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This graph depicts a vascular bed in which arterial/arteriolar resistance increases as the tissue O₂ content decreases.  This response is unique to the pulmonary vasculature, in which hypoxic vasoconstriction occurs to divert blood flow away from underventilated lung regions and toward well-ventilated lung areas.  This phenomenon improves ventilation-perfusion mismatch by decreasing physiologic shunting in poorly ventilated alveoli, leading to overall more efficient gas exchange.  The relationship between hypoxia and vascular resistance is reversed throughout the rest of the body, ensuring that hypoxic organs and tissues receive increased blood flow.

(Choice A)  Although the cerebral circulation is more sensitive to blood CO₂ levels (small degrees of hypercapnia lead to vasodilation), hypoxia causes significant arteriolar dilation when the partial pressure of oxygen (PO₂) falls below 50 mm Hg.

(Choice B)  In the coronary vasculature, subendocardial blood flow is mediated by the local tissue PO₂, adenosine, prostacyclin, and nitric oxide.  Decreased tissue PO₂ promotes vasodilation of arterioles in the myocardium.

(Choice C)  A large increase in sympathetic tone may cause vasoconstriction of the renal vasculature, but hypoxia does not have this effect.

(Choice E)  Parasympathetic-induced intestinal vasodilation occurs in response to digestive chyme passing over intestinal mucosa.  Sympathetic tone (not hypoxia) plays a large role in the splanchnic vasoconstriction that occurs with exercise or significant hypovolemia.

Educational objective:
The pulmonary vascular bed is unique in that tissue hypoxia results in a vasoconstrictive response.  Such hypoxic vasoconstriction occurs in the small muscular pulmonary arteries to divert blood flow away from underventilated lung regions and toward well-ventilated lung areas to minimize ventilation-perfusion mismatch, leading to more efficient overall gas exchange.