Nokea
The patient’s potassium level is 7.0 mEq/L. Besides dialysis, which of the following actually reduces plasma potassium levels and total body potassium content safely in a patient with renal dysfunction?
- A. Sodium polystyrene sulfonate
- B. Sodium polystyrene sulfonate with sorbitol
- C. Regular insulin
- D. Calcium gluconate
Correct Answer: C
Rationale: Correct Answer: C - Regular insulin
Rationale:
1. Insulin promotes cellular uptake of potassium.
2. When insulin is administered, it moves potassium from extracellular to intracellular space.
3. This decreases plasma potassium levels safely.
4. Other options do not directly lower potassium levels in the same manner.
Summary of Other Choices:
A: Sodium polystyrene sulfonate - exchanges sodium for potassium in the intestines, not reducing total body potassium.
B: Sodium polystyrene sulfonate with sorbitol - similar to A, does not reduce total body potassium.
D: Calcium gluconate - does not directly lower potassium levels, used for treating hyperkalemia-induced cardiac toxicity.
You may also like to solve these questions
represent?
- A. Alveolar oxygen tension.
- B. Oxygen that is chemically combined with hemoglobin .
- C. Oxygen that is physically dissolved in plasma.
- D. Total oxygen consumption.
Correct Answer: B
Rationale: The correct answer is B: Oxygen that is chemically combined with hemoglobin. This is because oxygen primarily travels in the blood by binding to hemoglobin in red blood cells, forming oxyhemoglobin. This process allows for efficient transport of oxygen to tissues throughout the body. Choices A, C, and D are incorrect because:
A: Alveolar oxygen tension refers to the partial pressure of oxygen in the alveoli of the lungs, not the specific form of oxygen in the blood.
C: Oxygen physically dissolved in plasma refers to the small amount of oxygen that is not bound to hemoglobin and is less significant in oxygen transport compared to oxygen bound to hemoglobin.
D: Total oxygen consumption is the overall amount of oxygen utilized by the body, not specifically the form of oxygen bound to hemoglobin for transport.
Intrapulmonary shunting refers to what outcome?
- A. Alveoli that are not perfused.
- B. Blood that is shunted from the left side of the heart to t he right and causes heart failure.
- C. Blood that is shunted from the right side of the heart to the left without oxygenation.
- D. Shunting of blood supply to only one lung.
Correct Answer: C
Rationale: Step-by-step rationale for why choice C is correct:
1. Intrapulmonary shunting refers to blood bypassing the normal oxygenation process in the lungs.
2. Choice C describes blood being shunted from the right side of the heart (deoxygenated blood) to the left side without oxygenation, leading to systemic circulation without oxygenation.
3. Choices A, B, and D do not accurately describe intrapulmonary shunting as they focus on other concepts like alveolar perfusion, heart failure, and unilateral lung blood supply, respectively.
The nurse is caring for an older adult patient who is in card iogenic shock and has failed to respond to medical treatment. The primary care provider conducts a conference to explain that they have exhausted treatment options and suggest that the patient be made a “do not resuscitate” status. This scenario illustrates what medical concept?
- A. Brain death
- B. Futility
- C. Incompetence
- D. Life-prolonging procedures
Correct Answer: B
Rationale: The correct answer is B: Futility. In this scenario, the primary care provider suggests making the patient a "do not resuscitate" status because further medical treatment is deemed futile. Futility refers to situations where medical interventions are unlikely to achieve the desired outcome. This decision is made when the benefits of continuing treatment do not outweigh the burdens on the patient.
Summary:
A: Brain death does not apply here as the patient is not brain dead.
C: Incompetence refers to the patient's ability to make decisions, not the medical concept being illustrated.
D: Life-prolonging procedures are not being discussed; the focus is on the futility of further treatment.
The intensive care unit (ICU) nurse educator will determine that teaching arterial pressure monitoring to staff nurses has been effective when the nurse:
- A. Balances and calibrates the monitoring equipment every 2 hours.
- B. Positions the zero-reference stopcock line level with the hemostatic axis.
- C. Ensures that the patient is supine with the head of the bed flat for all readings.
- D. Rechecks the location of the hemostatic axis when changing the patient’s position.
Correct Answer: B
Rationale: The correct answer is B because positioning the zero-reference stopcock line level with the hemostatic axis ensures accurate arterial pressure monitoring. Placing the stopcock at the hemostatic axis allows for correct measurement of blood pressure without any errors due to height differences. This positioning helps in obtaining precise and reliable readings.
A: Balancing and calibrating the monitoring equipment every 2 hours is important for equipment maintenance but does not directly impact the accuracy of arterial pressure monitoring.
C: Ensuring the patient is supine with the head of the bed flat is a standard position for arterial pressure monitoring but does not specifically address the correct positioning of the stopcock.
D: Rechecking the location of the hemostatic axis when changing the patient's position is essential for maintaining accuracy, but it does not directly relate to the initial correct positioning of the stopcock.
Continuous venovenous hemofiltration is used to
- A. remove fluids and solutes through the process of convection.
- B. remove plasma water in cases of volume overload.
- C. remove plasma water and solutes by adding dialysate.
- D. combine ultrafiltration, convection, and dialysis.
Correct Answer: A
Rationale: The correct answer is A because continuous venovenous hemofiltration (CVVH) primarily removes fluids and solutes through the process of convection. In CVVH, blood flows through a filter where hydrostatic pressure drives plasma water and solutes across a semipermeable membrane. This process mimics the natural filtration that occurs in the kidneys. Choice B is incorrect because CVVH does not specifically target plasma water only but also removes solutes. Choice C is incorrect because CVVH does not involve adding dialysate to remove plasma water and solutes. Choice D is incorrect because while CVVH may involve ultrafiltration and convection, it does not typically include dialysis as a primary mechanism for solute removal.