Which components define acid-base balance among the listed electrolytes?

• A. Bicarbonate, Cl, K
• B. Sodium, Potassium, Chloride
• C. Magnesium, Calcium, Phosphate
• D. Chloride, Sulfate, Phosphate

Answer: (A)

Acid-base balance in body fluids hinges on a buffering system and charge balance, mainly the bicarbonate buffering system and how chloride and potassium participate in maintaining electroneutrality as pH changes. Bicarbonate (HCO3−) is the key extracellular buffer; pH is governed by the ratio of bicarbonate to carbon dioxide (pH ≈ 6.1 + log([HCO3−]/(0.03 × PCO2)). When bicarbonate rises or falls, pH shifts accordingly. Chloride helps keep the electrical balance in the fluid; changes in bicarbonate are often accompanied by chloride adjustments, as seen in metabolic acidosis with hyperchloremia, where the anion balance shifts and pH changes reflect that interplay. Potassium also fits into this picture because hydrogen ion shifts between compartments during acid-base disturbances cause potassium to move in the opposite direction to preserve electroneutrality and overall cellular balance.

Among the listed electrolytes, bicarbonate, chloride, and potassium together capture the buffering capacity and the charge-balancing responses that define the acid-base status. The other sets miss the buffering element or the key interchanges that occur with acid-base changes, so they don’t reflect the overall balance as directly.