level, some mediated by ion channels and events at the cellular membrane and intercellular events mediated by receptors and mechanisms for signal transduction. As examples of some of these mechanisms, there are two major neural reflex arcs (Fig. 1). Baroreflexes are derived from high-pressure barorecep-tors in the aortic arch and carotid sinus and low-pressure cardiopulmonary baroreceptors in ventricles and atria. These receptors respond to stretch (high pressure) or... 

Vasopressin (antidiuretic hormone [ADH]) secretion increases in response to decreased blood volume and/or reductions in effective blood volume via a decrease in inhibitory tone from both low-pressure and high-pressure baroreceptors to the hypothalamus. The neuronal pathways that mediate hemodynamic regulation of... 

Back Propagation Bacterial Toxins Bacteriophage Barbiturates Baroreceptor Reflex (3 Barrel... 

Cardiovascular-peripheral vasodilation,decreased peripheral resistance, inhibition of baroreceptors (pressure receptors located in the aortic arch and carotid sinus that regulate blood pressure), orthostatic hypotension and fainting... 

Overactivation of the sympathetic nervous system (SNS) may also play a role in the development and maintenance of primary hypertension for some individuals. Among other effects, direct activation of the SNS may lead to enhanced sodium retention, insulin resistance, and baroreceptor dysfunction.9 Regardless of which mechanism(s) underlie the role the SNS may play in the development of primary hypertension, the SNS remains a target of many antihypertensive agents. 

Many different types of sensory receptors are located throughout the body. These receptors monitor the status of the internal environment or that of the surroundings. Sensory receptors are sensitive to specific types of stimuli and measure the value of a physiological variable. For example, arterial baroreceptors measure blood pressure and chemoreceptors measure the oxygen and carbon dioxide content of the blood. The information detected by these sensors then travels by way of afferent neuronal pathways to the central nervous system (CNS). The CNS is the integrative portion of the nervous system and consists of the (1) brain and the (2) spinal cord. 

An example of this type of reflex is the baroreceptor reflex (see Figure 1.2). Baroreceptors located in some of the major systemic arteries are sensory receptors that monitor blood pressure. If blood pressure decreases, the number of sensory impulses sent from the baroreceptors to the cardiovascular control center in the brainstem also decreases. As a result of this change in baroreceptor stimulation and sensory input to the brainstem, ANS discharge to the heart and blood vessels is adjusted to increase heart rate and vascular resistance so that blood pressure increases to its normal value. 

Describe the mechanism of action and physiological significance of the baroreceptor reflex, chemoreceptor reflex, and low-pressure reflex... 

Figure 15.4 Effects of the autonomic nervous system on mean arterial pressure. The baroreceptors, chemoreceptors, and low-pressure receptors provide neural input to the vasomotor center in the brainstem. The vasomotor center integrates this input and determines the degree of discharge by the sympathetic and parasympathetic nervous systems to the cardiovascular system. Cardiac output and total peripheral resistance are adjusted so as to maintain mean arterial pressure within the normal range.

Because baroreceptors respond to stretch or distension of the blood vessel walls, they are also referred to as stretch receptors. A change in blood pressure will elicit the baroreceptor reflex, which involves negative feedback responses that return blood pressure to normal (see Figure 15.6). For example, an increase in blood pressure causes distension of the aorta and carotid arteries, thus stimulating the baroreceptors. As a result, the number of afferent nerve impulses transmitted to the vasomotor center increases. The vasomotor center processes this information and adjusts the activity of the autonomic nervous system accordingly. Sympathetic stimulation of vascular smooth muscle and the heart is decreased and parasympathetic stimulation of the heart is increased. As a result, venous return, CO, and TPR decrease so that MAP is decreased back toward its normal value. 

It is important to note that the baroreceptor reflex is elicited whether blood pressure increases or decreases. Furthermore, these receptors are... 

Figure 15.6 The baroreceptor reflex. Baroreceptors are the most important source of input to the vasomotor center. The reflex elicited by these receptors is essential in maintenance of normal blood pressure.

Low-pressure receptors. The low-pressure receptors are located in the walls of the atria and the pulmonary arteries. Similar to baroreceptors, low-pressure receptors are also stretch receptors however, stimulation of these receptors is caused by changes in blood volume in these low-pressure areas. An overall increase in blood volume results in an increase in venous return an increase in the blood volume in the atria and the pulmonary arteries and stimulation of the low-pressure receptors. These receptors then elicit reflexes by way of the vasomotor center that parallel those of baroreceptors. Because an increase in blood volume will initially increase MAP, sympathetic discharge decreases and parasympathetic discharge increases so that MAP decreases toward its normal value. The simultaneous activity of baroreceptors and low-pressure receptors makes the total reflex system more effective in the control of MAP. 

Baroreceptors are sensitive to changes in MAP. As VR, CO, and MAP decrease, baroreceptor excitation is diminished. Consequently, the frequency of nerve impulses transmitted from these receptors to the vasomotor center in the brainstem is reduced. This elicits a reflex that will increase HR, increase contractility of the heart, and cause vasoconstriction of arterioles and veins. The increase in CO and TPR effectively increases MAP and therefore cerebral blood flow. Constriction of the veins assists in forcing blood toward the heart and enhances venous return. Skeletal muscle activity associated with simply walking decreases venous pressure in the lower extremities significantly. Contraction of the skeletal muscles in the legs compresses the veins and blood is forced toward the heart. 

Loss of plasma volume leads to a decrease in MAP. Baroreceptors located in the aortic and carotid sinuses detect this fall in MAP and elicit reflex responses that include an increase in the overall activity of the sympathetic nervous system. Sympathetic stimulation of the heart and blood vessels leads to an increase in cardiac output (CO) and increased total peripheral resistance (TPR). These adjustments, which increase MAP, are responsible for the short-term regulation of blood pressure. Although increases in CO and TPR are effective in temporary maintenance of MAP and blood flow to the vital organs, these activities cannot persist indefinitely. Ultimately, plasma volume must be returned to normal (see Table 19.1). 

The granular cells that secrete renin also serve as intrarenal baroreceptors, monitoring blood volume and blood pressure in the afferent arterioles. Arteriolar pressure and renin secretion have an inverse relationship in other words, an increase in blood volume causes an increase in arteriolar blood pressure increased stimulation of the intrarenal baroreceptors and decreased secretion of renin. With less angiotensin Il-induced vasoconstriction of the afferent arteriole, RBF, GFR, and urine output will increase so that blood volume returns to normal. 

A decrease in plasma volume leads to decreased MAP, which is detected by baroreceptors in the carotid sinuses and the arch of the aorta. By way of the vasomotor center, the baroreceptor reflex results in an overall increase in sympathetic nervous activity. This includes stimulation of the heart and vascular smooth muscle, which causes an increase in cardiac output and total peripheral resistance. These changes are responsible for the short-term regulation of blood pressure, which temporarily increases MAP toward normal. 

A more moderate stimulus for thirst and ADH secretion is a decrease in extracellular fluid, or plasma volume. This stimulus involves low-pressure receptors in the atria of the heart as well as baroreceptors in the large arteries. A decrease in plasma volume leads to a decrease in atrial filling, which is detected by low-pressure receptors, and a decrease in MAP, which the baroreceptors detect. Each of these receptors then provides excitatory inputs to the thirst center and to the ADH-secreting cells. 

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