Velázquez H, Perazella M A, Wright F S, Ellison D H
Department of Veterans Affairs Medical Center, West Haven, Connecticut.
Ann Intern Med. 1993 Aug 15;119(4):296-301. doi: 10.7326/0003-4819-119-4-199308150-00008.
Thirty consecutive patients who were treated with trimethoprim-containing drugs. All patients included in the study had the acquired immunodeficiency syndrome (AIDS).
Thirty-nine male Sprague-Dawley rats receiving normal rat chow and tap water (allowed free access).
Humans: high dose (20 mg/kg per day) of trimethoprim therapy. Rats: trimethoprim (9.6 mg/h per kg body weight) was infused intravenously or into the renal distal tubules (1 mmol/L).
Humans: Serum and urine electrolyte levels, serum creatinine, renin, aldosterone, and cortisol levels were measured, and the transtubular potassium gradient was calculated. Rats: The effects of trimethoprim infusion on urinary sodium, chloride, and potassium concentration and urine volume were measured. Sodium, chloride, potassium, and inulin concentrations were measured in fluid samples obtained from kidney distal tubules. The voltage across the wall of the distal tubule was measured.
Humans: Trimethoprim increased the serum potassium concentration by 0.6 mmol/L (95% Cl, 0.29 to 0.95 mmol/L) despite normal adrenocortical function and glomerular filtration rate. Serum potassium levels greater than 5 mmol/L were observed during trimethoprim treatment in 15 of 30 patients. Rats: Intravenous trimethoprim inhibited renal potassium excretion by 40% (Cl, 21% to 60%) and increased renal sodium excretion by 46% (Cl, 9% to 83%). Trimethoprim (1 mmol/L) in tubule fluid inhibited distal tubule potassium secretion by 59% (Cl, 26% to 92%) and depolarized the lumen-negative transepithelial voltage by 66% (Cl, 46% to 85%).
Trimethoprim (an organic cation) acts like amiloride and blocks apical membrane sodium channels in the mammalian distal nephron. As a consequence, the transepithelial voltage is reduced and potassium secretion is inhibited. Decreased renal potassium excretion secondary to these direct effects on kidney tubules leads to hyperkalemia in a substantial number of patients being treated with trimethoprim-containing drugs.
1)确定甲氧苄啶治疗期间高钾血症的发生率和严重程度。2)检验甲氧苄啶通过阻断哺乳动物远端肾单位中的钠通道来抑制肾钾排泄这一假设。
连续30例接受含甲氧苄啶药物治疗的患者。纳入研究的所有患者均患有获得性免疫缺陷综合征(艾滋病)。
39只雄性斯普拉格 - 道利大鼠,给予正常大鼠饲料和自来水(可自由摄取)。
人类:高剂量(每日20 mg/kg)甲氧苄啶治疗。大鼠:静脉注射或向肾远端小管内注入甲氧苄啶(每千克体重9.6 mg/h)(1 mmol/L)。
人类:测量血清和尿液电解质水平、血清肌酐、肾素、醛固酮和皮质醇水平,并计算跨肾小管钾梯度。大鼠:测量甲氧苄啶注入对尿钠、氯和钾浓度以及尿量的影响。测量从肾远端小管获取的液体样本中的钠、氯、钾和菊粉浓度。测量远端小管壁两侧的电压。
人类:尽管肾上腺皮质功能和肾小球滤过率正常,但甲氧苄啶使血清钾浓度升高了0.6 mmol/L(95%可信区间,0.29至0.95 mmol/L)。30例患者中有15例在甲氧苄啶治疗期间观察到血清钾水平大于5 mmol/L。大鼠:静脉注射甲氧苄啶使肾钾排泄减少40%(可信区间,21%至60%),并使肾钠排泄增加46%(可信区间,9%至83%)。小管液中的甲氧苄啶(1 mmol/L)使远端小管钾分泌减少59%(可信区间,26%至92%),并使管腔负性跨上皮电压去极化66%(可信区间,46%至85%)。
甲氧苄啶(一种有机阳离子)的作用类似于氨氯吡咪,可阻断哺乳动物远端肾单位顶端膜钠通道。因此,跨上皮电压降低,钾分泌受到抑制。这些对肾小管的直接作用导致肾钾排泄减少,在大量接受含甲氧苄啶药物治疗的患者中引发高钾血症。
