Effects of paracentesis on hemodynamic parameters and respiratory function in critically ill patients

We retrospectively analyzed a prospectively maintained database of patients undergoing paracentesis and monitored using TPTD (PiCCO®-device; Pulsion Medical Systems SE, Feldkirchen, Germany). The study was approved by the local ethics committee (Ethikkommission der Fakultät für Medizin der Technischen Universität München). Eighty-one paracenteses in 50 patients performed between January 2009 and July 2012 were eligible for the study. To avoid repeated measurements, only the first paracentesis of each patient was included in the analysis. All patients were equipped with hemodynamic monitoring irrespective of the study, and the decision to perform paracentesis was made by the treating ICU physician on clinical grounds independently from the study. Considering a possible impact of paracentesis on hemodynamic parameters as well as on the accuracy of their assessment by pulse contour analysis, re-calibration by TPTD after a major intervention is suggested by the manufacturer and part of clinical routine [23]. The same applies for the documentation of respiratory data before and after paracentesis. Twenty-eight of 50 (56%) patients were mechanically ventilated using pressure support ventilation or pressure control ventilation on the respirator Evita XL (Dräger Medical GmbH, Lübeck, Germany) or SERVO-i (Maquet, Rastatt, Germany). Data on ventilatory parameters (tidal volume (Vt), maximal inspiratory pressure (Pmax), positive end-expiratory pressure (PEEP), and fraction of inspired oxygen (FiO₂)) were recorded. Partial arterial oxygen pressure (PaO₂) and partial arterial carbon dioxide pressure (PaCO₂) were assessed using a fully automatic blood gas analysis system (RAPIDPOINT400, Siemens Healthcare Diagnostics GmbH, Eschborn, Germany). Laboratory, hemodynamic, respiratory parameters, and patients’ characteristics were obtained after analysis of the patients’ medical charts. Cumulative points for lung injury score (LIS) without points for chest roentgenogram and oxygenation ratio (PaO₂/FiO₂) as well as inotropic score ((dopamine dose × 1) + (dobutamine × 1) + (epinephrine dose × 100) + (norepinephrine dose × 100) + (phenylephrine dose × 100)) and vasopressor dependency index (inotropic score/MAP) were calculated [24‐27]. Hemodynamic parameters were available for all 50 patients immediately before and after paracentesis. Two hours after the end of paracentesis, data of 33/50 (66%) patients and 6 hours after paracentesis data of 34/50 (68%) were available. In mechanically ventilated patients, data for dynamic respiratory system compliance (Vt/Pmax-PEEP) and LIS were available immediately before paracentesis for all 28 patients, immediately after for 27/28 (96%). Data were additionally available 2 and 6 hours after the end of paracentesis in 21/28 (75%) and 18/28 (64%) patients, respectively [24].

Total paracentesis (removal of ascites without any volume restriction) was performed with a cannula (16–18 Gauge) connected to a bag without suction in a supine position as described before [28]. TPTD was performed as previously described immediately before and after paracentesis [29, 30]. Albumin substitution was at the discretion of the treating ICU physician [31].

All statistical analyses were performed using IBM SPSS Statistics 20 (SPSS Inc, Chicago, Illinois, USA). Descriptive statistics are presented as mean ± standard deviation for normally distributed data and median, range, and interquartile range (IQR) for non-normally distributed data. Comparisons of hemodynamic and respiratory parameters before and after paracentesis were performed by Wilcoxon signed-rank tests. Bivariate relations were assessed by Spearman’s correlation coefficient and univariate regression analyses. Parameters with a corresponding p-value <0.1 were considered for multivariable linear regression analyses. Stepwise forward variable selection was performed using likelihood ratio tests (inclusion criteria p < 0.05). All statistical tests were 2-sided and performed in an explorative manner on a 5% significance level.

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.

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).

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/cm⁵/m²; 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.

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.

In mechanically ventilated patients, a median baseline LIS of 6 points (IQR 4–7 points) and a median PaO₂/FiO₂ 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, PaO₂/FiO₂ 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 H₂O (p = 0.032) and 4.9 mL/cm H₂O (p = 0.030) immediately and 2 hours after the end of paracentesis, respectively. Likewise to the subgroup of mechanically ventilated patients, PaO₂/FiO₂ 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.

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 PaO₂/FiO₂ (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).

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).

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 × 10⁹/L (IQR, 37–82 × 10⁹/L); Table 1), no major bleeding or other intervention-related complications occurred.

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.