S M Koch1, R W Taylor. 1. Department of Anesthesiology, University of Texas, Houston 77030.
Abstract
OBJECTIVE: To review the physiology of the chloride ion and its relationship to various disease states encountered in the ICU. Special emphasis was paid to the renal handling of chloride and its role in the evaluation of the urine and serum anion gaps. Metabolic acidosis and alkalosis are discussed. DATA SOURCES: English-language articles were identified through a search of the MEDLINE and Index Medicus databases. Bibliographies of retrieved articles were examined for relevant articles. STUDY SELECTION: Approximately 125 articles and 25 textbook chapters were reviewed. Those articles most applicable to the ICU were used. Information contained in text chapters was included primarily in the tables. DATA EXTRACTION: All available information was reviewed and analyzed by the authors before inclusion. DATA SYNTHESIS: Guidelines for the evaluation of urine and serum electrolyte concentrations are presented. The use of the urine anion gap is discussed, particularly as it relates to the diagnosis of hyperchloremic metabolic acidosis. Stool chloride provides information relevant to congenital and acquired diarrheas. The evaluation of metabolic acidosis requires the calculation of the serum anion gap. Both normal and increased gap acidoses are discussed, although increased gap acidoses are more commonly encountered in the ICU. Urine chloride is invaluable in defining whether the metabolic alkalosis is sodium-chloride responsive (urine chloride less than 10 mmol/L) or sodium chloride-unresponsive (urine chloride greater than 20 mmol/L). CONCLUSIONS: Measurement of chloride is a valuable tool in the evaluation and treatment of a variety of disorders. Serum chloride is most helpful in assessing both normal and increased anion gap metabolic acidoses, while urine chloride finds utility in the diagnosis of metabolic alkalosis and hyperchloremia metabolic acidosis. The evaluation of any disturbance in chloride homeostasis that defies easy explanation necessitates the measurement of stool electrolytes.
OBJECTIVE: To review the physiology of the chloride ion and its relationship to various disease states encountered in the ICU. Special emphasis was paid to the renal handling of chloride and its role in the evaluation of the urine and serum anion gaps. Metabolic acidosis and alkalosis are discussed. DATA SOURCES: English-language articles were identified through a search of the MEDLINE and Index Medicus databases. Bibliographies of retrieved articles were examined for relevant articles. STUDY SELECTION: Approximately 125 articles and 25 textbook chapters were reviewed. Those articles most applicable to the ICU were used. Information contained in text chapters was included primarily in the tables. DATA EXTRACTION: All available information was reviewed and analyzed by the authors before inclusion. DATA SYNTHESIS: Guidelines for the evaluation of urine and serum electrolyte concentrations are presented. The use of the urine anion gap is discussed, particularly as it relates to the diagnosis of hyperchloremic metabolic acidosis. Stool chloride provides information relevant to congenital and acquired diarrheas. The evaluation of metabolic acidosis requires the calculation of the serum anion gap. Both normal and increased gap acidoses are discussed, although increased gap acidoses are more commonly encountered in the ICU. Urine chloride is invaluable in defining whether the metabolic alkalosis is sodium-chloride responsive (urine chloride less than 10 mmol/L) or sodium chloride-unresponsive (urine chloride greater than 20 mmol/L). CONCLUSIONS: Measurement of chloride is a valuable tool in the evaluation and treatment of a variety of disorders. Serum chloride is most helpful in assessing both normal and increased anion gap metabolic acidoses, while urine chloride finds utility in the diagnosis of metabolic alkalosis and hyperchloremia metabolic acidosis. The evaluation of any disturbance in chloride homeostasis that defies easy explanation necessitates the measurement of stool electrolytes.
Authors: Richard Brunner; Andreas Drolz; Thomas-Matthias Scherzer; Katharina Staufer; Valentin Fuhrmann; Christian Zauner; Ulrike Holzinger; Bruno Schneeweiß Journal: Crit Care Date: 2015-04-06 Impact factor: 9.097