Hypochloremia and Diuretic Resistance in Heart Failure: Mechanistic Insights

Background—Recent epidemiological studies have implicated chloride, rather than sodium, as the driver of poor survival previously attributed to hyponatremia in heart failure. Accumulating basic science evidence has identified chloride as a critical factor in renal salt sensing. Our goal was to probe the physiology bridging this basic and epidemiological literature. Methods and Results—Two heart failure cohorts were included: (1) observational: patients receiving loop diuretics at the Yale Transitional Care Center (N=162) and (2) interventional pilot: stable outpatients receiving ≥80 mg furosemide equivalents were studied before and after 3 days of 115 mmol/d supplemental lysine chloride (N=10). At the Yale Transitional Care Center, 31.5% of patients had hypochloremia (chloride ⩽96 mmol/L). Plasma renin concentration correlated with serum chloride (r=−0.46; P<0.001) with no incremental contribution from serum sodium (P=0.49). Hypochloremic versus nonhypochloremic patients exhibited renal wasting of chloride (P=0.04) and of chloride relative to sodium (P=0.01), despite better renal free water excretion (urine osmolality 343±101 mOsm/kg versus 475±136; P<0.001). Hypochloremia was associated with poor diuretic response (odds ratio, 7.3; 95% confidence interval, 3.3–16.1; P<0.001). In the interventional pilot, lysine chloride supplementation was associated with an increase in serum chloride levels of 2.2±2.3 mmol/L, and the majority of participants experienced findings such as hemoconcentration, weight loss, reduction in amino terminal, pro B-type natriuretic peptide, increased plasma renin activity, and increased blood urea nitrogen to creatinine ratio. Conclusions—Hypochloremia is associated with neurohormonal activation and diuretic resistance with chloride depletion as a candidate mechanism. Sodium-free chloride supplementation was associated with increases in serum chloride and changes in several cardiorenal parameters. Clinical Trial Registration—URL: http://www.clinicaltrials.gov. Unique identifier: NCT02031354.

[1]  F. Wilson,et al.  Hypochloraemia is strongly and independently associated with mortality in patients with chronic heart failure , 2016, European journal of heart failure.

[2]  S. Ellis,et al.  Importance of Abnormal Chloride Homeostasis in Stable Chronic Heart Failure , 2016, Circulation. Heart failure.

[3]  L. Powell,et al.  Impact of Dietary Sodium Restriction on Heart Failure Outcomes. , 2016, JACC. Heart failure.

[4]  C. O'connor,et al.  The Role of Sodium and Chloride in Heart Failure: Does It Take Two to Tango? , 2015, Journal of the American College of Cardiology.

[5]  R. Starling,et al.  Prognostic Role of Serum Chloride Levels in Acute Decompensated Heart Failure. , 2015, Journal of the American College of Cardiology.

[6]  M. Redfield,et al.  Dietary sodium modulation of aldosterone activation and renal function during the progression of experimental heart failure , 2015, European journal of heart failure.

[7]  E. Goldsmith,et al.  Chloride Sensing by WNK1 Involves Inhibition of Autophosphorylation , 2014, Science Signaling.

[8]  W. Mosleh,et al.  Hypertonic saline with furosemide for the treatment of acute congestive heart failure: a systematic review and meta-analysis. , 2014, International journal of cardiology.

[9]  C. Ariano,et al.  Hypertonic saline plus i.v. furosemide improve renal safety profile and clinical outcomes in acute decompensated heart failure , 2015, Herz.

[10]  C. Parikh,et al.  Timing of hemoconcentration during treatment of acute decompensated heart failure and subsequent survival: importance of sustained decongestion. , 2013, Journal of the American College of Cardiology.

[11]  G. Aliti,et al.  Aggressive fluid and sodium restriction in acute decompensated heart failure: a randomized clinical trial. , 2013, JAMA internal medicine.

[12]  Biykem Bozkurt,et al.  2013 ACCF/AHA guideline for the management of heart failure: a report of the American College of Cardiology Foundation/American Heart Association Task Force on practice guidelines. , 2013, Circulation.

[13]  Kenrick Berend,et al.  Chloride: the queen of electrolytes? , 2012, European journal of internal medicine.

[14]  R. Bellomo,et al.  Bench-to-bedside review: Chloride in critical illness , 2010, Critical care.

[15]  C. Schmid,et al.  A new equation to estimate glomerular filtration rate. , 2009, Annals of internal medicine.

[16]  R. Lifton,et al.  Regulation of NKCC2 by a chloride-sensing mechanism involving the WNK3 and SPAK kinases , 2008, Proceedings of the National Academy of Sciences.

[17]  K. Swedberg,et al.  Effects of oral tolvaptan in patients hospitalized for worsening heart failure: the EVEREST Outcome Trial. , 2007, JAMA.

[18]  G. Filippatos,et al.  Congestion in acute heart failure syndromes: an essential target of evaluation and treatment. , 2006, The American journal of medicine.

[19]  A. Subramanya,et al.  WNK kinases regulate sodium chloride and potassium transport by the aldosterone-sensitive distal nephron. , 2006, Kidney international.

[20]  Nadine Bazilinski,et al.  Brenner and Rector's The Kidney , 1997 .

[21]  J. Schnermann,et al.  Whys and wherefores of juxtaglomerular apparatus function. , 1996, Kidney international.

[22]  D. Brater,et al.  Bioavailability, pharmacokinetics, and pharmacodynamics of torsemide and furosemide in patients with congestive heart failure , 1995, Clinical pharmacology and therapeutics.

[23]  H. Koomans,et al.  Evaluation of lithium clearance as a marker of proximal tubule sodium handling. , 1989, Kidney international.

[24]  W. Welch,et al.  Renal tubular chloride and renin release. , 1987, The Journal of laboratory and clinical medicine.

[25]  D. Wesson,et al.  Glomerular filtration effects of acute volume expansion: importance of chloride. , 1987, Kidney international.

[26]  R. Heel,et al.  Bumetanide , 1984, Drugs.

[27]  J. Briggs The macula densa sensing mechanism for tubuloglomerular feedback. , 1981, Federation proceedings.