Many hormones help to regulate blood pressure, including adrenaline and noradrenaline, which are released from the adrenal medulla in response to a drop in blood pressure; these hormones increase cardiac contractility and vasoconstriction, and thus increase cardiac output (Patton [155]). Atrial natriuretic peptide is a hormone that is produced from the atria of the heart in response to hypertension. It works by inhibiting the renin–angiotensin system, raising the glomerular filtration rate by causing vasodilation in the afferent arteriole, inhibiting sodium reabsorption and causing fluid transfer into the interstitial space (Waugh and Grant [207]) in an attempt to lower blood pressure.

When blood pressure increases, the baroreceptors, or stretch receptors, are stimulated and in turn stimulate the cardiac inhibitory centre, reducing sympathetic nerve impulses and increasing parasympathetic nerve impulses (Marieb and Keller [111]). This causes vasodilation and a decrease in cardiac output, thereby reducing blood pressure (Blows [21]). When blood pressure is low, the opposite occurs. This response is termed a ‘reflex arc’, and it continually maintains homeostasis (Marieb and Hoehn [110]). Baroreceptors are located in the aortic arch, the carotid sinuses and the walls of most of the large arteries in the thorax and neck (Marieb and Hoehn [110]). Close to these are chemoreceptors, which are stimulated when the pH of the blood drops or when carbon dioxide rises, and when oxygen levels drop significantly; this causes an increase in cardiac output and vasoconstriction, leading to an increase in blood pressure (Marieb and Hoehn [110]).

The juxtaglomerular cells within the kidneys are stimulated to release renin when blood volume or pressure falls (Tortora and Derrickson [199]). This leads to the production of angiotensin I, which is converted to angiotensin II (with the aid of angiotensin‐converting enzyme) (Patton [155]). Angiotensin II has a potent effect on blood pressure, increasing cardiac output and vasoconstriction and stimulating the production of aldosterone. Aldosterone increases reabsorption of water and sodium and stimulates the thirst receptors (Patton [155]) in an attempt to increase the circulatory volume of fluid and thereby blood pressure (Blows [21]). These mechanisms are known collectively as the renin–angiotensin–aldosterone system (Figure 14.22). Anti‐diuretic hormone is produced in the hypothalamus in response to low blood pressure or volume and increases vasoconstriction and water reabsorption in the kidneys. These mechanisms are inhibited when fluid volume in the circulatory system is high (Marieb and Keller [111]).

Skeletal muscle contractions and the mechanism of respiration promote venous return of blood to the heart and therefore assist in maintaining cardiac output (Lin [104]). Skeletal muscles contract on movement, compressing the veins and pushing the blood towards the heart, and respiration causes a change in thoracic and abdominal pressure, which acts to pump venous blood (Patton [155]). Starling's law states that the force of the contraction of the heart is directly related to how much blood volume is in the heart (Patton [155]). The more stretched the muscle fibres are prior to contraction, the stronger the contraction and the greater volume the heart will pump (Marieb and Keller [111]).