Chloride-liberal fluids are associated with acute kidney injury after liver transplantation

Acute kidney injury (AKI) occurs both frequently after liver transplantation, reportedly in 29 to 60% recipients [1]-[3] and, irrespective of severity, confers an increased risk of death [4]. This increase in risk of mortality extends from the early postoperative period (28 days) and up to one year after transplantation [1]. The National Institute of Diabetes and Digestive and Kidney Disease (NIDDK) long-term follow-up study ascribed a 2.66 hazard ratio (HR) directly attributable to renal dysfunction developing after liver transplantation [5].

Previously described risk factors for AKI in liver recipients are greater severity of illness pretransplant (higher model for end-stage liver disease (MELD) scores, intensive care unit (ICU) admission, and coagulopathy), vasopressors, and greater transfusions in the immediate perioperative period [5]-[13]. However, very little is known about the effects of intravenous fluid selection (chloride-liberal versus chloride-restrictive) or the effects of fluid balance on the risk of renal injury. An overall fluid overload state leads to renal congestion, compromised renal blood flow and reductions in glomerular filtration rate (GFR) [14]. In critically ill patients, a positive fluid balance has been associated with increased mortality [15],[16] and poorer outcomes once AKI develops [17]-[19]. Recent evidence has highlighted the possible nephrotoxic effects of `chloride-liberal’ fluids (0.9% saline). Animal and human controlled studies have shown that infusions of chloride-liberal or solutions with supraphysiological chloride concentrations cause vasoconstriction of renal afferent arterioles, cortical hypoperfusion and decreased GFR [20]-[22]. In a recent pre- and postintervention study, restriction to chloride-restrictive fluids was associated with lower AKI and need for renal replacement therapy (RRT) as compared to chloride-liberal fluids [23]. Therefore, perioperative intravenous fluid selection and volume may prove to be a modifiable risk factor for the prevention of AKI. No similar data exists for liver transplant recipients. These patients clearly are at an increased risk of renal injury with mortal consequences. We hypothesized that AKI occurring in the early postoperative period after liver transplant may be associated with the use of chloride-liberal fluids and overall fluid overload causing renal congestion.

This study is reported following the STROBE statement checklist for observational studies [24]. All studies at our institution require ethical approval; the Office of Research Affairs (ORA) and ORA Research Ethics Committee approved the study (RAC no. 2131 073). Patient consent was waived by the Research Ethics Committee.

In this observational study, we found that liver transplant recipients were more likely to develop AKI if they received larger volumes of chloride-liberal (hyperchloremic) fluids. This association was significant, after adjusting for baseline variables, for both 5% albumin in 0.9% saline and only 0.9% saline infusions. Patients who developed AKI had significantly higher serum chloride levels compared to transplant recipients that did not develop AKI.

`Normal’ saline or 0.9% saline contains supraphysiological levels of chloride (154 mmol/L as compared to Hartmann’s solution, Ringer’s lactate or Plasma-Lyte 148, all of which contain chloride concentrations that are lower (94 to 111 mmol/L). Five percent albumin is available either as salt-poor or in sodium chloride (chloride concentration 128 mmol/L). Intravenous infusions of chloride-liberal fluids have been associated with hyperchloremia and metabolic acidosis when administered in large volumes [26].

Our results show a detrimental effect on renal function with use of chloride-liberal fluids in the immediate postoperative period (up to 48 hours). Support for our findings comes from animal studies that have demonstrated reductions in GFRs, renal arteriolar vasoconstriction [27], and human volunteer studies that have shown reduced renal cortical tissue perfusion, renal blood flow velocity after infusions of hyperchloremic solutions. [28]. In controlled trials, chloride-liberal fluids compared to chloride-poor fluids have been linked to longer time to micturition [21], lower urine output [29] and in a recent observational study of over 31,000 postoperative patients, 0.9% saline compared to `balanced’ crystalloids increased the risk of acute renal failure requiring dialysis [30]. Yunos et al., in a pre- and postintervention study on 1,530 critically ill patients found that a chloride-restrictive fluid strategy resulted in a significant reduction in AKI, need for RRT and increase in creatinine as compared to a control group given chloride-liberal fluids [23].

Possible explanations for this renal `toxicity’ of chloride-liberal fluids come from animal studies that have demonstrated renal vasoconstriction [22] and thromboxane release after chloride infusions [20]. Chloride infusions increase delivery to the macula densa that stimulates glomerulotubular feedback leading to afferent arteriole constriction, mesangial contraction and resultant decrease in GFR [31].

Patients in our study received both 5% albumin in saline and 20% albumin in saline. Though it is possible that the observed renal dysfunction resulted from hyperoncotic albumin, the data on 20% albumin is so far inconclusive. A recent cohort study on 1,000 patients found a higher risk of renal injury and failure with the use of hyperoncotic albumin (OR 5.99) [32], however, a contradictory result was reported from two meta-analyses that concluded no harmful effects of hyperoncotic resuscitation [33],[34]. The SAFE study that compared albumin and saline found no difference in adverse outcomes [35].

Fluid overload leads to organ dysfunction due to interstitial edema and visceromegaly. The limited accommodative capacity of the encapsulated kidney causes increased interstitial hydrostatic pressures with reduced renal perfusion and filtration [36]. Additionally, a fluid overload state contributes to third spacing, ascitic fluid accumulation and abdominal compartment syndrome [37]. Cumulative fluid overload has been linked to poor outcomes in all groups (pediatric, septic, postoperative) of critically ill patients with prolonged days on mechanical ventilation, ICU stay and mortality [16],[17],[38]-[43]. Recovery of renal function in patients on RRT is also determined by overall fluid balance [17],[38],[42]. In our study, a cumulative positive fluid balance increased the duration of stay in ICU.

A limitation of our study is that the observational design does not establish a causal relationship of hyperchloremic fluid excess with the development of AKI in liver transplant recipients. These associations may be subject to bias from selection, confounding or random error. We attempted to control for confounders by using regression analysis. Another limitation is the external validity or generalizability of our results to other liver transplant recipients since we collected data only from a single institution.

In summary, large infusions of chloride-liberal fluids may predict a higher risk of AKI in liver transplant recipients. Our findings support the hypothesis that `routine’ intravenous fluids may not be routine and in themselves be associated with organ dysfunction. Our results can be used to build hypotheses for further controlled trials.

Chloride-liberal fluids may cause renal dysfunction

Large volumes (>3,200 ml) of chloride-liberal fluids infused in the first 24 hours after liver transplantation were associated with a higher risk of AKI.

AN participated in the design of the study, collected the data, analyzed and interpreted the data, drafted the manuscript, and revised the manuscript critically for important intellectual content. NS conceived the study, participated in the design of the study, made the figures and table, analyzed and interpreted the data, drafted the manuscript, and revised the manuscript critically for important intellectual content. AH, MJ, HAS and BB participated in the design of the study, collected the data, and participated in the coordination of the study. YS and DB participated in the design and coordination of the study and participated in the critical review of the final manuscript. All authors have given final approval of the version to be published.