Background
Ascites is a major and frequent complication of liver cirrhosis that is associated with high mortality [
1‐
5]. The first line management of uncomplicated ascites includes dietary salt restriction and diuretics [
6]. However, large or refractory ascites often necessitates paracentesis [
7,
8].
Data on the safety and efficacy of large volume paracentesis (LVP) regarding hemodynamic function are contradictory. On the one hand, some studies suggest that LVP might deteriorate cardiocirculatory function or even induce circulatory failure [
9,
10]. On the other hand, there are data showing that LVP with and without post interventional intravenous albumin substitution does not impair circulatory function and that it is more effective and less associated with complications than diuretic therapy [
11‐
13]. Furthermore, ascites increases intraabdominal pressure and abdominal pressure causes impaired aeration of the lung in mechanically ventilated patients [
14,
15]. A number of studies suggest improved respiratory function after paracentesis [
16‐
21]. However, the vast majority of studies on the subject of paracentesis were not performed in critically ill patients with advanced hemodynamic monitoring or mechanical ventilation.
As critically ill patients are often in a hemodynamical unstable situation, LVP is likely to influence hemodynamics in these patients more than in non-ICU (intensive care unit) patients. Furthermore, estimation of volume status based on physical examination in critically ill patients is difficult [
22]. This problem might be even more pronounced in patients with ascites. Therefore, advanced hemodynamic monitoring might help to accurately assess the fluid status and hemodynamic changes particularly in critically ill patients with ascites.
Therefore, the purpose of our study was to evaluate potential effects of paracentesis on hemodynamic parameters and respiratory function in ICU patients monitored using transpulmonary thermodilution (TPTD).
Results
Patients’ characteristics are shown in Table
1.
Table 1
Patients’ characteristics
Male sex, n/total (%) | 27/50 (54%) |
Age, years | 58 ± 10 |
Body height, cm | 171 ± 8 |
Body weight, kg | 78 ± 18 |
Scores
| |
SAPS II | 42 ± 13 |
TISS | 19 ± 7 |
APACHE II | 20; 10–40; 17-27 |
Pre-existing medical conditions
| |
Cirrhosis of the liver, n/total (%) | 44/50 (88%) |
Cirrhosis due to alcohol, n/total (%) | 38/44 (86%) |
Cirrhosis due to hepatitis, n/total (%) | 4/44 (9%) |
Cirrhosis due to unknown reason, n/total (%) | 2/44 (5%) |
Outcome
| |
ICU mortality, n/total (%) | 26/50 (52) |
Hospital mortality, n/total (%) | 33/50 (66) |
Intervention related data
| |
Amount of ascites removed, L | 5.99; 0.49-17.06; 3.33-7.68 |
Duration of paracentesis, minutes | 130; 45–300; 100-173 |
Speed of paracentesis, mL/minutes | 44; 4–122; 28-61 |
Laboratory data
| |
International normalized ratio (INR) | 1.8; 1.1-4.1; 1.4-2.6 |
Partial thromboplastin time (PTT), seconds | 57; 31–132; 45-75 |
Thrombocytes, ×109/L | 58; 19–359; 37-82 |
Bilirubin, mg/dL | 4.7; 0.6-52.0; 2.0-13.7 |
Paracentesis
Fifty paracenteses in 50 patients were analyzed. The median amount of ascites removed was 5.99 L (range, 0.49-17.06; IQR 3.33 - 7.68 L). Within the 6 hours follow up after paracentesis, a median amount of 100 mL (range, 0–500 mL; IQR, 0–200 mL) of 20% human albumin and a median volume of 350 mL (range, 0–830 mL; IQR, 203–565 mL) crystalloid infusions were administered.
Serum and ascites protein levels
The serum protein values within 72 hours before (median, 5.2 g/dL; range, 3.8-7.1 g/dL; IQR, 4.8-5.9 g/dL) and 72 hours after (median, 5.4 g/dL; range, 3.7-6.6 g/dL; IQR, 4.5-5.7 g/dL) paracentesis were available in 34/50 (68%) patients. The difference was statistically not significant (p = 0.068). Data for calculating the serum ascites protein gradient (SAPG) were available for 39/50 (78%) patients. Median SAPG was 4.1 (range, 2.5-6.5; IQR, 3.3-4.8).
Hemodynamics
Compared to baseline values, there were no statistically significant changes in hemodynamic parameters immediately, 2 hours and 6 hours after paracentesis except decrease of mean arterial pressure (MAP, -7 mm Hg; p = 0.041) and systemic vascular resistance index (SVRI, -116 dyne·sec/cm
5/m
2; p = 0.016) when measured 2 hours after paracentesis. Hemodynamic parameters before paracentesis as well as immediately, 2 hours, and 6 hours after the end of paracentesis are shown in Table
2.
Table 2
Hemodynamic data before and after paracentesis
Heart rate, beats per minute | 88 (79–101) | 88 (80–100) | 0.340 | 91 (81–99) | 0.152 | 90 (85–99) | 0.530 |
MAP, mmHg | 84 (76–93) | 79 (73–88) | 0.060 | 77 (71–90) | 0.041* | 80 (71–89) | 0.213 |
CI, L/min/m2
| 4.6 (3.7-5.4) | 4.6 (3.6-5.6) | 0.211 | 4.7 (3.7-5.7) | 0.304 | 4.9 (3.8-5.7) | 0.402 |
GEDVI, mL/m2
| 817 (697–909) | 820 (713–941) | 0.787 | 784 (711–900) | 0.943 | 792 (685–861) | 0.669 |
SVRI, dyne·sec/cm5/m2
| 1163 (883–1606) | 1120 (869–1443) | 0.118 | 1047 (882–1370) | 0.016* | 1116 (877–1406) | 0.270 |
EVLWI, mL/m2
| 10 (7–12) | 10 (8–12) | 0.442 | 10 (8–13) | 0.129 | 10 (8–12) | 0.338 |
Norepinephrine dose, μg/h | 0.0 (0.0-300.0) | 0.0 (0.0-325.0) | 0.812 | 0.0 (0.0-375.0) | 0.979 | 0.0 (0.0-238.0) | 0.905 |
Subgroup analysis including only mechanically ventilated patients did not reveal statistically significant or clinically relevant paracentesis-induced changes in hemodynamic parameters.
Vasopressor dependency index for all patients (median before paracentesis 0.0; IQR 0.0-374.1) did not change statistically significantly when measured immediately (median, 0.0; IQR, 0.0-343.4; p = 0.876), 2 hours (median, 0.0; IQR, 0.0-493.8; p = 0.650), and 6 hours (median, 0.0; IQR, 0.0-288.2; p = 0.711) after paracentesis. Subgroup analysis including only mechanically ventilated patients revealed similar results with a median vasopressor dependency index before paracentesis of 243.9 (IQR 0.0-735.3) and no statistically significant changes immediately (median, 253.2; IQR, 0.0-735.3; p = 0.679), 2 hours (median, 241.0; IQR, 0.0-762.3; p = 0.701), and 6 hours (median, 142.9; IQR, 0.0-709.7; p = 0.776) after paracentesis.
Subgroup analysis of patients undergoing paracentesis of more than 5 liters (n = 32) and more than 10 liters (n = 6) did not show any additional statistically significant changes in circulatory or TPTD derived parameters at any timepoint measured.
Respiratory function
In mechanically ventilated patients, a median baseline LIS of 6 points (IQR 4–7 points) and a median PaO
2/FiO
2 of 220 mmHg (IQR 161–329 mmHg) indicated severe respiratory dysfunction. In these patients, respiratory function markedly improved following paracentesis. Compared with the baseline values before paracentesis, LIS significantly improved immediately (-1 point; p < 0.001), 2 hours (-1 point; p = 0.003) and 6 hours (±0 points; p = 0.012) after paracentesis (Table
3). Similarly, PaO
2/FiO
2 significantly improved immediately (+54 mmHg; p < 0.001) and 2 hours (+24 mmHg; p = 0.001) after paracentesis. Furthermore, compliance significantly increased by 5.5 mL/cm H
2O (p = 0.032) and 4.9 mL/cm H
2O (p = 0.030) immediately and 2 hours after the end of paracentesis, respectively. Likewise to the subgroup of mechanically ventilated patients, PaO
2/FiO
2 statistically significantly increased also for all patients. Table
3 shows baseline respiratory parameters as well as values obtained immediately, 2 hours, and 6 hours after the end of paracentesis.
Table 3
Respiratory parameters before and after paracentesis
PaO2, mmHg | 82.5 (72.9-98.6) | 90.1 (82.5-110.0) | 0.001* | 91.6 (76.1-103.2) | 0.044* | 87.9 (74.5-94.8) | 0.645 |
PaCO2, mmHg | 39.0 (31.0-51.3) | 40.3 (31.6-45.3) | 0.156 | 40.4 (31.7-48.6) | 0.665 | 40.7 (32.0-47.8) | 0.486 |
PaO2/FiO2, mmHg | 220 (161–329) | 278 (195–390) | 0.001* | 229 (167–354) | 0.004* | 226 (162–327) | 0.050 |
FiO2, % (mechanically ventilated patients) | 48 (40–64) | 45 (35–60) | 0.016* | 45 (38–53) | 0.004* | 45 (40–55) | 0.007* |
PaO2/FiO2, mmHg (mechanically ventilated patients) | 188 (136–233) | 242 (184–284) | <0.001* | 212 (163–266) | 0.001* | 201 (152–274) | 0.078 |
Vt/(Pmax-PEEP), mL/cmH2O (mechanically ventilated patients) | 30.1 (21.2-57.6) | 35.6 (24.8-60.0) | 0.032* | 35.0 (23.8-61.1) | 0.030* | 35.6 (28.6-55.5) | 0.062 |
Lung injury score (without x-ray) (mechanically ventilated patients) | 6 (4–7) | 5 (4–6) | <0.001* | 5 (4–7) | 0.003* | 6 (4–6) | 0.012* |
In univariate analysis including only mechanically ventilated patients, the amount of ascites removed (p = 0.013) and the parameters LIS before paracentesis (p = 0.004) and baseline PaO
2/FiO
2 (p = 0.012) were statistically significantly associated with paracentesis-induced changes in LIS when determined immediately after paracentesis. No statistically significant association was seen for simplified acute physiology score II (SAPS II) (p = 0.846), therapeutic intervention scoring system (TISS) (p = 0.950), dynamic respiratory system compliance before paracentesis (p = 0.350), and model for end-stage liver disease (MELD) score (p = 0.704). Subsequent multivariate linear regression analysis including the factors univariately associated confirmed LIS before paracentesis (p = 0.003) and amount of ascites removed (p = 0.009) as independent factors regarding improvement of LIS immediately after paracentesis compared with baseline values (Table
4).
Table 4
Factors associated with changes of LIS immediately before and after paracentesis in mechanically ventilated patients
Amount of ascites removed | 0.026 | -0.170 | 0.470 | 0.013* | 1.517 | -0.154 | 0.009* |
LIS before paracentesis | 0.638 | -0.298 | 0.537 | 0.004* | -0.277 | 0.003* |
PaO2/FiO2
| -2.549 | 0.008 | 0.476 | 0.012* | | |
SAPS II | -1.254 | 0.004 | 0.039 | 0.846 | | |
TISS | -1.123 | 0.002 | 0.013 | 0.950 | | |
Lung compliance | -1.258 | 0.004 | 0.187 | 0.350 | | |
MELD score | -0.804 | -0.010 | 0.077 | 0.704 | | | |
Renal function
Despite a median negative 24-hour fluid balance on the day of intervention of -4.2 L (IQR, -6.0 L to -1.8 L), the median 24-hour urine output on the day after paracentesis (median, 800 mL; IQR, 250–1850 mL) was significantly higher (+200 mL; p = 0.015) when compared with the day before the intervention (median, 600 mL; IQR, 200–1300 mL).
Complications
Despite a marked general risk profile of the patients population in our study (mean SAPS II on the day of intervention 42 ± 13 points) and impaired blood coagulation tests (median INR 1.8 (IQR 1.4-2.6), median partial thromboplastin time 57 seconds (IQR, 45–75 seconds), median platelet count 58 × 10
9/L (IQR, 37–82 × 10
9/L); Table
1), no major bleeding or other intervention-related complications occurred.
Discussion
In this trial we analyzed the effects of paracentesis on hemodynamic parameters and respiratory function in critically ill patients.
According to the results of our study, no relevant impairment of circulatory function was observed whereas renal function in terms of urine output improved following removal of ascites. Furthermore, paracentesis is related to immediate and sustained improvement of respiratory function. The median oxygenation ratio of all patients increased, whereas PaCO2 remained stable after paracentesis.
Patients with tense ascites often display signs of circulatory dysfunction [
32]. Portal hypertension leads to vasodilatation of splanchnic vessels, leading to decreased peripheral resistance, decreased effective central blood volume with consequent arterial hypotension and hyperdynamic circulation. These changes finally result in activation of vasoconstrictor systems, the renin-angiotensin-aldosteron system (RAAS) and the sympathetic nervous system, as well as increased levels of antidiuretic hormone, water retention and renal vasoconstriction, possibly ending in renal failure [
33‐
35]. Infusion of albumin is recommended by the American Association for the Study of Liver Diseases (AASLD) for large volume paracentesis (> 5 Liter), because intravenously administered albumin increases the effective arterial blood volume and improves serum sodium concentrations in patients with cirrhosis and severe hyponatremia [
36‐
40]. However, albumin does not interfere with the main mechanisms of ascites formation and therefore only prevents complications of paracentesis rather than prevents the recurrence of ascites [
10].
Regarding hemodynamic parameters, paracentesis did neither result in an immediate nor in a delayed cardiocirculatory impairment. No statistically significant changes in arterial blood pressure, heart rate, or TPTD-derived parameters such as cardiac index (CI), global end diastolic volume index (GEDVI), and extra vascular lung water index (EVLWI) were observed after paracentesis. This is partly in contrast to some previous studies demonstrating a paracentesis-related deterioration of cardiac function and might be explained by the fact that volume resuscitation was guided using advanced hemodynamic monitoring in the patients included in our study during their ICU stay. This might have resulted in an optimized baseline (pre-paracentesis) hemodynamic and intravascular volume status in our patients indicated by normal baseline values for MAP, CI, and GEDVI assessed using advanced hemodynamic monitoring [
9,
41‐
43]. Two hours after the intervention, MAP and SVRI were statistically significantly lower compared with the values before the intervention. However, 6 hours after the end of paracentesis, there was no statistically significant difference in MAP and SVRI compared with baseline values anymore. These paracentesis-related hemodynamic changes (decreased SVRI, unchanged GEDVI) two hours after the end of paracentesis are most likely due to a reduction of cardiac afterload as a consequence of a paracentesis-induced lower intraabdominal pressure [
28]. In addition, the reduction of SVRI after paracentesis might be explained by the substitution of albumin following paracentesis. A significant reduction of SVRI after plasma-expansion with hyperoncotic albumin in cirrhotic patients with renal failure has been described before [
34,
43]. However, Cabrera et al. observed no decrease of SVRI when removing ascites but maintaining the intraabdominal pressure at its original level in an experimental setting using a pneumatic girdle. Only after decrease of intraabdominal pressure, SVRI also decreased [
44]. Since application rates of vasoactive drugs and the vasopressor dependency index were not significantly different before and after paracentesis, the decrease in SVRI in our study cannot be explained by a lower application rate of vasopressors following paracentesis. Based on the considerations mentioned before, the decrease in SVRI observed following removal of ascites is most likely caused by a paracentesis-related reduction of intraabdominal pressure [
28,
45]. Unfortunately, documentation of intraabdominal pressure before and after paracentesis is not routinely performed in our ICU and was therefore not available for data analysis.
Given the fact, that all hemodynamic parameters were stable 6 hours after the end of paracentesis and that vasopressor dependency index did not change statistically significantly, LVP seems to be a safe procedure regarding circulatory function.
Regarding the positive impact of paracentesis on respiratory function, an improvement of oxygenation (while PaCO
2 remained unchanged) was also observed in a previous study [
18]. These positive effects regarding respiratory function are most likely due to improved respiratory mechanics as a consequence of a paracentesis-induced reduction of intraabdominal pressure [
18,
21,
46]. The fact that paracentesis caused a significant improvement of dynamic respiratory system compliance in mechanically ventilated patients is also indicative for a decreased intraabdominal pressure following paracentesis. These findings are in accordance with the results from a recent study by Levesque and colleagues in 31 mechanically ventilated cirrhotic patients demonstrating a significant decrease in intraabdominal pressure, improvement of oxygenation, and an increase in end-expiratory lung volume after LVP [
21]. The improvement of dynamic respiratory system compliance, LIS, and PaO
2/FiO
2 in mechanically ventilated patients demonstrates the possibility to reduce ventilator associated lung injury by removal of ascites in these patients.
The median urine output on the day after paracentesis was significantly higher compared with the day before the intervention. This indicates, as described before by our group and others, that paracentesis might help to improve renal function [
43,
47]. The increase of urine output on the day after paracentesis despite a negative fluid balance on the day of paracentesis indicates that the reduction of intraabdominal pressure – besides possible humoral effects – is causative for the improvement of renal function [
48].
Limitations of the study
There are several limitations of our study that need to be mentioned. In general, since we studied a limited number of paracenteses in a monocentric study, the results of our study need to be interpreted with caution. Especially the number of patients on mechanical ventilation is relatively low in our study. In addition, documentation of intraabdominal pressure before and after paracentesis is not routinely performed and therefore not available for data analysis. Finally, albumin substitution after paracentesis was at the discretion of the treating ICU physician and was not performed strictly adhering to international guidelines.
Competing interests
Wolfgang Huber and Bernd Saugel collaborate with Pulsion Medical Systems SE (Feldkirchen, Germany) as members of the medical advisory board. All other authors have no conflict of interest. No financial support was obtained for the study.
Authors’ contributions
VP, BS and WH contributed to the conception and design of the study. VP, BS, CE, CS, PT and UM were responsible for acquisition, analysis and interpretation of data. VP and WH drafted the manuscript. RMS and BS participated in study design and coordination and helped to draft the manuscript. AH participated in the design of the study and performed the statistical analysis. All authors read and approved the final manuscript.