A 62-year-old man is brought to the emergency department because of a 4-hour history of abdominal pain, nausea, vomiting, and confusion. His wife reports that he had blurry vision on the way to the hospital. Two weeks ago, he lost his job and since then has been extremely worried about their financial situation and future. He has congestive heart failure and atrial fibrillation well controlled with combination medical therapy. His temperature is 36.5°C (97.7°F), pulse is 57/min and irregular, respirations are 14/min, and blood pressure is 118/63 mm Hg. The patient is oriented only to person. Serum studies show: Na+ 138 mEq/L Cl− 100 mEq/L K+ 5.3 mEq/L HCO3− 25 mEq/L Blood urea nitrogen 14 mg/dL Creatinine 0.9 mg/dL An ECG shows premature ventricular beats. The drug most likely responsible for this patient's symptoms has which of the following mechanisms of action?

Blockade of aldosterone receptors

Blockade of beta-adrenergic receptors

Inhibition of Na+-K+-2Cl--cotransporters

A pharmaceutical company is studying a new drug that inhibits the glucose transporter used by intestinal enterocytes to absorb glucose into the body. The drug was designed such that it would act upon the glucose transporter similarly to how cyanide acts upon cytochrome proteins. During pre-clinical studies, the behavior of this drug on the activity of the glucose transporter is examined. Specifically, enterocyte cells are treated with the drug and then glucose is added to the solution at a concentration that saturates the activity of the transporter. The transport velocity and affinity of the transporters under these conditions are then measured. Compared to the untreated state, which of the following changes would most likely be seen in these transporters after treatment?

Unchanged Km and decreased Vmax

Unchanged Km and unchanged Vmax

Increased Km and unchanged Vmax

Increased Km and decreased Vmax

Decreased Km and decreased Vmax

A previously healthy 52-year-old woman comes to the physician because of a 3-month history of chest pain on exertion. She takes no medications. Cardiopulmonary examination shows no abnormalities. Cardiac stress ECG shows inducible ST-segment depressions in the precordial leads that coincide with the patient's report of chest pain and resolve upon cessation of exercise. Pharmacotherapy with verapamil is initiated. This drug is most likely to have which of the following sets of effects? $$$ End-diastolic volume (EDV) %%% Blood pressure (BP) %%% Contractility %%% Heart rate (HR) $$$

No change no change no change no change

A patient is receiving daily administrations of Compound X. Compound X is freely filtered in the glomeruli and undergoes net secretion in the renal tubules. The majority of this tubular secretion occurs in the proximal tubule. Additional information regarding this patient's renal function and the renal processing of Compound X is included below: Inulin clearance: 120 mL/min Plasma concentration of Inulin: 1 mg/mL PAH clearance: 600 mL/min Plasma concentration of PAH: 0.2 mg/mL Total Tubular Secretion of Compound X: 60 mg/min Net Renal Excretion of Compound X: 300 mg/min Which of the following is the best estimate of the plasma concentration of Compound X in this patient?

There is insufficient information available to estimate the plasma concentration of Compound X

P-glycoprotein interactions for USMLE Step 2 CK: High-Yield Pharmacology Lessons

P-glycoprotein (MDR1) - The Body's Bouncer

Function: ATP-dependent efflux pump encoded by the MDR1 gene. Actively transports drugs out of cells, ↓ absorption & penetration into protected sites.
Key Locations:
- Intestinal epithelium: ↓ drug absorption.
- Blood-brain barrier: Limits CNS entry.
- Renal tubules: ↑ drug elimination.
- Tumor cells: Contributes to multi-drug resistance (MDR).

P-glycoprotein efflux pump mechanism

Inhibitors (↑ Drug Levels):
- Verapamil
- Quinidine
- Macrolides (e.g., erythromycin)
- Azole antifungals (e.g., ketoconazole)
Inducers (↓ Drug Levels):
- Rifampin
- St. John's Wort
- Carbamazepine

⭐ Exam Favorite: Co-administration of digoxin with a P-gp inhibitor (e.g., verapamil, quinidine) can ↑ digoxin levels, leading to toxicity. Always monitor for bradycardia, nausea, and visual disturbances.

P-gp Interactions - The Gatekeepers

Core Function: P-glycoprotein (P-gp), from the MDR1 gene, is a key ATP-dependent efflux transporter. It protects tissues by actively pumping a wide variety of drugs out of cells, which reduces intracellular drug concentration and overall bioavailability.
Key Sites & Effects:
- Intestinal epithelium → ↓ Oral drug absorption.
- Blood-brain barrier → ↓ CNS drug penetration.
- Renal proximal tubules → ↑ Renal drug excretion.
- Hepatocytes → ↑ Biliary drug excretion.
- Tumor cells → Contributes to multi-drug resistance in chemotherapy.
P-gp Inhibitors → ↑ Substrate Levels & Toxicity:
- Mechanism: Block the P-gp pump, increasing absorption and decreasing clearance of substrates.
- Examples: Macrolides (Clarithromycin), Azoles (Ketoconazole), Protease Inhibitors (Ritonavir), Amiodarone, Verapamil, Diltiazem, Cyclosporine.
P-gp Inducers → ↓ Substrate Levels & Efficacy:
- Mechanism: Upregulate P-gp expression, decreasing absorption and increasing clearance of substrates.
- Examples: Rifampin, St. John's Wort, Carbamazepine, Phenytoin, Phenobarbital.

⭐ Digoxin has a narrow therapeutic index and is a classic P-gp substrate. Co-administration with an inhibitor like Amiodarone or Verapamil can double its concentration, risking life-threatening cardiotoxicity. Always consider dose reduction.

📌 P-gp Inhibitors cause drug levels to Increase. P-gp Inducers cause drug levels to Decrease.

Clinical Correlations - Patient Impact

P-gp Inhibition: ↑ absorption and ↓ clearance of substrates, leading to ↑ plasma concentration and toxicity.
- Key Inhibitors: Verapamil, amiodarone, quinidine, macrolides (e.g., clarithromycin), azole antifungals, protease inhibitors.
- Clinical Impact: Co-administration of verapamil with digoxin ↑ digoxin levels, risking bradycardia and AV block.
P-gp Induction: ↓ absorption and ↑ clearance of substrates, causing ↓ plasma concentration and therapeutic failure.
- Key Inducers: Rifampin, St. John's wort, carbamazepine, phenytoin.
- Clinical Impact: Rifampin ↓ dabigatran levels, increasing the risk of stroke or systemic embolism.

⭐ Digoxin toxicity is a classic adverse effect precipitated by P-gp inhibitors like verapamil or amiodarone, which reduce its renal clearance.

High‑Yield Points - ⚡ Biggest Takeaways

P-glycoprotein (P-gp) is an ATP-dependent efflux pump that transports drugs out of cells.

It is primarily located in the gut, kidneys, and blood-brain barrier to limit drug absorption and distribution.

P-gp inducers (e.g., Rifampin, St. John's wort) ↓ levels of substrates like Digoxin, risking therapeutic failure.

P-gp inhibitors (e.g., Verapamil, Ketoconazole) ↑ levels of substrates, increasing toxicity risk.

A key mechanism of multidrug resistance in cancer cells.

Continue reading on Oncourse

CONTINUE READING — FREE

or get the app

App Store|Google Play