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. 2007 Jun 15;11(3):141. doi: 10.1186/cc5935

Kidney function assessment in the critically ill child: is it time to leave creatinine behind?

Stuart L Goldstein 1,
PMCID: PMC2206426  PMID: 17581273

Abstract

The accurate diagnosis of acute kidney injury (AKI) is especially problematic in critically ill patients in whom renal function is in an unsteady state, rendering creatinine-based baseline assessment measures of renal function potentially inadequate. Herrero-Morin and colleagues performed a cross-sectional analysis of the ability of cystatin C and β2 microglobulin to reflect creatinine clearance in pediatric patients with AKI. The aim of this commentary is to review the current state of AKI clinical and translational research in the light of the results presented in that study.

Current standard assessments of renal function for pediatric patients use serum creatinine or formulas based on serum creatinine designed for longitudinal assessment of baseline renal function. The accurate diagnosis of acute kidney injury (AKI) is especially problematic in critically ill patients in whom renal function is in an unsteady state, thus rendering such creatinine-based baseline assessment measures of renal function potentially inadequate. Pediatric patients comprise a valuable cohort for study, because they usually do not carry many of the co-morbidities that often confound adult patient studies. In this issue of Critical Care, Herrero-Morin and colleagues assess the ability of two markers, cystatin C and β2 microglobulin (β2M), to detect decreases in renal function accurately in 25 critically ill children [1].

The authors conducted a careful study to obtain 24-hour urine collections of creatinine clearance before obtaining serum β2M and cystatin C samples. Fourteen (56%) developed AKI, which they defined as a creatinine clearance of less than 80 ml/min per 1.73 m2. Their primary results demonstrated thresholds for both β2M (1.5 mg/l) and cystatin C (0.6 mg/l) that exhibited reasonable sensitivity and specificity to detect AKI accurately, whereas serum creatinine was no different between patients with and without AKI. The present study is therefore the first report of non-creatinine-based methods to estimate renal function in critically ill pediatric patients with AKI.

The rationale for assessing AKI markers in critically ill patients is strong. Numerous studies demonstrate that AKI is an independent risk factor for mortality, so critically ill patients are dying from and not just 'with' AKI. Until recently, pediatric AKI studies used the Schwartz formula [2], a creatinine-based equation designed to assess baseline renal function [3]. The need for accurate and sensitive description of AKI has led to the development of a multidimensional AKI classification system, which in essence grades AKI severity. The most widely referenced system is the RIFLE (Risk, Injury, Failure, Loss, End-stage kidney disease) criteria, proposed as an empiric system by the Acute Dialysis Quality Initiative [4]. Hoste and colleagues validated the RIFLE criteria in critically ill adult patients, finding that patients with maximum RIFLE class R, class I and class F had hospital mortality rates of 8.8%, 11.4% and 26.3%, respectively [5]. Our center recently reported similar results for pediatric modified RIFLE criteria in a pediatric cohort of critically ill children: AKI by pediatric RIFLE during admission was an independent predictor of intensive care, hospital length of stay and an increased risk of death independent of the Pediatric Risk of Mortality (PRISM II) score (odds ratio 3.0) [6].

Early recognition of AKI, before changes in serum creatinine occur, has been an area of intensive investigation over the past 5 years. The rationale for such research emanates from studies demonstrating that even small increases in serum creatinine are associated with increases in patient morbidity and mortality. Chertow found a 6.5-fold increase in the odds of death for patients with a 0.5 mg/dl increase in serum creatinine, even when adjusted for numerous co-morbidities [7]. We have found a sevenfold increase in the odds of death in pediatric patients with acute decompensated heart failure who had an serum creatinine increase of 0.3 mg/dl or more [8].

Cystatin C is a logical marker for AKI study because its concentration is not affected by muscle mass and it is not secreted by the renal tubule; it is therefore a potentially more accurate and earlier marker of change in glomerular filtration rate (GFR) than serum creatinine. Herget-Rosenthal and colleagues found increases in serum cystatin C 1 1/2 days before AKI development (defined as attaining RIFLE-R [9]), and the same group found serum cystatin C to detect decreased GFR 1 1/2 days before serum creatinine increased in patients undergoing unilateral nephrectomy for kidney donation [10]. Because both cystatin C and β2M in the current study by Herrero-Morin differed between patients with and without AKI, whereas serum creatinine did not differ, a reasonable inference could be that serum β2M and cystatin C detect renal injury before changes in serum creatinine. However, the present study was not designed to assess for earlier AKI recognition. Further study of these two markers, along with potential urinary AKI biomarkers currently under investigation, including NGAL (neutrophil gelatinase-associated lipocalin) [11], interleukin-18 [12] and KIM-1 (kidney injury molecule-1) [13], is required in pediatric patients to develop a panel of markers for the accurate and reliable assessment of early AKI development, AKI duration and site of injury. So, is it time to leave serum creatinine behind as a marker of renal function in patients with AKI? Currently, the answer is no, but the work of Herrero-Morin and colleagues argues strongly for the study of other markers, including cystatin C and β2M, in the near future.

Abbreviations

AKI = acute kidney injury; β2M = β2 microglobulin; GFR = glomerular filtration rate; RIFLE = Risk, Injury, Failure, Loss, End-stage kidney disease.

Competing interests

The authors declare that they have no competing interests.

See related research by Herrero-Morín et al., http://ccforum.com/content/11/3/R59

References

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