Question:

A 19-year-old man is brought to the emergency department after sustaining a traumatic brain injury during a motor vehicle collision. On arrival, the patient is comatose and has a Glasgow Coma Scale score of 3. His blood pressure is 110/70 mm Hg, and pulse is 114/min. Pupils are miotic, equal, and reactive to light. Ecchymosis is present behind the ear, but the remainder of the trauma survey is unremarkable. Rapid-sequence intubation is performed, and the patient is mechanically ventilated. A noncontrast head CT scan demonstrates bifrontal contusions and a basilar skull fracture. One day later, a repeat head CT scan reveals diffuse cerebral edema. The ventilator respiratory rate is adjusted to achieve a PaCO₂ level of 26-30 mm Hg. Which of the following is the most likely effect of this intervention?

Decreased brain metabolic demand

Increased cerebral perfusion

Increased cerebral blood volume

Increased cerebral vascular resistance

Increased displacement of cerebrospinal fluid into the thecal sac

Welcome to USMLEPREPS!

Master your USMLE exams with our comprehensive question bank.

Subscribe to our Life Time Plan for unlimited access to Step 1, Step 2, and Step 3 preparation materials.

Don't miss this offer!

Hurry up!

: : Get The Offer

Unlimited Access Step ( one, two and three ).

Priority Access To New Features.

Free Lifetime Updates Facility.

Dedicated Support.

Explanation:

There are many explanatory sources, such as pictures, videos, and audio clips to explain these explanations and questions and explain the answers, but you must subscribe first so that you can enjoy all these advantages. We have many subscription plans at the lowest prices. Don't miss today's offer. Subscribe

Show Explanatory Sources

The brain has little room for expansion as it is encased in the cranium. A small volume change in any of the intracranial components (eg, brain tissue, blood, cerebrospinal fluid [CSF]) can produce significant changes in intracranial pressure (ICP). Therefore, even small increases in cerebral blood volume can raise ICP and cause brain compression.

The main factors influencing cerebral circulation are systemic blood pressure and arterial blood gas levels. When systemic blood pressure is 60-140 mm Hg, it has little effect on cerebral blood volume because autoregulation (via cerebral blood vessel dilation and contraction) keeps blood flow constant. Blood pressure >150 mm Hg increases cerebral vascular volume and blood flow, causing a corresponding increase in ICP. In contrast, blood pressure <50 mm Hg causes cerebral hypoperfusion and potential ischemia.

Arterial blood gases also have a powerful effect on cerebral blood flow, with PaCO₂ being the most important regulator. A drop in PaCO₂ due to hyperventilation causes vasoconstriction. The resulting reduction in cerebral blood volume (Choice C) leads to decreased ICP. Lowering PaCO₂ is one of the measures employed to reduce ICP in mechanically ventilated patients with cerebral edema.

(Choice A) The brain has a very large oxygen requirement, about 20% of all O₂ consumed by the body. Induced sedation and therapeutic hypothermia can decrease brain metabolic demand, exerting a neuroprotective effect and improving ICP by reducing cerebral blood volume.

(Choice B) The vasoconstriction induced by hyperventilation can cause a decrease in local cerebral perfusion that can worsen neurologic injury in patients with acute traumatic brain injury or stroke. Therefore, hyperventilation should be used with caution in these patients, and the PaCO₂ should be maintained >30 mm Hg.

(Choice E) The thecal sac is a sheath of dura mater that contains CSF and surrounds the spinal cord. Increased ICP can cause displacement of CSF from the brain into the thecal sac. However, the drop in ICP caused by hyperventilation reduces CSF displacement.

Educational objective:
Carbon dioxide is a potent vasodilator of cerebral vasculature. Tachypnea causes hypocapnia and cerebral vasoconstriction, thereby decreasing cerebral blood volume and intracranial pressure.