RENAL TUBULAR-ACIDOSIS (RTA) - RECOGNIZE THE AMMONIUM DEFECT AND PHORGET THE URINE PH

被引:45
作者
CARLISLE, EJF
DONNELLY, SM
HALPERIN, ML
机构
[1] Renal Division, St. Michael's Hospital, Toronto
来源
PEDIATRIC NEPHROLOGY | 1991年 / 5卷 / 02期
关键词
AMMONIUM; RENAL TUBULAR ACIDOSIS; HYPERCHLORAEMIC METABOLIC ACIDOSIS; URINE NET CHARGE; URINE PH; ACID-BASE; NET ACID EXCRETION;
D O I
10.1007/BF01095965
中图分类号
R72 [儿科学];
学科分类号
100202 ;
摘要
To maintain acid-base balance, the kidney must generate new bicarbonate by metabolizing glutamine and excreting ammonium (NH4+). During chronic metabolic acidosis, the kidney should respond by increasing the rate of excretion of NH4+ to 200-300 mmol/day. If the rate of excretion of NH4+ is much lower, the kidney is responsible for causing or perpetuating the chronic metabolic acidosis. Thus, the first step in the assessment of hyperchloraemic metabolic acidosis is to evaluate the rate of excretion of NH4+. It is important to recognize that the urine pH may be misleading when initially assessing the cause of this acidosis, as it does not necessarily reflect the rate of excretion of NH4+. If proximal renal tubular acidosis (RTA) is excluded, low NH4+ excretion disease may be broadly classified into problems of NH4+ production and problems interstitial disease or disorders of hydrogen ion secretion. The measurement of the urine pH at this stage may identify which problem predominates. This approach returns the focus of the investigation of RTA from urine pH to urine NH4+.
引用
收藏
页码:242 / 248
页数:7
相关论文
共 28 条
  • [11] Halperin M.L., Goldstein M.B., Stinebaugh B.J., Jungas R.L., Biochemistry and physiology of ammonium excretion, The kidney: physiology and pathophysiology, pp. 1471-1490, (1985)
  • [12] Lemieux G., Pichette C., Vinay P., Gougoux A., Cellular mechanism of the antiammoniagenic effect of ketone bodies in the dog, Am J Physiol, 239, pp. F420-F426, (1980)
  • [13] Tannen R.L., Effect of potassium on renal acidification and acid-base homeostasis, Semin Nephrol, 7, pp. 263-273, (1987)
  • [14] Halperin M.L., Kamel K.S., Ethier J.H., Magner P.O., What is the underlying defect in patients with isolated, proximal renal tubular acidosis?, Am J Nephrol, 9, pp. 265-268, (1989)
  • [15] Good D.W., Active absorption of NH<sub>4</sub><sup>+</sup> by rat medullary thick ascending limb: inhibition by potassium, Am J Physiol, 255, pp. F78-F87, (1988)
  • [16] Good D.W., Caflisch C.R., DuBose T.D., Transepithelial ammonia concentration gradients in inner medulla of the rat, Am J Physiol, 252, pp. F491-F500, (1987)
  • [17] Stanton B.A., Regulation by adrenal corticosteroids of sodium and potassium transport in loop of Henle and distal tubule of rat kidney, J Clin Invest, 78, pp. 1612-1620, (1986)
  • [18] Field M.J., Giebisch G.J., Hormonal control of renal potassium excretion, Kidney Int, 27, pp. 379-387, (1985)
  • [19] Al-Awqati Q., Norby L.H., Mueller A., Steinmetz P.R., Characteristics of stimulation of H<sup>+</sup> transport by aldosterone in turtle urinary bladder, Journal of Clinical Investigation, 58, pp. 351-358, (1976)
  • [20] Oh, Carroll H.J., The anion gap, N Engl J Med, 297, pp. 814-817, (1977)
123