Background
Augmented renal clearance (ARC) is most of the time defined by a glomerular filtration rate (GFR) above 130 mL/min/1.73 m
2 [
1]. The pathophysiology of ARC is generally difficult to elucidate and could be secondary to several factors in intensive care (ICU) including 1. Increase of cardiac output and therefore renal blood flow [
2‐
4], mostly in case of inflammatory response syndrome; 2. Mobilization of the functional nephron reserve, mostly in younger and/or obese patients [
5]; or 3. Endocrine responses including atrial natriuretic peptide [
6].
Few studies focused on ARC in ICU. The prevalence of ARC was between 20 and 65% [
7], and was higher in the sub groups of patient with cerebro-vascular disorders [
8] or severe burns [
9]. The main factors of ARC were age [
10‐
14], reason for admission (trauma) [
2,
11,
14‐
16] and severity on admission [
2,
15‐
17]. ARC was also associated with under antibiotic dosage including vancomycin [
13,
16,
18‐
20] and beta-lactams [
21‐
26]. However, the relationship between ARC and therapeutic failure or prognosis is less clear and not well described [
21,
24,
27‐
29].
Unfortunately, those studies are scarce and most of the time based on small and specific cohort of critically ill patients.
Furthermore, very few studies focused on the evolution profile of ARC. Fuster-lluch et al. reported an incidence of ARC of 17.9% on admission which increased to 30% during the first week of ICU stay [
17]. Similar results were found by Udy et al. which also underlined that most of the ARC occurred during the first week after ICU admission [
11]. Moreover, De Waele et al. underlined that only 30% of the patients remained with ARC during their whole ICU stay [
12].
In that context, the aim of our study was to describe the evolutionary profile of ARC in ICU, to determine the factors associated with the occurrence of early and secondary ARC and to assess the impact of ARC on ICU death.
Methods
Type of study, population, and data source
We conducted a retrospective, monocentric, observational study including patients admitted for the first time to the medical and infectious resuscitation department of Bichat-Claude-Bernard University Hospital, APHP, France, between January 1, 2017 and November 31, 2020 and included in the OutcomeRea database. Patients were excluded if they had dialysis-dependent chronic kidney disease (CKD) as defined by the Knaus Scale [
30], if their length of stay (LOS) was less than 72 h, if serum creatinine was never measured during their ICU stay or if GFR could not be measured during the whole ICU stay.
Ethical considerations
Outcomerea is an observational prospective multicenter cohort. The clinical and biologic data of each included patients are registered in the database each day of the ICU stay. This database has been approved by the French Advisory Committee for Data Processing in Health Research (CCTIRS), by the Institutional Review Board (CECIC Clermont-Ferrand -IRB n°5891; Ref: 2007-16) and the French Informatics and Liberty Commission (CNIL) which waived the need for signed informed consent of the participants, in accordance with French legislation on non-interventional studies. This study did not require individual patient consent because it involved research on a previously approved database.
Collected data and definition
The GFR was estimated using the measured Creatinine Renal Clearance (CrCl) based on 24-h urine output, corresponding creatinine and urinary creatinine (Additional file
1: Table S1).
ARC was defined by a GFR above 130 mL/min/1.73 m2.
Patients on renal replacement therapy had a zero GFR from the beginning to the end of the last renal replacement therapy session during their stay in the ICU.
GFR was estimated from day 1 to day 30 in ICU.
Patients were considered to have ‘ARC on admission’ if they had ARC on day 1 or day 2 of ICU stay. Patients who had ARC for the first time after Day 2, were considered to have ‘late ARC’.
Acute kidney injury (AKI) was defined using the KDIGO (Kidney Disease: Improving Global Outcome) [
31] classification using serum creatinine item and urinary output (UO). However, since our database does not track UO at 6 h, but only for 24 h, one cannot distinguish between the subgroups of AKI (KDIGO stage 1 and 2). Under the assumption that the requirement of the UO to be less than 0.5 mg/kg/h for 24 h is more stringent than for 6 h, we assigned all patients with UO less than 0.5 ml/kg/h to KDIGO stage 2 [
32].
Baseline serum creatinine levels were measured in blood samples taken before hospital admission when available. In times the baseline creatinine level or GFR was not available, the lowest serum creatinine level measured during the patient’s hospital stay was used if the GFR was ≥ 75 ml/min/1.73 m2. In other cases, the baseline creatinine level was estimated by using the Modification of Diet in Renal Disease equation with a normal GFR value of 75 ml/min/ 1.73 m
2 [
33].
Severe COVID-19 pneumonia was defined as the combination of: (1) radiological features compatible with this diagnosis; (2) PaO2/Fio2 ratio ≤ 300 mm Hg, and (3) a positive severe acute respiratory syndrome coronavirus-2 test using reverse transcriptase polymerase chain reaction.
Data collection
The following data were collected at admission: age, sex, reason for admission, comorbidities as defined by the Knaus Scale [
30], severity of illness at ICU admission (SAPS II, SOFA scores), main symptoms on admission, organ failures and organ support including vasopressors, renal replacement therapy, invasive mechanical ventilation and other treatments including the use of parenteral or enteral nutrition, vancomycin, aminoglycoside or proton-pump inhibitors and the administration of iodinated contrast media during CT scans.
Outcomes recorded were ICU and hospital LOS, vital status at the end of ICU and hospital stay.
Outcomes and subgroup analyses
Main outcomes were the occurrence of ARC on admission and late ARC and ICU death.
Statistical analyses
The data were described as mean and standard deviation or median and interquartile range for continuous data according to their distribution, and the categorical data as number and percentage. Comparisons relied on the Fisher exact test for categorical data and Wilcoxon test for continuous data.
Missing data were imputed linearly. GFR were first measured using complete data and then linearly imputed. Daily distributions of the missing data are reported in Additional file
1: Table S2.
The cumulative incidence curve over time of the first episode of ARC was plotted.
Univariate and then multivariate logistic regression analysis were performed to determine factors associated with the presence of ARC at admission. Variables achieving a p-value < 0.2 were tested in the multivariate model. Variables were selected by forward–backward analysis to define the final model. Only variables with a p-value < 0.05 were retained in the final model.
The factors associated with the occurrence of ‘late ARC’ were sought by a Fine Gray-type subdistribution survival model, taking death or alive discharge from the ICU as the competing risk. A univariate and then multivariate analysis were conducted in a similar manner with univariate variable selection and forward/backward selection for the final model.
Finally, we reported the cumulative probability of death overtime according to admission status: ARC, No ARC/No AKI; AKI KDIGO 1–2 and AKI KDIGO 3. Subgroup analyses were achieved among the patients with SARS-COV 2 and under anti-microbial therapy.
A logistic regression model evaluating the association between the occurrence of death and the "% of stay with ARC" adjusted to the LOS was performed. As sensitive analyses, cause-specific models with death and being discharged alive from ICU as outcomes considering ARC as a time-dependent covariate during ICU stay were achieved with a landmark approach from Day 2 to Day 7. Sub-distribution survival analyses considering being discharged alive from ICU as competing risk and assessing the effect of ARC on Day 2 among the patients still alive on Day 2, the effect of ARC on Day 3 among the patients still alive on Day 3, and so on until Day 7 were also achieved.
All analyses were performed with SAS software version 9.4 (SAS Institute Inc., Cary, North Carolina) or R software with the "mstate" library.
Discussion
We found a high overall prevalence of ARC at 24.6%, with an increase of the incidence from the admission to Day 6 of ICU stay. The protective factors associated with the occurrence of ARC on admission were young age and low severity on admission. Patients with cardiovascular comorbidities and AKI on admission (KDIGO 3) had less chance of developing ARC during the stay. Finally, ARC and its persistence during the ICU stay was associated with a better patient prognosis.
These results deserve some comments.
First, we found a relatively high prevalence of ARC in ICU, which was already reported [
7], highlighting the need to monitor GFR. However, it is interesting to notice that the prevalence observed in the literature changed with the methods used to estimate GFR. Indeed, studies evaluating GFR using equations based on serum creatinine often found lower prevalence of ARC (less than 10%), because of the underestimation of GFR by these formulas [
29,
34]. In addition, prevalence varies also according to the inclusion criteria of the studies (e.g., exclusion of patients with AKI at admission), or definitions of ARC [
6,
17].
Second, we observed a "rebound" of ARC between Day 5 and Day 7, mostly for the patients with normal renal function or AKI KDIGO 1 or 2. Several studies have already reported this “rebound” effect. Udy et al. showed that 65% of critically ill patients had at least one episode of ARC, and that patients with ARC on admission tended to remain with ARC during their ICU stay. They underlined also that the highest clearance value was most of the time reached at Day 5 [
11]. Fuster-lluch et al. also found that most of the ARC were reached at Day 5 with a 30% prevalence of ARC at Day 5 [
17]. Similar results were found by Brown et al. in a cohort of polytraumatized patients [
4]. The main explanation for this "rebound" effect could be the implementation of compensatory and recovery mechanisms by the organism in response to the administration of fluid therapy and vasopressors to improve cardiac output and renal perfusion [
3]. Our study thus underlines the need to monitor every day renal clearance, with a particular interest for patients without renal failure or with rapidly reversible AKI.
Third, we identified young age and the absence of cardiovascular comorbidities as factors associated with ARC on admission in multivariate analysis. Young age is the main factor associated with ARC in the literature. The combination of a systemic inflammatory response syndrome and a higher renal functional reserve observed in younger patients may explain why these patients have more chance of developing ARC. The absence of cardiovascular comorbidities on admission has not to our knowledge been reported as a factor associated with ARC. Cardiovascular pathologies being associated with a risk of chronic kidney disease, this factor seems logically associated with the absence of ARC. Then, we are the first to report factors associated with secondary ARC occurrence, that is absence of KDIGO 2–3 AKI. This result agrees with the rebound of GFR observed in patients without AKI or with KDIGO 1 AKI, highlighting once again the importance of close monitoring of renal clearance in these patients during the whole ICU stay. Moreover, these results highlight that patients with ARC have a better renal functional reserve explaining also the association found between ARC and young age.
At last, we showed that ARC and its persistence during ICU stay were associated with a better prognosis. Several studies have investigated the association between ARC and poor prognosis and therapeutic failures related to underdosing of antibiotics in ICU. Most of them were negative [
21,
28,
29,
34]. One explanation could be that ARC is also an organ failure recovery marker, and therefore associated with better outcome. Mulder et al. found in their study an association between ARC and a decrease in mortality in a trauma unit, hypothesizing that ARC is a beneficial compensation mechanism for trauma [
35]. However, it is difficult to establish a relationship between prognosis and ARC in the ICU. ARC is both a marker of good renal functional reserve and may be responsible for antibiotic underdosing and thus therapeutic failure. The relationship between ARC and prognosis is therefore complex and deserves to be studied in more detail. In our study, only a part of the patients was admitted for sepsis and received antibiotics at admission. In addition, drug dosing especially antibiotics are adapted according to the estimated glomerular filtration rate. In case of ARC antibiotic dosing is increased. It is therefore very likely that the prognosis observed in relation to ARC is primarily a reflection of the severity of the patients and their young age.
Our study has several limitations. First, it is a retrospective, single-center study, limiting the internal validity of our results. Second, the population is mainly medical patients, with 18.9% of patients of the immunocompromised cohort and a significant proportion of patients hospitalized for SARS-COV-2 pneumonia, which limits the external validity of our results. Third, several variables of interest were not recorded including diuretic use, calory and protein intakes and fluid balance, preventing from time-dependant analyses. Another important issue concerns the GFR measurement technique. CrCl overestimates GFR, due to tubular secretion of creatinine, but remains well correlated with inulin clearance [
36]. Furthermore, collection of urine over 24 h may be difficult, with a risk of urine loss. In this context, some authors suggest measuring GFR over shorter periods [
37,
38]. There is still, however, no clear consensus on the duration of the urine collection period to obtain a more accurate estimate of GFR. Other exogenous markers can also be used to better characterize ARC, in particular the use of iodinated contrast agent. Sangla et al. have found a low precision and an important bias of CrCl compared with plasma iohexol clearance probably due to imprecision in urine collection, sarcopenia and renal secretion of creatinine [
39]. Although there are different techniques for estimating GFR, the calculation of urinary creatinine clearance remains the main technique for assessing GFR in ICU due to its feasibility and low cost. Then, we could not precisely distinguish patient with KDIGO 1 from patient with KDIGO 2 AKI because our database does not track UO at 6 h or 12 h. Lastly, missing data concerning GFR during ICU stay might have biased our results. However, most of the GFR missing were related to missing urinary creatine, with low urinary output and therefore considered with low GFR.
This work opens several perspectives, including studies focusing on patients without AKI or only AKI KDIGO 1 or 2 on admission, i.e., those at risk of ARC. More reliable measurements of GFR by exogenous markers combined with cardiac output, renal perfusion and fluid balance measurements and data on diuretics intakes would allow better characterization of the evolutionary profile of ARC in the ICU. The study of antibiotic dosage in the presence of ARC and the impact of their adaptation would also deserve a prospective work.
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