Baroreceptor
Baroreceptor
Anti-establishment
<catset>Category="Sensory receptors"</catset><b>Baroreceptors</b> (or <b>baroceptors</b>) in the <a href="Human anatomy">human body</a> detect the pressure of blood flowing though them, and can send messages to the <a href="Central nervous system">Central nervous system</a> to increase or decrease <a href="Total peripheral resistance">Total peripheral resistance</a> and <a href="Cardiac output">Cardiac output</a>.<p>Baroreceptors can be divided into two categories, high pressure arterial baroreceptors and low pressure baroreceptors (also known as cardiopulmonary receptors).<h2 style="margin: 0; padding-top: 0.5em; padding-bottom: 0.17em; border-bottom: 1px solid #aaaaaa; font-size: 150%;">Arterial Baroreceptors</h2>There are baroreceptors present in the arch of the <a href="Aorta">Aorta</a>, and the carotid sinuses of the left and right internal <a href="Carotid artery">carotid arteries</a>. In some sensitive patients, due to baroreceptors, vigorous <a href="Palpation">Palpation</a> of a carotid artery can cause severe <a href="Bradycardia">Bradycardia</a> or even heart arrest.<p>Baroreceptors act to maintain mean arterial blood pressure to allow tissues to receive the right amount of blood.<p><i>See main article <a href="Baroreflex">Baroreflex</a></i><p>If blood pressure falls, such as in <a href="Shock">Shock</a>, baroreceptor firing rate decreases. Signals from the carotid baroreceptors are sent via the <a href="Glossopharyngeal nerve">Glossopharyngeal nerve</a> (<a href="Cranial nerves">cranial nerve</a> IX). Signals from the aortic baroreceptors travel through the <a href="Vagus nerve">Vagus nerve</a> (<a href="Cranial nerves">cranial nerve</a> X). Baroreceptors work by detecting the amount of stretch. The more the baroreceptor walls are stretched, the more frequently they generate <a href="Action potential">action potentials</a>. The arterial baroreceptors have a lower threshold of around 70 <a href="Torr">mmHg</a> (typical arterial <a href="Blood pressure">Blood pressure</a> is around 80-90 mmHg). Below this the receptors stop firing signals completely, any further decrease in pressure will cause no additional effect. At this low pressure however the response of <a href="Chemosensor">chemoreceptors</a> becomes more vigorous, especially below 60 mmHg.<p>Baroreceptors respond very quickly to maintain a stable blood pressure, but they only respond to short term changes. Over a period of days or weeks they will reset to a new value. Thus, in people with <a href="Hypertension">essential hypertension</a> the baroreceptors behave as if the elevated blood pressure is normal and aim to maintain this high blood pressure.<h2 style="margin: 0; padding-top: 0.5em; padding-bottom: 0.17em; border-bottom: 1px solid #aaaaaa; font-size: 150%;">Low pressure Baroreceptors</h2>These are found in the large <a href="Vein">veins</a> and in the walls of the atria of the <a href="Heart (L'Arc-en-Ciel album)">heart</a>. The low pressure baroreceptors are involved with the regulation of blood volume. The blood volume determines the mean pressure throughout the system, in particular in the venous side where most of the blood is held.<p>The low pressure baroreceptors have both circulatory and renal effects, they produce changes in <a href="Hormone">Hormone</a> secretion which have profound effects on the retention of <a href="Osmoregulation">salt and water</a> and also influence intake of salt and water. The renal effects allow the receptors to change the mean pressure in the system in the long term.<p>Denervating these receptors fools the body into thinking that we have too low blood volume and initiates mechanisms which retain fluid and so push up the blood pressure to a higher level than we would otherwise have.