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REVIEW ARTICLE

An Update on Hepatorenal Syndrome

Samuel Chan
1,2

, Kenneth Au
2,3

, Ross Francis
1
, David W. Mudge

1
, David W. Johnson

1
,

Tony Rahman
3

1Department of Nephrology, Princess Alexandra Hospital, Brisbane, Queensland, Australia; 2Centre for Health Services Research, University
of Queensland, Brisbane, Queensland, Australia; 3Department of Gastroenterology and Hepatology, The Prince Charles Hospital, Chermside,
Queensland, Australia

Abstract

Hepatorenal syndrome (HRS) is one of the many potential causes of acute kidney injury (AKI) in patients with decompensated liver
disease. HRS is associated with poor prognosis and represents the end-stage of a sequence of reductions in renal perfusion induced
by progressively severe hepatic injury. The pathophysiology of HRS is complex with multiple mechanisms interacting simulta-
neously, although HRS is primarily characterised by renal vasoconstriction. A recently revised diagnostic criteria and
management algorithm for AKI has been developed for patients with cirrhosis, allowing physicians to commence treatment
promptly. Vasopressor therapy and other general management, such as antibiotic prophylaxis, need to be initiated whilst patients
are assessed for eligibility for transplantation. Liver transplantation remains the treatment of choice for HRS but is limited by
organ shortage. Other management options, such as transjugular intrahepatic portosystemic shunt, renal replacement therapy
and molecular absorbent recirculating system, may provide short-term benefit for patients not responding to medical therapy
whilst awaiting transplantation. Clinicians need to be aware of the pathophysiology and management principles of HRS to provide
quality care for patients with multi-organ failure.

Keywords: acute kidney injury; hepatorenal syndrome; molecular absorbent recirculating system; renal replacement therapy; transjugular
intrahepatic portosystemic shunt

Received: 17 February 2017; Accepted after revision: 01 March 2017; Published: 22 March 2017.

Author for correspondence: Samuel Chan, Department of Nephrology, Princess Alexandra Hospital, 199 Ipswich Road, Woolloongabba,
Brisbane, Queensland, Australia. Email: samuel.chan@uqconnect.edu.au

How to cite: Chan S et al. An Update on Hepatorenal Syndrome. J Ren Hepat Disord 2017;1(1):55–61.

DOI: http://dx.doi.org/10.15586/jrenhep.2017.12

Copyright: Chan S et al.

License: This open access article is licensed under Creative Commons Attribution 4.0 International (CC BY 4.0).
http://creativecommons.org/licenses/by/4.0

Introduction

Renal failure is common amongst patients with decompen-
sated cirrhosis and is associated with a poor prognosis, with
life expectancy ranging from weeks to months. Hepatorenal
syndrome (HRS) is a functional form of acute kidney injury
(AKI) characterised by renal vasoconstriction. Studies attempt-
ing to develop renal biomarkers to differentiate aetiologies

of AKI have shown promise, but such endeavour remains
in its infancy. There are different approaches to the manage-
ment of HRS, although liver transplantation still shows the
highest survival rates amongst patients with both hepatic
and renal failure (1). This review article will provide an
update on the pathophysiology, diagnostic criteria and treat-
ment options, including prophylaxis, in patients with HRS.

Journal of Renal and Hepatic Disorders 2017; 1(1): 55–61

mailto:samuel.chan@uqconnect.edu.au
http://dx.doi.org/10.15586/jrenhep.2017.12
http://creativecommons.org/licenses/by/4.0


Epidemiology

The incidence and the prevalence of HRS in patients with
advanced liver disease are approximately 7.6% and 13%,
respectively (2). HRS occurs predominantly in portal hyper-
tension associated with cirrhosis, but it has been described
in severe alcoholic hepatitis and fulminant hepatic failure
(3). HRS may occur either spontaneously or may be precipi-
tated by an acute insult, including spontaneous bacterial peri-
tonitis (SBP), non-steroidal anti-inflammatory drugs
(NSAIDs) or upper gastrointestinal bleeding.

Pathophysiology

There are a plethora of simultaneous mechanisms underlying
the pathophysiology of HRS, including arterial vasodilatory
effects, systemic inflammation, bacterial translocation and
hepatorenal reflex (4) (Figure 1). These mechanisms appear
to be mostly functional, as normalisation of kidney function
may be achieved either by pharmacotherapy or by liver
transplantation.

The arterial vasodilation theory

Arterial vasodilation appears to be the most plausible expla-
nation for circulatory dysfunction that occurs in patients with
cirrhosis and ascites (3). This involves two major mechanisms
as follows: firstly, systemic circulatory disturbances and,
secondly, activation of neurohumoral systems. Splanchnic
vasodilatation, resulting from portal hypertension secondary
to cirrhosis, leads to decreased systemic vascular resistance

and subsequent reduction in effective blood volume, which
is clinically mediated by an increased production of nitric
oxide (NO), carbon monoxide and/or endogenous cannabi-
noids (3). In the early stages, the effective arterial blood
volume and arterial pressure are maintained by increased
cardiac output resulting in a hyperdynamic circulation.
In later stages, the progressive splanchnic vasodilatation
results in a decrease in effective arterial blood volume that
can no longer be compensated by cardiac output. Moreover,
the subsequent decrease in cardiac output may be due to
cirrhotic cardiomyopathy, thereby contributing to further
arterial underfilling and worsening of renal function (4).
In order to maintain arterial pressure, systemic vasocon-

strictor systems, such as the renin-angiotensin-aldosterone
system (RAAS), the sympathetic nervous system (SNS) and
the non-osmotic hypersecretion of arginine vasopressin
(AVP), are activated leading to increased plasma renin activ-
ity and increased plasma norepinephrine levels. However, the
activation of neurohumoral systems has harmful impacts on
kidneys. Development of renal sodium and solute-free
water retention leads to ascites and oedema, and hypervole-
mic hyponatremia, respectively. This results in significant
renal vasoconstriction, which leads to a decrease in
glomerular filtration rate and subsequently HRS (5).

Renal factors

Prostaglandins (PGs), specifically PGI2 and PGE2, induce
renal vasodilation, thereby providing renal protective effects
by compensating for the vasoconstrictor systems of RAAS,

Activation of neurohumoral
system (RAAS, SNS, AVP)

Renal vasoconstriction

HRS-AKI

Hyponatremia and ascites

Sodium and water
retention

Neurally mediated
reflex

Activation of
chemoreceptors,

baroreceptors and
osmoreceptors in the liver

↓ Renal blood flow

↓ Effective arterial blood
volume

Splanchnic/systemic
arterial dilatation

Portal hypertension

Cirrhosis

Bacterial translocation

Inflammatory cytokines
(TNF, endotoxins)

Compensatory ↑ cardiac
output

Figure 1. Proposed mechanisms for pathophysiology of hepatorenal syndrome.
AVP, arginine vasopressin; RAAS, renin-angiotensin-aldosterone system; SNS, sympathetic nervous system; TNF, tumour
necrosis factor.

Chan S et al.

Journal of Renal and Hepatic Disorders 2017; 1(1): 55–61 56



SNS and AVP. The levels of renal PGs are increased in
patients with cirrhosis and ascites (6). NSAIDs are a common
cause of kidney failure in patients with cirrhosis (6), illustrat-
ing the probable important role of PG production for main-
taining renal function in patients with cirrhosis.

Cytokines and vasoactive mediators

Systemic inflammation plays a role in the pathophysiology of
HRS. Bacterial translocation has been implicated in the
haemodynamic derangement of cirrhotic patients, thereby
leading to HRS (4). In the clinical setting, increased levels of
pro-inflammatory cytokines, such as tumour necrosis factor
α (TNFα), interleukin-6 (IL-6) and NO, in the splanchnic
area lead to reduced systemic vascular resistance and
increased cardiac output (7).

Hepatorenal reflex

The existence of sensor(s) in the hepatic circulation, which play a
role in regulating extracellular fluid volume, is pathologically sti-
mulated by hepatic haemodynamic irregularities. This may con-
tribute to volume overload and ascites by activating renal
sympathetic nerves to promote salt and water retention (8).

Diagnostic criteria

AKI is a frequent complication in patients with advanced
liver disease, with several potential causes. Recent consensus

guidelines have been published by the International Club of
Ascites (ICA) updating the recommended threshold for diag-
nosing AKI in patients with cirrhosis (Table 1), which now
align with the Kidney Disease Improving Global Outcomes
(KDIGO) AKI classification (2). HRS is a diagnosis of exclu-
sion and should be suspected in patients presenting with
new renal impairment in the setting of cirrhosis with ascites.
Criteria for the diagnosis of HRS were first published by
the ICA in 1996 with subsequent revisions (2, 9), and the cur-
rent recommended criteria are listed in Table 2. A vital step in
evaluating patients with potential HRS is to exclude other
possible causes of AKI.
HRS has traditionally been subdivided into Type 1 or Type

2 disease based on the rate of onset of AKI and prognosis.
Type 1 HRS is characterised by a rapid (less than 2 weeks)
onset of AKI, often precipitated by other events, in particular
SBP. Type 1 HRS is usually associated with a poor prognosis.
Type 2 HRS typically presents with a more insidious onset of
renal impairment over several weeks in patients with cirrhosis
and refractory ascites.
Currently, there are no clinical criteria to reliably distinguish

between HRS and other causes of AKI. This has prompted
researchers to search for biomarkers, such as urinary neutrophil
gelatinase-associated lipocalin (NGAL), with the potential to
aid the differential diagnosis and management of AKI occur-
ring in cirrhotic patients (4). However, these biomarkers are
yet to be validated in large randomised control trials and there-
fore cannot be routinely recommended in clinical practice yet.

Table 1. ICA-AKI new definitions for the diagnosis of AKI in patients with cirrhosis

Subject Definition

Baseline sCr

A value of sCr obtained in the previous 3 months, when
available, can be used as baseline sCr. In patients with more
than one value within the previous 3 months, the value closest
to the admission time to the hospital should be used.

In patients without a previous sCr value, the sCr on admission
should be used as baseline.

Definition of AKI

• Increase in sCr ≥0.3 mg/dl (≥26.5 μmol/L) within 48 h; or
• A percentage increase in sCr ≥50% from baseline that is
known, or presumed, to have occurred within the previous
7 days.

Staging of AKI

• Stage 1: increase in sCr ≥0.3 mg/dl (26.5 μmol/L) or an
increase in sCr ≥1.5-fold to 2-fold from baseline.

• Stage 2: increase in sCr >2-fold to 3-fold from baseline.
• Stage 3: increase of sCr >3-fold from baseline or sCr ≥4.0
mg/dl (353.6 μmol/L) with an acute increase ≥0.3 mg/dl
(26.5 μmol/L) or initiation of renal replacement therapy.

Reproduced with permission from Angeli et al. (2).

AKI, acute kidney injury; ICA, International Club of Ascites; sCr, serum creatinine.

An update on hepatorenal syndrome

Journal of Renal and Hepatic Disorders 2017; 1(1): 55–61 57



Prognosis

Prognosis is poor when patients with cirrhosis develop renal
impairment, and HRS is associated with the worst mortality
rate amongst the different causes of AKI in the setting of
cirrhosis (10). A study in 2005 showed the median survival
times for Type 1 HRS and Type 2 HRS to be 1 month and
6 months, respectively (11). Further prognostic studies with
the newly revised HRS diagnostic criteria will be required.

Management

The ICA has proposed a new algorithm for managing AKI
based on the ICA-AKI criteria, which potentially allows
patients to receive earlier treatment for AKI-HRS (Figure 2)
(2). Due to scarce supply of organs for transplantation,
medical treatments are often initiated first.

Prevention of HRS

In patients with SBP, a meta-analysis of four randomised
trials demonstrated that treatment with antibiotics and albu-
min was associated with a significant reduction in renal
impairment (8% vs. 31%) and mortality (16% vs. 35%) com-
pared with controls (12). Furthermore, another randomised
controlled trial reported that primary prophylaxis with nor-
floxacin reduced the incidence of SBP, delayed the develop-
ment of HRS and improved survival in patients with
cirrhosis, ascites and either advanced liver failure or
impaired renal function (13). The phosphodiesterase inhibi-
tor, pentoxifylline, which has anti-inflammatory properties
through inhibition of leukotriene and TNFα synthesis, was
included in management for prevention of HRS. However,
a recent randomised study demonstrated that pentoxifylline
is not statistically equivalent to the efficacy of prednisolone
in patients with severe alcoholic hepatitis (14).

Vasoconstrictor therapy

Medical treatment for patients with suspected HRS usually
consists of vasopressor and albumin infusion, with the aims
of improving splanchnic arterial circulation and plasma
volume expansion, respectively. Several vasopressor thera-
pies have been trialled in HRS, including terlipressin, norepi-
nephrine and midodrine plus octreotide. Terlipressin is not
licensed for use in the United States nor is it on the Pharma-
ceutical Beneficial Scheme (PBS) in Australia, whilst mido-
drine is only available through Special Assess Scheme
(SAS). A pooled analysis of 501 patients in 21 studies showed
that an increase in mean arterial pressure of at least 5 mmHg
correlated with improvement in renal function regardless of
which vasopressor was used (15).
A systematic review and meta-analysis of randomised

controlled trials of norepinephrine versus terlipressin in
patients with Type 1 HRS found no significant difference in
reversal of HRS, mortality at 30 days or recurrence of HRS
(16). Furthermore, a recent study indicated that the efficacy
of a midodrine plus octreotide regimen might not be as
significant as previous studies suggested (17). In 2015, a
randomised controlled trial of 49 patients comparing terli-
pressin with octreotide/midodrine illustrated a significantly
higher rate of improvement in renal function with terlipressin
(≥50% serum creatinine decrease, 70.4% vs. 28.6%, P = 0.01),
although there was no significant difference in survival
between the two groups (18). Terlipressin is a bridging
option, despite its high cost, to liver transplantation in
patients who are transplant candidates as it may improve
both renal function and short-term survival for patients
awaiting a liver transplant. Further clinical trials will be
required to assess the indication, efficacy and duration of dif-
ferent vasopressors under the new ICA-AKI criteria and
management algorithm.

Table 2. Diagnostic criteria of HRS type of AKI in patients with cirrhosis

HRS – AKI

• Diagnosis of cirrhosis and ascites
• Diagnosis of AKI according to ICA-AKI criteria
• No response after two consecutive days of diuretic withdrawal and plasma volume expansion with albumin 1 g per kg of
body weight

• Absence of shock
• No current or recent use of nephrotoxic drugs (NSAIDs, aminoglycosides, iodinated contrast media, etc.)
• No macroscopic signs of structural kidney injury*, defined as:

○ Absence of proteinuria (>500 mg/day)
○ Absence of microhaematuria (>50 RBCs per high power field)
○ Normal findings on renal ultrasonography

Reproduced with permission from Angeli et al. (2).

AKI, acute kidney injury; HRS, hepatorenal syndrome; ICA, International Club of Ascites; NSAIDs, non-steroidal anti-inflammatory drugs;
RBCs, red blood cells.

*Patients who fulfil these criteria may still have structural damage such as tubular damage.

Chan S et al.

Journal of Renal and Hepatic Disorders 2017; 1(1): 55–61 58



Transjugular intrahepatic portosystemic shunt

Although limited studies have suggested that transjugular
intrahepatic portosystemic shunt (TIPS) may lead to impro-
vement of renal function in a well-selected group of patients
(19), poor prognosis has been associated with patients with
advanced liver disease undergoing TIPS procedure (20). TIPS
aims to reduce portal pressure by inserting an intrahepatic
stent, which shunts portal blood into the systemic circulation,
and in theory may benefit some patients with HRS. However,
many patients with HRS are ineligible for TIPS due to con-
traindications including severe hyperbilirubinaemia or Child-
Pugh class C (e.g., Bilirubin >5 mg/dL, Child-Pugh score >11).
Moreover, the risks associated with TIPS, namely hepatic ence-
phalopathy, liver failure, cardiac failure and renal injury due
to contrast, also need to considered (21).

Extracorporeal support systems

Renal replacement therapy (RRT) has been shown to
improve short-term survival in patients with AKI and may
provide a bridge to liver transplantation for patients with
HRS who are unresponsive to vasopressors and ineligible
for TIPS (22). However, in the absence of an acute reversible
component to the AKI or a plan for liver transplantation,
initiation and/or continuation of RRT should be evaluated
carefully, as these patients have a poor prognosis and are
unlikely to recover with RRT alone (22).

Molecular absorbent recirculating system (MARS)
removes albumin-bound and water-soluble substances,

including NO and TNF, which are involved in pathogenesis
of HRS. MARS has been shown to improve neurological
function and coagulation parameters although a randomised
trial of 189 patients reported no beneficial effect on survival
of MARS therapy in patients with acute or chronic liver
failure (23).

Liver transplantation

The definitive treatment for Type 1 HRS is liver transplan-
tation, as this will reverse both portal hypertension and liver
failure, the two main factors leading to systemic circulatory
disturbances in HRS. A case-control study suggested that
patients with HRS treated with vasopressin before trans-
plantation had similar outcomes compared with patients
transplanted with normal renal function (24). However,
other studies have demonstrated that vasopressors, regard-
less of the agent used, had no significant impact on survival
(1, 25). Simultaneous liver–kidney transplantation is not
necessary for patients with isolated HRS and should only
be considered in selected patients at high risk for non-recov-
ery of renal function, such as patients with heavy proteinuria
and other evidence of advanced primary renal disease.

Conclusion

HRS remains an important and life-threatening complica-
tion for patients with advanced liver disease. Recent
advances in the understanding of the pathophysiology of
HRS have identified potential targets for novel diagnostic

ProgressionStableResolution

Close
follow up

Further treatment of
AKI decided on a case-

by-case basis
Specific treatment for
other AKI phenotypes

Vasoconstrictors and
albumin

No

No

Yes

Yes

Response

Withdrawal of diuretics (if not
withdrawn already) and voulme
expansion with albumin (1g/kg)

for 2 days

Satge 2 and 3 AKI#Satge 1 AKI#

Close monitoring
Remove risk factors (withdrawal of
nephrotoxic drugs, vasodilators and

NSAIDs; decrease/withdrawal of diuretics,
treatment of infections* when diagnosed),

plasma volume expansion in case of
hypovolaemia

Meet criteria for HRS

Figure 2. Proposed algorithm for the management of acute kidney injury in patients with cirrhosis and ascites.
*Treatment of spontaneous bacterial peritonitis should include albumin infusion according to current guidelines.
#Initial AKI stage is defined as AKI stage at the time of first fulfilment of the AKI criteria.
AKI, acute kidney injury; HRS, hepatorenal syndrome; NSAIDs, non-steroidal anti-inflammatory drugs.
Reproduced with permission from Angeli et al. (2).

An update on hepatorenal syndrome

Journal of Renal and Hepatic Disorders 2017; 1(1): 55–61 59



and therapeutic approaches. HRS is now recognised as
HRS–AKI and the diagnostic criteria have recently been
revised. Whilst liver transplantation in appropriate patients
is the only definitive treatment for HRS, vasopressors and
albumin remain the key supportive medical therapy for
HRS-AKI. Novel biomarkers may play a future significant
role in helping clinicians to identify the aetiology of AKI
in patients with cirrhosis.

Conflict of interest

David Johnson has previously received consultancy fees,
research grants, speaker’s honoraria and travel sponsorships
from Baxter Healthcare and Fresenius Medical Care. He
has also received consultancy fees from Astra Zeneca and tra-
vel sponsorship from Amgen. All other authors declare no
conflicts of interest with respect to research, authorship or
publication of this article.

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