Introduction
Intra-abdominal hypertension (IAH) and abdominal compartment syndrome (ACS) have been associated with organ dysfunction and mortality in critically ill patients [
1,
2]. In terms of organ dysfunction, both intra-abdominal and remote organs are involved. The effects of IAH on cardiovascular, respiratory, and renal functions have all been described in some detail [
3]. Few data are available, however, on the effect of IAH on the liver [
4], partly due to the fact that hepatic blood flow and liver function remain difficult to assess reliably at the bedside [
5]. Liver function is routinely evaluated by plasma concentrations of liver enzymes physiologically restraint to certain cells and subcellular compartments (aspartate aminotransferase (ASAT), alanine aminotransferase (ALAT), lactate dehydrogenase (LDH), gamma-glutamyltranspeptidase (γGT), alkaline phosphatase) and laboratory parameters of liver synthesis (albumin, plasma cholinesterase, glucose, coagulation factors with international normalized ratio (INR)). However, all these tests supply only indirect information on actual liver function.
The plasma disappearance rate of indocyanine green (PDR
ICG) might be an alternative for bedside liver function testing. After injection, indocyanine green (ICG) is distributed via the bloodstream and excreted by hepatocytes into the bile. ICG does not enter enterohepatic recirculation and is excreted completely by the gastrointestinal system. Therefore, elimination of ICG is determined by cardiac output (CO), hepatic blood flow, and hepatocellular uptake [
6]. While excretion into the bile can be impaired, PDR
ICG can be unaffected. PDR
ICG has been shown to be a good surrogate marker for liver function and hepatosplanchnic perfusion [
7‐
11]. Because PDR
ICG is one of very few available markers for hepatic blood flow and function and intra-abdominal pressure (IAP) is an important indicator of a patient's physiologic status, further investigation of a possible interaction was deemed necessary because of the scarce data currently available [
12‐
15]. Therefore, the first aim of the study was to investigate the correlation between PDR
ICG and classic liver parameters. The second aim was to analyze the correlation between IAP, abdominal perfusion pressure (APP), and PDR
ICG as well as between changes in IAP and APP and changes in PDR
ICG, and finally, to determine the best threshold value for IAP, APP, and PDR
ICG as prognostic factors in critically ill patients.
Methods
Patients
The study consists of a retrospective data analysis from measurements obtained in a case series of 40 critically ill patients admitted to the medical ICU of a tertiary hospital (Ziekenhuis Netwerk Antwerpen (ZNA) Stuivenberg General Hospital, Antwerp, Belgium). Disease severity on ICU admission was evaluated using the averaged simplified acute physiology score (SAPS-II), the acute physiology and chronic health evaluation (APACHE-II) score, and the sequential organ failure assessment (SOFA) score. The indication to perform PDRICG was based on the clinical judgement of the attending physician in charge. The study was approved by the local institutional review board without need for informed consent due to the retrospective nature of the analysis.
Measurements and definitions
IAP was measured using either a balloon-tipped stomach catheter connected to an IAP monitor (Spiegelberg, Hamburg, Germany, or CiMON, Pulsion Medical Systems, Munich, Germany) or a FoleyManometer (Holtech Medical, Charlottenlund, Denmark) via the bladder. IAP was measured according to the World Society of the Abdominal Compartment Syndrome (WSACS,
http://www.wsacs.org) guidelines and expressed in mmHg [
16]. APP was calculated as mean arterial pressure (MAP) minus IAP, and IAH was defined as a sustained or repeated pathologic elevation of IAP ≥ 12 mmHg.
The PDRICG was obtained at the bedside using the LiMON device (Pulsion Medical Systems, Munich, Germany) connected to a disposable color sensor at the earlobe or finger obtaining a chromodilution curve of 0.25 mg/kg of ICG solution (in a concentration of 5 mg ICG/ml water) injected via a central venous catheter. In principle, the PDRICG is determined by mono-exponential transformation of the original ICG concentration curve, backward extrapolation to the time 'zero' (100%), and describing the decay as percentage change over time. The normal range of PDRICG is 18% to 25%/min in healthy subjects. Together with PDRICG, the value of residual ICG after 15 min can also be calculated as a percentage.
Classic liver tests (ASAT, ALAT, LDH, γGT, alkaline phosphatase, bilirubin) and so-called liver synthesis tests (albumin, plasma cholinesterase, glucose, and coagulation factors with INR) were performed daily according to routine practice in our institution.
Statistical analysis
Descriptive statistics are presented as mean ± standard deviation (SD) for normally distributed values and as median (with interquartile range) in case of non-normal distribution. Categorical variables were compared using the chi-squared test, while continuous variables were compared using Student's t test or Mann Whitney U test in case of non-normal distribution.
Statistical significance was defined at two-tailed
p value levels of 0.05. Calculations were performed using SPSS software version 17 (SPSS Inc., Chicago, IL, USA). The coefficient of determination (
R2) derived from Pearson's product-moment correlation (
R) was used for measurement of correlation between the mean values of IAP, APP, and PDR
ICG obtained in each patient. Because of repeated measurements in each patient, we used weighted analysis, as described by Bland and Altman [
17,
18] to investigate correlations.
To analyze whether changes in IAP or APP were related to changes or trends in PDRICG, a four-quadrant trend plot was constructed by plotting ΔIAP or ΔAPP against ΔPDRICG at the same time interval by subtracting the first from the last value. The concordance is calculated as the percentage of pairs with the same direction of change. Based on previous reports, the concordance should be >85% to 90%.
Receiver operating characteristics (ROC) curves were calculated (for hospital mortality), and these curves graphically describe the sensitivity of a diagnostic test (true positive proportion) vs. 1 - specificity (true negative proportion) and provide an improved measure of the overall discriminatory power of a test as they assess all possible threshold values. The WSACS recommends that a good area under the ROC (AUROC) curve is at least 0.75; the best threshold needs to be identified with a sensitivity and/or specificity of at least, or close to, 75%.
Primary endpoint was hospital mortality; secondary endpoints were ICU mortality and the development of IAH or a low PDRICG. Outcome analysis and prediction was based on the best threshold identified by AUROC for APP and PDRICG (lowest value) and for IAP (highest value) obtained within the first week of ICU admission for each patient.
Discussion
The data of this retrospective analysis suggest that IAP is inversely correlated with PDRICG. The rationale behind this observation could be that increased IAP leading to decreased APP and a drop in CO can result in compromised splanchnic and thereby hepatic perfusion. As PDRICG is dependent from both hepatocellular function and effective sinusoidal perfusion, this consecutively leads to reduced PDRICG. This is underlined in our study by the good correlation between changes in IAP (and APP) with changes in PDRICG. Rapid changes (within hours) are most likely due to changes in sinusoidal perfusion rather than hepatocellular uptake of the dye. Measuring PDRICG might therefore be a good additional tool to estimate influence of IAH on splanchnic perfusion in the individual patient.
There are very few data on the relationship between IAP and PDR
ICG. So far, Michelet et al. studied this subject prospectively in detail [
13]. In 20 ARDS patients, they looked at the influence of prone positioning on IAP, PDR
ICG, and extravascular lung water compared to the supine position, lying on a conventional foam mattress vs. an air-cushioned mattress. They observed an increase in IAP and a decrease in PDR
ICG in the prone compared with the supine position on a conventional foam mattress. The effect of proning on IAP was the topic of a recent review [
19]. The use of an air-cushioned mattress had beneficial effects on IAP and PDR
ICG during the prone position. Analyzing our data, we found that PDR
ICG correlated significantly with IAP and even more so with APP. Similar to the data of Michelet et al. [
13], changes in IAP were associated with significant concomitant but opposite changes in PDR
ICG, suggesting that an increase in IAP may compromise hepatosplanchnic perfusion. Hering et al., however, did not observe a decrease in PDR
ICG when patients were proned despite the small increase in IAP from 10 to 13 mmHg [
15].
Previous studies have shown that overall mortality increases with lower values of PDR
ICG and that a PDR
ICG threshold >14% is a good predictor of survival [
20,
21]. With respect to survival and using analysis by ROC with AUROC curve as a measure of accuracy, Inal et al. [
10] demonstrated a superior sensitivity and specificity (AUROC = 0.78) of PDR
ICG compared to the APACHE-II score (AUROC = 0.64), SOFA score (AUROC = 0.56), and bilirubin (AUROC = 0.62), while Sakka and Meier-Hellmann [
20] showed a superior sensitivity and specificity to APACHE-II (AUROC = 0.68) and a comparable sensitivity and specificity to SAPS-II (AUROC = 0.76). In a prospective observational study in septic patients, PDR
ICG < 8% predicted mortality with high sensitivity and specificity [
22]. This was confirmed by our data, showing significantly lower values of PDR
ICG in non-survivors. We also noted significantly higher IAP and lower APP values in non-survivors, suggesting that low IAP and high APP may be useful predictors of survival in ICU patients and thus may also be interesting resuscitation endpoints, especially, since we observed that changes in IAP and APP were related to changes in PDR
ICG. In non-survivors, the worst values of IAP, APP, and PDR
ICG occurred later on during the course of the critical illness, suggesting that non-resolution of IAH and sustained poor hepatosplanchnic perfusion eventually may lead to organ dysfunction and increased mortality. More recently, Inal et al. showed in a retrospective analysis of 30 critically ill patients that IAP was significantly higher (21.5 ± 2 mmHg vs. 11.7 ± 1.5 mmHg) and PDR
ICG was significantly lower (10.9 ± 3.4% vs. 24.5 ± 6.8%) in non-survivors compared to survivors [
10].
Our data show no significant correlation between PDR
ICG and conventional liver laboratory tests in mixed ICU patients. Two possible explanations for this observation might be that either PDR
ICG does not reflect liver function at all or PDR
ICG gives additional information on hepatocellular function and hepatosplanchnic perfusion that is not 'detected' by the classic liver function tests. However, due to its unique hepatic elimination, PDR
ICG has been shown to be a good surrogate marker for liver function and hepatosplanchnic perfusion; therefore, the latter explanation seems more likely [
10,
11,
20].
Our study has several limitations. First, the data sample is quite small with only 40 patients studied. Second, the analysis was retrospective, so we could not examine the effects of interventions to lower IAP or to improve APP on values of PDRICG. Third, our results are merely observational, so we cannot exclude other confounding factors and deduct cause and effect from the observed relations. Finally, important data on CO are missing, and this is an important parameter in order to understand and interpret the possible effects of IAP on liver flow (and thus also on PDRICG), since previous studies showed that liver flow correlates well with CO.
Conclusions
In this study, we demonstrated that PDRICG is not correlated with classic liver laboratory tests; hence, it may provide additional information on hepatic blood flow and hepatocellular function. We found a significant correlation between PDRICG and IAP (and APP), suggesting that IAH may impair hepatic blood flow and/or hepatic function as it does also compromise other organ functions. Finally, we found that there were significant differences between survivors and non-survivors regarding IAP, APP, and PDRICG. An IAP below 12 mmHg, a PDRICG above 12%/min, and an APP above 52.5 mmHg were predictive for good outcome. PDRICG might be a good tool to estimate clinical impact of IAH on splanchnic perfusion in selected critically ill patients.
Competing interests
MB and MLNGM are members of the medical advisory board of Pulsion Medical Systems (Munich, Germany), a monitoring company. The other authors declare that they have no competing interests. AK received a study grant from Pulsion Medical Systems.
Authors' contributions
DV, IDL, NVR, KS, HD, and MLNGM planned the study and were responsible for the design, coordination, and drafting the manuscript. AK and MB participated in the study design and helped draft the manuscript. DV and MLNGM performed the statistical analysis and helped draft the manuscript. All authors read and approved the final manuscript.