Human albumin has been a cornerstone in the management of complications associated with liver cirrhosis for decades. Albumin use spans both evidence-based indications, such as spontaneous bacterial peritonitis, following large-volume paracentesis (LVP), hepatorenal syndrome-acute kidney injury (HRS-AKI) and non-evidence-based indications [1,2]. Terlipressin, a vasopressin analogue, was recently approved in the United States for treating HRS-AKI and is widely used in Europe to treat HRS-AKI and variceal bleeding, but where limited evidence also supports its use in patients with cirrhosis and sepsis-induced hypotension [3,4].

However, two large recent clinical trials have raised concerns about safety for their combined use in hospitalized patients. The ATTIRE trial of daily albumin infusions to target a serum value of ≥30 g/L compared with standard care, found an increased risk of pulmonary edema and fluid overload in patients from the targeted albumin arm [5]. The CONFIRM, phase III trial of terlipressin and albumin compared to albumin alone, had an increased number of respiratory failures in the terlipressin and albumin arm [6]. While CONFIRM protocolized terlipressin use in patients with HRS-AKI, ATTIRE enrolled patients with any acute decompensation of cirrhosis and terlipressin use administered according to the clinician’s decision. As the safety of concomitant human albumin and terlipressin outside HRS-AKI is largely unknown, we aimed to evaluate this using ATTIRE trial data.

In hospitalized patients with decompensated cirrhosis who were treated with terlipressin at their clinician’s discretion, we found concomitant daily human albumin infusions that increased serum albumin to >30 g/L may also have increased the risk of a composite of death and fluid-related complications. Although not statistically significant, this difference in the composite primary outcome seemed to be driven by patients given terlipressin to treat variceal bleeding.

Our findings are consistent with the higher rate of pulmonary edema and fluid overload with targeted albumin infusions from the complete ATTIRE analyses [5]. Overall, pulmonary edema and fluid overload were rare events in ATTIRE, and therefore it was not possible to make specific recommendations to avoid this complication from the trial. CONFIRM also identified an increased risk of respiratory failure, but did not show a clear relationship with the amount of human albumin given in patients with HRS-AKI [6]. This post hoc analysis identified patients treated with terlipressin and targeted albumin infusions as especially prone to fluid overload events. The potential increased risk of the composite of death and fluid-related complications persisted after adjusting for baseline MELD and the presence of ACLF. This observation indicates that the higher rate of death and fluid-related complications was not necessarily a mere reflection of liver disease severity. Given that patients prescribed terlipressin at randomization in ATTIRE made up only 11 % (42 of 380) of the targeted albumin arm but were involved in 30 % (7 of 23) of the fluid overload events, we strongly advocate exercising caution, when administering albumin and terlipressin concomitantly to decompensated cirrhosis patients.

As the indication for terlipressin was not restricted to HRS-AKI, but also included variceal bleed and sepsis-induced hypotension, this study adds important information about the safety of concomitant use of these drugs. Indeed, variceal bleeding was the most common indication for terlipressin. This subgroup of patients was also where we observed the biggest numerical difference in the number of events between the targeted albumin intervention and standard care, although this did not reach statistical significance. As practice guidelines do not recommend use of human albumin as part of fluid resuscitation regimens in patients with cirrhosis and variceal bleed, our findings might be deemed to have limited clinical applicability [10]. However, human albumin use in patients with cirrhosis outside evidence-based indications is common and patients with variceal bleeding frequently develop complications to cirrhosis where albumin is recommended (e.g. spontaneous bacterial peritonitis and renal dysfunction) [2,11] Indeed, in our study the median cumulative amount of albumin administered during hospitalization to patients with variceal bleed was 200 g which is equivalent to 1 L of 20 % human albumin. Importantly, this amount is similar to the guideline recommended dosing for SBP and that given in CONFIRM for patients with HRS-AKI [6,10]. Furthermore, a survey among members of the American Association for the Study of Liver Diseases (AASLD) showed that 9 % would use human albumin in patients with variceal bleeding and 22 % for treating hypoalbuminemia [12]. Though dosing and timing of albumin from the survey was not clear, a retrospective analysis of hospitalized patients with cirrhosis and hyponatremia indeed showed a similar finding where 9 % of patients admitted with variceal bleeding received hypertonic human albumin during admission [13]. Finally, patients with a history of a recent variceal bleed have been excluded from previous albumin trials such as ANSWER [14]. Our study therefore identifies a previously unexplored subgroup where one should exercise caution with the use of albumin.

The fluid overload susceptibility for these patients may be explained by the pharmacodynamics of albumin and terlipressin, together with the hemodynamic changes in patients with decompensated cirrhosis [15]. 20 % human albumin acts as a circulating volume expander by increasing plasma oncotic pressure, while terlipressin is a potent V1-receptor analogue which causes splanchnic vasoconstriction and increases the effective arterial blood volume [16,17]. Decompensated cirrhosis is characterized by altered hemodynamics and cardiac dysfunction [18] and in patients with cirrhosis, a single bolus dose of terlipressin has been shown to suppress systolic cardiac function [19]. The additive, and maybe even synergistic, effects of combined human albumin and terlipressin may therefore unmask a vulnerable hemodynamic system, in which increased pulmonary hydrostatic pressure cannot be relieved, leading to fluid-related complications [16]. We were unable to explore the contributions from other fluid- and transfusion treatments, such as red blood cell transfusion for patients with variceal bleeding, to the development of fluid-related outcomes since this information was not collected as part of ATTIRE. Nevertheless, most patients were randomized into the trial on the day following admission, and so large systematic differences in fluid resuscitation pre-randomization is unlikely. We found no apparent association between terlipressin dosing and development of the composite of death and fluid-related complications. Neither did we observe a statistically significant effect of targeted albumin on 180-day mortality, which suggests that the potential harmful effects of concomitant targeted albumin and terlipressin are observed only in the immediate period after administration.

In our exploratory analyses of predictors for the composite of death and fluid-related complications, baseline levels of WCC, PCT and TNF-α were all positively correlated associated with the outcome. Notably, all three markers reflect inflammatory processes and could suggest the presence of infection. Infections in patients with cirrhosis are common, especially respiratory tract infections for patients with variceal bleeding [20]. Various studies have shown an association between respiratory tract infections and the development of fluid-related complications with albumin in patients cirrhosis. A trial comparing albumin to plasmalyte in patients with cirrhosis and sepsis-induced hypotension (ALPS) found pneumonia and 20 % human albumin administration as independent predictors of pulmonary complications [4]. The INFECIR-2 study testing 20 % human albumin to prevent HRS-AKI and death in non-SBP infected patients with cirrhosis found only diabetes mellitus as a predictor for the development of pulmonary edema [21]. Notably, one-third-of patients in the INFECIR-2 had pneumonia at baseline. Unfortunately, we did not collect data on type and site of infections at hospitalization in ATTIRE, and so we could not explore this association any further. Personalized medicine with human albumin may therefore be an important aspect to limit harm and increase treatment efficacy [22].

Besides baseline WCC, we did not identify any routine clinical variables that were associated with the development of the composite primary outcome when treated with targeted albumin infusions. In CONFIRM for patients with HRS-AKI, baseline INR, oxygen saturation and MAP were all associated with the development of respiratory failure in the intervention group [23]. Our contrasting findings may relate to our lower number of events and the severity of disease, where the median MELD was 19 in the current study and 33 in CONFIRM [6].

Our study has a number of strengths. First, our data derives from the largest trial in patients hospitalized with an acute decompensation of cirrhosis. Secondly, we investigated terlipressin use across the clinical indications of variceal bleeding, HRS-AKI and sepsis-induced hypotension. Finally, our primary composite outcome of death and fluid-related complications is highly clinically relevant.

However, there are also limitations. First, this is a post hoc analysis where findings shall be interpreted as exploratory rather than confirmatory. But since our data shows a potential safety risk rather than an efficacy signal, we believe the findings are important for guiding the clinical management of patients receiving terlipressin. All patients from ATTIRE were enrolled between 2016 and 2019 where they were prescribed terlipressin in boluses as part of their routine clinical care. Hence, we do not have the information on the concomitant use of albumin and terlipressin with continuous infusions which appear to have a more favorable safety profile in the HRS-AKI population [24]. The insertion of a transjugular intrahepatic portosystemic shunt (TIPS) is part of the management in patients with variceal bleeding and is currently being tested in a randomized clinical trial for HRS-AKI [25]. As data on TIPS insertion nor fluid treatment regimens were not collected in ATTIRE, we were unable to control for this in our analyses of patients with variceal bleeding. However, current use of TIPS for variceal bleed is very low in the United Kingdom [26].

In conclusion, we show that targeted albumin infusions may be associated with a composite of mortality and fluid-related complications in patients with cirrhosis receiving terlipressin. The majority of patients were treated with terlipressin for variceal bleeding and albumin infusions should be used with caution in these patients.

Funded by the Health Innovation Challenge fund awarded to AOB (Wellcome Trust and Department of Health and Social Care) HICF reference HICF-R8–439, WT grant number WT102568. The MICROB-PREDICT project has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement No 825,694. AOB was supported by the National Institute for Health and Care Research University College London Hospitals Biomedical Research Centre.

The datasets analyzed during the current study are not publicly available due to data privacy but are available from the corresponding author on reasonable request and subject to approval from the relevant ethical and institutional committees. Any requests for data access will be evaluated on a case-by-case basis to ensure compliance with applicable data protection regulations and ethical standards.

All authors meet the ICMJE criteria for authorship, having each contributed to the conception and design of the study, the acquisition, analysis, or interpretation of data, and the drafting or critical revision of the manuscript; all authors have approved the final version to be published and agree to be accountable for all aspects of the work, ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved.

During the preparation of this work the author(s) used ChatGPT from OpenAI in order to improve language and readability. After using this tool/service, the author(s) reviewed and edited the content as needed and take(s) full responsibility for the content of the publication.