If I hang upside down, and feel blood rushing to my head, what structures are actually responsible for me "feeling" this excess flow of blood? Baroreceptors? Mechanoreceptors? Something else?

Regardless, how does this process actually work? How do I "feel" excess blood pressure to a certain area of my body?

  • $\begingroup$ Thanks @WYSIWYG (+1) I appreciate the help but must request that you remove the "possible dupe" label on this question. If you really read both questions, I am actually asking 2 different things. Here I am asking for root causes of the feeling of pressure to any area of the body. The other question is specifically about ears and what types of structures cause the sensation of pressure. I argue these are 2 separate questions. Thanks again! $\endgroup$
    – smeeb
    Feb 18, 2015 at 10:42
  • $\begingroup$ Ok removed my vote. $\endgroup$
    Feb 18, 2015 at 13:27

1 Answer 1


Arterial Baroreceptors felling the pressure.

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Arterial blood pressure is normally regulated within a narrow range, with a mean arterial pressure typically ranging from 85 to 100 mmHg in adults. It is important to tightly control this pressure to ensure adequate blood flow to organs throughout the body. This is accomplished by negative feedback systems incorporating pressure sensors (i.e., baroreceptors) that sense the arterial pressure. The most important arterial baroreceptors are located in the carotid sinus (at the bifurcation of external and internal carotids) and in the aortic arch (Figure 1). These receptors respond to stretching of the arterial wall so that if arterial pressure suddenly rises, the walls of these vessels passively expand, which increases the firing frequency of receptor action potentials. If arterial blood pressure suddenly falls, decreased stretch of the arterial walls leads to a decrease in receptor firing.

The carotid sinus baroreceptors are innervated by the sinus nerve of Hering, which is a branch of the glossopharyngeal nerve (IX cranial nerve). The glossopharyngeal nerve synapses in the nucleus tractus solitarius (NTS) located in the medulla of the brainstem. The aortic arch baroreceptors are innervated by the aortic nerve, which then combines with the vagus nerve (X cranial nerve) traveling to the NTS. The NTS modulates the activity of sympathetic and parasympathetic (vagal) neurons in the medulla, which in turn regulate the autonomic control of the heart and blood vessels.

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Of these two sites for arterial baroreceptors, the carotid sinus is quantitatively the most important for regulating arterial pressure. The carotid sinus receptors respond to pressures ranging from 60-180 mmHg (Figure 2). Receptors within the aortic arch have a higher threshold pressure and are less sensitive than the carotid sinus receptors. Maximal carotid sinus sensitivity occurs near the normal mean arterial pressure; therefore, very small changes in arterial pressure around this "set point" dramatically alters receptor firing so that autonomic control can be reset in such a way that the arterial pressure remains very near to the set point. This set point changes during exercise, hypertension, and heart failure. The changing set point (response curve shifts to right) explains how arterial pressure can remain elevated during chronic hypertension.

Baroreceptors are sensitive to the rate of pressure change as well as to the steady or mean pressure. Therefore, at a given mean arterial pressure, decreasing the pulse pressure (systolic minus diastolic pressure) decreases the baroreceptor firing rate. This is important during conditions such as hemorrhagic shock in which pulse pressure as well as mean pressure decreases. The combination of reduced mean pressure and reduced pulse pressure amplifies the baroreceptor response.

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Although the baroreceptors can respond to either an increase or decrease in systemic arterial pressure, their most important role is responding to sudden reductions in arterial pressure (Figure 3). This can occur, for example, when a person suddenly stands up or following blood loss (hemorrhage). A decrease in arterial pressure (mean, pulse or both) results in decreased baroreceptor firing. Autonomic neurons within the medulla respond by increasing sympathetic outflow and decreasing parasympathetic (vagal) outflow. Under normal physiological conditions, baroreceptor firing exerts a tonic inhibitory influence on sympathetic outflow from the medulla. Therefore, acute hypotension results in a disinhibition of sympathetic activity within the medulla, so that sympathetic activity originating within the rostral ventrolateral medulla increases. These autonomic changes cause vasoconstriction (increased systemic vascular resistance, SVR), tachycardia and positive inotropy. The latter two changes increase cardiac output. Increases in cardiac output and SVR lead to a partial restoration of arterial pressure.

It is important to note that baroreceptors adapt to sustained changes in arterial pressure. For example, if arterial pressure suddenly falls when a person stands, the baroreceptor firing rate will decrease; however, after a period of time, the firing returns to near normal levels as the receptors adapt to the lower pressure. Therefore, the long-term regulation of arterial pressure requires activation of other mechanisms (primarily hormonal and renal) to maintain normal blood pressure.

This information from PhD Richard E. Klabunde lecture, that based on his book Cardiovascular Physiology Concepts (chapter 5, pages 93-123)

  • $\begingroup$ +1 for a good detailed answer, but I was just wondering, shouldn't venous baroreceptors also play a part in this, since the veins are more likely to change their internal pressure due to gravity (as compared to arteries?) $\endgroup$
    – March Ho
    Feb 20, 2015 at 22:59

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