Which factor contributes to the PCO2 electrode requiring 60–120 seconds to reach equilibrium?

Unlock all questions

This demo includes only 20 questions. Upgrade to access hundreds of questions, flashcards, exam simulations, and disable ads.

Full question bankExam simulationsFlashcards
From $9.99Unlock all

Master the BOC Clinical Chemistry Test. Prepare with interactive flashcards and multiple choice questions with detailed explanations. Boost your confidence and ace the exam!

Multiple Choice

Which factor contributes to the PCO2 electrode requiring 60–120 seconds to reach equilibrium?

Explanation:
The time it takes for a PCO2 electrode to reach equilibrium is governed by how quickly CO2 can diffuse through the membrane into the internal electrolyte and form the equilibrated chemical signal. The membrane’s diffusion characteristics—thickness, material, and permeability—set the rate at which CO2 crosses into the sensing solution. If the membrane is thicker or less permeable, diffusion is slower, so it takes longer to stabilize, often on the order of 60–120 seconds. The other factors don’t primarily control this equilibration rate: the oxygen tension of the blood (PO2) affects oxygen measurements more than CO2 diffusion, the type of calibrating standard doesn’t change how fast diffusion occurs, and the polarizing mercury cell’s potential maintains the electrochemical driving force but doesn’t determine the diffusion-limited equilibration time.

The time it takes for a PCO2 electrode to reach equilibrium is governed by how quickly CO2 can diffuse through the membrane into the internal electrolyte and form the equilibrated chemical signal. The membrane’s diffusion characteristics—thickness, material, and permeability—set the rate at which CO2 crosses into the sensing solution. If the membrane is thicker or less permeable, diffusion is slower, so it takes longer to stabilize, often on the order of 60–120 seconds. The other factors don’t primarily control this equilibration rate: the oxygen tension of the blood (PO2) affects oxygen measurements more than CO2 diffusion, the type of calibrating standard doesn’t change how fast diffusion occurs, and the polarizing mercury cell’s potential maintains the electrochemical driving force but doesn’t determine the diffusion-limited equilibration time.

More Multiple Choice Questions
Subscribe

Get the latest from Examzify

You can unsubscribe at any time. Read our privacy policy