Abbreviations
ACLD:
advanced chronic liver disease
AE:
adverse event
BMI:
body mass index
BRTO:
balloon-occluded retrograde transvenous obliteration
BSG:
British Society of Gastroenterology
DOAC:
direct oral anticoagulant
EBL:
endoscopic band ligation
EGD:
esophagogastroduodenoscopy
EGVH:
esophagogastric variceal hemorrhage
ESGE:
European Society of Gastrointestinal Endoscopy
EUS:
endoscopic ultrasound
EVH:
esophageal variceal hemorrhage
FFP:
fresh frozen plasma
GI:
gastrointestinal
GRADE:
Grading of Recommendations, Assessment, Development and Evaluation
GVH:
gastric variceal hemorrhage
HVPG:
hepatic venous pressure gradient
INR:
international normalized ratio
NSBB:
nonselective beta blocker
PCC:
prothrombin complex concentrate
PPI:
proton pump inhibitor
OR:
odds ratio
RBC:
red blood cell
RCT:
randomized controlled trial
RR:
relative risk or risk ratio
SEMS:
self-expanding metal stent
SHR:
summary hazard ratio
TIPS:
transjugular intrahepatic portosystemic shunt
UGIH:
upper gastrointestinal hemorrhage
VCE:
video capsule endoscopy
TEG:
thromboelastography
This Guideline is an official statement of the European Society of Gastrointestinal
Endoscopy (ESGE) and addresses the role of gastrointestinal endoscopy in the diagnosis
and management of esophagogastric variceal hemorrhage.
1 Introduction
Portal hypertension caused by increased sinusoidal (i. e. advanced chronic liver disease
[ACLD]), presinusoidal (i. e. schistosomiasis, portal vein thrombosis), or post-sinusoidal
(i. e. Budd–Chiari syndrome) pressure can lead to significant complications including
esophagogastric variceal hemorrhage (EGVH). EGVH is a medical emergency that requires
urgent evaluation and management. This ESGE Guideline provides evidence-based guidance
on EGVH including screening/primary prophylaxis (preventing a first variceal hemorrhage),
management of an acute bleeding episode, and guidance on secondary prophylaxis (preventing
recurrent EGVH) in patients with ACLD.
2 Methods
The ESGE commissioned this Guideline (ESGE Guideline Committee chair, K.T.) and appointed
a guideline leader (I.M.G.). The guideline leader (I.M.G.) established six task forces,
each with its own leader (J.C.G.-P., M.C.D., L.F., T.H., J.G.K., and I.J.). Key questions
were prepared by the coordinating team (I.M.G., J.C.G.-P., M.C.D., L.F., T.H., J.G.K.,
and I.J.) and divided amongst the six task forces (Appendix 1 s , see online-only Supplementary material).
A professional health sciences librarian (R.R.) performed a structured systematic
literature search using keywords of English-language articles limited from 1 January
2000 to 30 September 2021, in Ovid MEDLINE, Embase (Elsevier), the Cochrane Database
of Systematic Reviews (CDSR), and Cochrane Center Register of Controlled Trials (CENTRAL).
Free-text keywords, MeSH terms, and other database-specific controlled vocabulary
were searched; terms included esophageal/oesophageal varices, gastric varices, gastrointestinal,
hemorrhage/haemorrhage, bleeding, and other related words (Appendix 2 s ). The hierarchy of studies included in this evidence-based guideline was, in decreasing
order of evidence level: published systematic reviews/meta-analyses, randomized controlled
trials (RCTs), prospective and retrospective observational studies, and case series.
Evidence on each key question was summarized in tables, using the Grading of Recommendations
Assessment, Development and Evaluation (GRADE) system [1 ] (Table 1 s ). Grading of the evidence depends on the balance between the benefits and risk or
burden of any health intervention. Further details on ESGE guideline development have
been previously reported [2 ].
The results of the literature search and answers to the PICO (patient, intervention,
comparator, outcome) questions were presented to all guideline group members during
two online face-to-face meetings conducted on 18 and 19 February 2022. Subsequently,
drafts were written by each task force leader and distributed between the task force
members for revision and online discussion. In June 2022, a draft prepared by the
guideline leader and the six task force leaders was sent to all guideline group members.
After the agreement of all members had been obtained, the manuscript was reviewed
by two independent external reviewers. The manuscript was then sent for further comments
to the 51 ESGE member societies and individual members. It was subsequently submitted
to the journal Endoscopy for publication. The final revised manuscript was agreed upon by all the authors.
This ESGE Guideline was issued in 2022 and will be considered for update in 2027.
Any interim updates will be noted on the ESGE website: http://www.esge.com/esge-guidelines.html .
The evidence statements and recommendations in this Guideline have in general been
grouped according to the different task force topics (Appendix 1 s ). Each statement is followed by the strength of evidence based on the GRADE system
and the discussion/consensus of the evidence that occurred during the two 4-hour online
meetings. All recommendations in this guideline are summarized in [Table 1 ]. The definitions used throughout the guideline are shown in [Table 2 ].
Table 1
Summary of recommendations made in this Guideline.
Endoscopic screening for high risk esophagogastric varices and primary prophylaxis
for EGVH
ESGE recommends that, for patients with compensated ACLD and liver stiffness measurement
< 20 kPa and platelet count ≥ 150 × 109 /L, screening upper GI endoscopy can be avoided since these patients are thought to
have a low probability for having high risk varices
ESGE recommends that patients with decompensated ACLD (liver stiffness measurement
by transient elastography ≥ 20 kPa or platelet count ≤ 150 × 109 /L) should be screened by upper GI endoscopy to identify high risk esophagogastric
varices (esophageal varices that are medium or large in size; or small-sized esophageal
varices with red wale markings)
ESGE recommends that patients with compensated ACLD, but with liver stiffness measurement
by transient elastography ≥ 20 kPa or platelet count ≤ 150 × 109 /L who are not receiving NSBB therapy, should be screened by upper GI endoscopy to
identify high risk esophagogastric varices (esophageal varices that are medium or
large in size; or small-sized esophageal varices with red wale markings)
ESGE recommends that esophageal varices be documented in the endoscopy report according
to the Baveno criteria as small, medium, or large varices, with or without the presence
of red wale markings
ESGE recommends that gastric varices be documented in the endoscopy report according
to the Sarin classification
ESGE does not recommend VCE for screening of esophageal varices
ESGE recommends that patients with compensated ACLD (due to viruses, alcohol, and/or
nonobese [BMI < 30 kg/m2 ] nonalcoholic steatohepatitis) and clinically significant portal hypertension (HVPG
> 10 mmHg and/or liver stiffness by transient elastography > 25 kPa) should receive,
if no contraindications, NSBB therapy (preferably carvedilol) to prevent the development
of variceal bleeding
ESGE recommends that, in those patients who are unable to receive NSBB therapy with
a screening upper GI endoscopy that demonstrates high risk esophagogastric varices,
prophylactic endoscopic treatment should be performed
ESGE recommends that, in those patients unable to receive NSBB therapy with a screening
upper GI endoscopy that demonstrates high risk esophageal varices, EBL is the endoscopic
prophylactic treatment of choice. EBL should be repeated every 2–4 weeks until variceal
eradication is achieved. Thereafter, surveillance EGD should be performed every 3–6
months in the first year following eradication
ESGE suggests that, in those patients unable to receive NSBB therapy with a screening
upper GI endoscopy that demonstrates gastric varices (Sarin GOV-2 or IGV-1), no treatment,
cyanoacrylate injection alone, or EUS-guided coil plus cyanoacrylate injection can
be considered. EUS-guided injection therapy should be decided on a case-by-case basis
and limited to centers with expertise in this endoscopic technique
ESGE recommends that, in those patients unable to receive NSBB therapy with a screening
upper GI endoscopy that does not demonstrate high risk varices, surveillance endoscopy
should be performed every 2 years if there is ongoing active liver disease or every
3 years if the underlying liver disease is quiescent
Pre-endoscopy management of acute EGVH
ESGE recommends urgent assessment of the hemodynamic status in patients presenting
with suspected acute EGVH
ESGE recommends prompt, yet careful, intravascular volume replacement, initially using
crystalloid fluids, if hemodynamic instability exists, to restore tissue perfusion
while avoiding intravascular volume overexpansion
ESGE does not recommend the transfusion of FFP as part of the initial management of
EGVH
ESGE does not recommend the use of recombinant factor VIIa as part of the initial
management of EGVH
ESGE suggests endotracheal intubation prior to upper GI endoscopy in patients with
suspected variceal hemorrhage and ongoing hematemesis, encephalopathy, and/or with
agitation and inability to control their airway to protect against the potential aspiration
of gastric contents
ESGE recommends that, if prophylactic endotracheal intubation is performed, extubation
should occur as soon as clinically safe following upper GI endoscopy
ESGE does not recommend routine platelet transfusion or a specific minimum platelet
count threshold for triggering platelet transfusion. If variceal bleeding is not controlled,
the decision to transfuse platelets should be made on a case-by-case basis
ESGE recommends, in hemodynamically stable patients with acute UGIH and no history
of cardiovascular disease, a restrictive RBC transfusion strategy, with a hemoglobin
threshold of ≤ 70 g/L prompting RBC transfusion. A post-transfusion target hemoglobin
of 70–90 g/L is desired
ESGE recommends, in hemodynamically stable patients with acute UGIH and a history
of acute or chronic cardiovascular disease, a more liberal RBC transfusion strategy
with a hemoglobin threshold of ≤ 80 g/L prompting RBC transfusion
ESGE recommends that patients with ACLD presenting with suspected acute variceal bleeding
be risk stratified according to the Child–Pugh score and MELD score, and by documentation
of active/inactive bleeding at the time of upper GI endoscopy
ESGE recommends the following risk stratification definitions:
ESGE recommends the vasoactive agents terlipressin, octreotide, or somatostatin be
initiated at the time of presentation in patients with suspected acute variceal bleeding
and be continued for a duration of up to 5 days
Strong recommendation, high quality evidence
ESGE suggests, following successful endoscopic hemostasis, vasoactive agents may be
stopped 24–48 hours later in selected patients
ESGE recommends antibiotic prophylaxis using ceftriaxone 1 g/day for up to 7 days
for all patients with ACLD presenting with acute variceal hemorrhage, or in accordance
with local antibiotic resistance and patient allergies
ESGE recommends that antiplatelet agents be temporarily withheld in patients presenting
with acute variceal hemorrhage
ESGE recommends that the restarting of antiplatelet agents be determined on the basis
of the patient’s risk of rebleeding versus their risk of thrombosis
ESGE recommends that anticoagulants be temporarily withheld in patients presenting
with suspected acute variceal hemorrhage and appropriate reversal agents be used in
patients with hemodynamic instability
ESGE recommends that the restarting of anticoagulants should be guided by the patient’s
risk of rebleeding versus their risk of thrombosis
ESGE recommends, in the absence of contraindications, intravenous erythromycin 250 mg
be given 30–120 minutes prior to upper GI endoscopy in patients with suspected acute
variceal hemorrhage
Endoscopic management of EGVH
ESGE recommends that, in patients with suspected variceal hemorrhage, endoscopic evaluation
should take place within 12 hours from the time of patient presentation, provided
the patient has been hemodynamically resuscitated
ESGE recommends that the timing of upper GI endoscopy in patients with suspected acute
variceal hemorrhage should not be influenced by the INR level at the time of patient
presentation
ESGE recommends EBL for the treatment of acute EVH
ESGE does not recommend the use of hemostatic sprays/powders for the definitive endoscopic
treatment of acute esophageal or gastric variceal hemorrhage. Hemostatic sprays/powders
may be considered as a bridge to definitive therapy when standard endoscopic treatment
is not effective or is not available
ESGE recommends that, in patients at high risk for recurrent esophageal variceal bleeding
following successful endoscopic hemostasis (Child–Pugh C ≤ 13 or Child–Pugh B > 7
with active EVH at the time of endoscopy despite vasoactive agents, or HVPG > 20 mmHg),
pre-emptive TIPS within 72 hours (preferably within 24 hours) must be considered
ESGE recommends that, for persistent esophageal variceal bleeding despite vasoactive
pharmacological and endoscopic hemostasis therapy, urgent rescue TIPS should be considered
(where available)
ESGE suggests that, for persistent esophageal variceal bleeding despite vasoactive
pharmacological and endoscopic hemostasis therapy, self-expandable metal stents (where
available) are preferred over balloon tamponade for bridging to definitive hemostasis
therapy
ESGE suggests that recurrent EVH in the first 5 days following successful initial
endoscopic hemostasis be managed by a second attempt at endoscopic therapy or salvage
TIPS
ESGE recommends classifying gastric or gastroesophageal varices according to the Sarin
classification
ESGE recommends endoscopic cyanoacrylate injection for acute gastric (cardiofundal)
variceal (GOV2, IGV1) hemorrhage
ESGE makes no formal recommendation regarding the use of endoscopic thrombin injection
in acute gastric (cardiofundal) variceal (GOV2, IGV1) hemorrhage because of the currently
limited and disparate data
ESGE recommends endoscopic cyanoacrylate injection or EBL in patients with GOV1-specific
bleeding
ESGE suggests that EUS-guided management of bleeding gastric varices combining injection
of coils and cyanoacrylate may be used in centers with expertise and familiarity with
this technique
ESGE suggests urgent rescue TIPS or BRTO for gastric variceal bleeding when there
is a failure of endoscopic hemostasis or early recurrent bleeding
Post-endoscopy management of EGVH
ESGE recommends that patients who have undergone EBL for acute EVH should be scheduled
for follow-up EBLs at 1- to 4-weekly intervals to eradicate esophageal varices (secondary
prophylaxis)
ESGE recommends the use of NSBBs (propranolol or carvedilol) in combination with endoscopic
therapy for secondary prophylaxis in EVH in patients with ACLD
ESGE recommends an individualized approach for secondary prophylaxis of cardiofundal
variceal hemorrhage (GOV2, IGV1) based upon patient factors and local expertise owing
to the current lack of definitive high level evidence regarding specific eradication
therapies for cardiofundal varices (e. g. endoscopic cyanoacrylate injection ± NSBB,
EUS-guided injection of coils plus cyanoacrylate, TIPS, or BRTO) and appropriate treatment
intervals
ESGE suggests against the routine use of PPIs in the post-endoscopic management of
acute variceal bleeding and, if initiated before endoscopy, PPIs should be discontinued
ESGE recommends the rapid removal of blood from the GI tract, preferably using lactulose,
to prevent or to treat hepatic encephalopathy in cirrhotic patients with acute variceal
hemorrhage
ACLD, advanced chronic liver disease; BMI, body mass index; BRTO, balloon-occluded
retrograde transvenous obliteration; EBL, endoscopic band ligation; EGD, esophagogastroduodenoscopy;
EGVH, esophagogastric variceal hemorrhage; EUS, endoscopic ultrasound; EVH, esophageal
variceal hemorrhage; FFP, fresh frozen plasma; GI, gastrointestinal; GOV, gastroesophageal
varices; HVPG, hepatic venous pressure gradient; IGV, isolated gastric varices; INR,
international normalized ratio; NSBB, nonselective beta blocker; PPI, proton pump
inhibitor; TIPS, transjugular intrahepatic portosystemic shunt; UGIH, upper gastrointestinal
hemorrhage; VCE, video capsule endoscopy.
Table 2
Definitions used in this Guideline.
Compensated ACLD
Liver stiffness measurement by transient elastography < 20 kPa and platelet count
> 150 × 109 /L
Decompensated ACLD
Liver stiffness measurement by transient elastography ≥ 20 kPa or platelet count ≤ 150 × 109 /L
Clinically significant portal hypertension
HVPG > 10 mmHg and/or liver stiffness by transient elastography > 25 kPa
High risk esophagogastric varices
Varices that are medium or large size or varices that are small size with red wale
markings
High risk cirrhotic patients with variceal bleeding
HVPG ≥ 20 mmHg
Acute episode of variceal bleeding
Variceal bleeding events in the interval of 5 days from the time of patient presentation
to a medical facility
Early variceal rebleeding
Variceal bleeding that occurs beyond 5 days but with 6 weeks from the time of patient
presentation to a medical facility provided initial hemostasis was achieved
Late variceal rebleeding
Variceal bleeding that occurs ≥ 6 weeks from the time of patient presentation to a
medical facility
Type 1 gastroesophageal varices (GOV1)
Extend below the gastroesophageal junction along the lesser curvature of the stomach
Type 2 gastroesophageal varices (GOV2)
Extend below the gastroesophageal junction into the gastric fundus
Type 1 isolated gastric varices (IGV1)
Are only located in the gastric fundus
Type 2 isolated gastric varices (IGV2)
Are located elsewhere in the stomach (e. g. antrum)
ACLD, advanced chronic liver disease; GOV, gastroesophageal varices; HVPG, hepatic
venous pressure gradient; IGV, isolated gastric varices.
3 Endoscopic screening for high risk esophagogastric varices and primary prophylaxis
for EGVH
3 Endoscopic screening for high risk esophagogastric varices and primary prophylaxis
for EGVH
3.1 Screening for high risk esophagogastric varices
ESGE recommends that, for patients with compensated ACLD and liver stiffness measurement
< 20 kPa and platelet count ≥ 150 × 109 /L, screening upper gastrointestinal (GI) endoscopy can be avoided because these patients
are thought to have a low probability for having high risk varices.
Strong recommendation, high quality evidence.
ESGE recommends that patients with decompensated ACLD (liver stiffness measurement
by transient elastography ≥ 20 kPa or platelet count ≤ 150 × 109 /L) should be screened by upper GI endoscopy to identify high risk esophagogastric
varices (esophageal varices that are medium or large in size; or small-sized esophageal
varices with red wale markings).
Strong recommendation, moderate quality evidence.
ESGE recommends that patients with compensated ACLD, but with liver stiffness measurement
by transient elastography ≥ 20 kPa or platelet count ≤ 150 × 109 /L who are not receiving nonselective beta blocker therapy, should be screened by
upper GI endoscopy to identify high risk esophagogastric varices (esophageal varices
that are medium or large in size; or small-sized esophageal varices with red wale
markings).
Strong recommendation, moderate quality evidence.
ESGE recommends that esophageal varices be documented in the endoscopy report according
to the Baveno criteria as small, medium, or large varices, with or without the presence
of red wale markings.
Strong recommendation, low quality evidence.
ESGE recommends that gastric varices be documented in the endoscopy report according
to the Sarin classification.
Strong recommendation, low quality evidence.
In 2015, the Baveno VI consensus conference challenged the dogma that all patients
with cirrhosis/ACLD should undergo upper gastrointestinal (GI) endoscopy to screen
for high risk varices [3 ]. With the use of noninvasive testing, it has been reported that patients with a
liver stiffness < 20 kPa and a platelet count ≥ 150 × 109 /L are at low risk (< 5 %) of having high risk varices [3 ]. These parameters, known as the Baveno VI criteria, have subsequently been validated
by numerous studies in multiple settings, including in various compensated ACLD patient
populations [4 ]
[5 ]
[6 ]
[7 ]. A recent systematic review assessing the performance of the Baveno VI criteria
showed a pooled negative predictive value of 99 % (95 %CI 99 % to 100 %) for ruling
out high risk varices, with criteria performance not affected by the cause of cirrhosis,
so appearing to confirm that the Baveno VI criteria can be safely used to avoid endoscopy
in a substantial proportion of patients with compensated cirrhosis [8 ].
ESGE does not recommend video capsule endoscopy (VCE) for screening of esophageal
varices.
Strong recommendation, high quality evidence.
A multicenter randomized trial and two meta-analyses investigating the diagnostic
performance of esophageal video capsule endoscopy (VCE) compared with esophagogastroduodenoscopy
(EGD) for the detection and grading of esophageal varices in patients with ACLD have
been published [9 ]
[10 ]
[11 ]. Sacher-Huvelin et al. reported on the diagnostic performance of VCE compared with
EGD in 300 patients with cirrhosis [9 ]. Esophageal varices were identified by VCE in 121 patients (40.3 %) and by EGD in
140 (46.6 %). The overall sensitivity, specificity, and positive and negative predictive
values of VCE were 76 %, 91 %, 88 %, and 81 %, respectively, and the overall accuracy
was 84 % [9 ].
Colli et al. performed a systematic review/meta-analysis on the diagnostic accuracy
of VCE for the diagnosis of esophageal varices in children or adults with chronic
liver disease or portal vein thrombosis [10 ]. In the 15 included studies (936 patients with cirrhosis), 68.4 % had varices of
any size. The sensitivity of VCE to diagnose esophageal varices of any size ranged
from 65 % to 100 % and the specificity from 33 % to 100 %. The pooled estimate of
sensitivity was 84.8 % and of specificity 84.3 % of VCE for diagnosing esophageal
varices of any size [10 ]. In a subsequent systematic review/meta-analysis including 17 studies (1328 patients
with portal hypertension) comparing VCE with EGD, the diagnostic accuracy of VCE in
diagnosing esophageal varices was 90 % [11 ]. The diagnostic pooled sensitivity and specificity were 83 % and 85 %, respectively.
The diagnostic accuracy of VCE for the grading of medium-to-large sized esophageal
varices was 92 %. The pooled sensitivity and specificity were 72 % and 91 %, respectively,
for the grading of esophageal varices [11 ].
3.2 Primary prophylaxis for esophagogastric variceal hemorrhage
ESGE recommends that patients with compensated ACLD (due to viruses, alcohol, and/or
nonobese [BMI < 30 kg/m2 ] nonalcoholic steatohepatitis) and clinically significant portal hypertension (hepatic
venous pressure gradient [HVPG] > 10 mmHg and/or liver stiffness by transient elastography
> 25 kPa) should receive, if no contraindications, nonselective beta blocker (NSBB)
therapy (preferably carvedilol) to prevent the development of variceal bleeding.
Strong recommendation, moderate quality evidence.
ESGE recommends that, in those patients who are unable to receive NSBB therapy with
a screening upper GI endoscopy that demonstrates high risk esophagogastric varices,
prophylactic endoscopic treatment should be performed.
Strong recommendation, moderate quality evidence.
ESGE recommends that, in those patients unable to receive NSBB therapy with a screening
upper GI endoscopy that demonstrates high risk esophageal varices, endoscopic band
ligation (EBL) is the endoscopic prophylactic treatment of choice. EBL should be repeated
every 2–4 weeks until variceal eradication is achieved. Thereafter, surveillance EGD
should be performed every 3–6 months in the first year following eradication.
Strong recommendation, moderate quality evidence.
ESGE suggests that, in those patients unable to receive NSBB therapy with a screening
upper GI endoscopy that demonstrates gastric varices (Sarin GOV-2 or IGV-1; cardiofundal
varices), no treatment, cyanoacrylate injection alone, or endoscopic ultrasound (EUS)-guided
coil plus cyanoacrylate injection can be considered. EUS-guided injection therapy
should be decided on a case-by-case basis and limited to centers with expertise in
this endoscopic technique.
Weak recommendation, low quality evidence.
ESGE recommends that, in those patients unable to receive NSBB therapy with a screening
upper GI endoscopy that does not demonstrate high risk varices, surveillance endoscopy
should be performed every 2 years if there is ongoing active liver disease or every
3 years if the underlying liver disease is quiescent.
Weak recommendation, low quality evidence.
Primary prophylaxis is universally recommended for patients with ACLD and high risk
varices. Both NSBB therapy and endoscopic band ligation (EBL) are accepted primary
prophylaxis options for esophageal varices, as they have both been shown to significantly
reduce the risk of a first episode of esophageal variceal hemorrhage (EVH). A network
meta-analysis (including 32 RCTs comparing NSBBs, isosorbide mononitrate, carvedilol,
and EBL, alone or in combination with each other or placebo; 3362 adults who had cirrhosis
with large esophageal varices and no prior history of bleeding) showed that both NSBB
therapy and EBL have similar efficacy in reducing the risk of a first variceal bleed
[12 ]. While serious and life-threatening adverse events (AEs) are more common in patients
treated with EBL, discontinuation owing to AEs was more common in NSBB-treated patients.
Moreover, NSBBs demonstrated a survival benefit over EBL. This observed beneficial
effect may be a result of factors beyond the prevention of EVH and may be related
to the effect of NSBBs on reducing portal hypertension.
Moreover, an individual patient data meta-analysis also reinforced the benefit of
NSBBs in patients with compensated cirrhosis and high risk varices [13 ]. This meta-analysis included 11 RCTs (1400 patients with cirrhosis and high risk
varices, of which 656 had compensated cirrhosis) comparing NSBB therapy against EBL,
either as monotherapy or in combination, for the primary prevention of bleeding. In
patients with compensated cirrhosis, the mortality risk was lower with NSBB therapy
than with EBL (summary hazard ratio [SHR] 0.57, 95 %CI 0.36 to 0.90; P = 0.02) and was similar with NSBB therapy and EBL compared with NSBBs alone (P = 0.10). The benefit in patients with compensated cirrhosis treated with NSBBs was
mainly because of a decrease in the risk of developing ascites (SHR 0.38, 95 %CI 0.19
to 0.73; P = 0.004), while the risk of a first variceal bleed was similar (SHR 0.94, 95 %CI
0.47 to 0.87; P = 0.86) between the groups. Additionally, neither the risk of variceal bleeding nor
the risk of developing ascites was improved by adding EBL to NSBBs as compared with
treatment with NSBBs alone. These data suggest that NSBBs should be the treatment
of choice in patients with high risk varices because, in addition to decreasing the
variceal bleeding risk similarly to EBL, they decrease the risk of developing ascites
and significantly improve survival.
The preferred NSBB for primary prophylaxis is carvedilol based on its greater portal
pressure lowering effect compared with propranolol or nadolol, and the improvement
in the outcome of nonresponders to propranolol [14 ]. The effects of carvedilol in preventing decompensation and improving survival in
patients with compensated cirrhosis has been recently investigated in a meta-analysis.
This study included 352 patients with compensated cirrhosis (181 treated with carvedilol
and 171 controls) from four RCTs and showed a decreased risk of decompensation (SHR
0.506, 95 %CI 0.289 to 0.887; P = 0.02) and mortality (SHR 0.417, 95 %CI 0.194 to 0.896; P = 0.03) in patients treated with carvedilol, without significant heterogeneity [15 ].
There have been several systematic reviews/meta-analyses of RCTs evaluating the benefits
and harms of EBL versus NSBBs as primary prophylaxis for esophageal variceal bleeding
[16 ]
[17 ]
[18 ]. In a Cochrane systematic review, Gluud et al. reported that 176/731 of the patients
randomized to EBL (24 %) and 177/773 of patients randomized to NSBBs (23 %) died.
EBL reduced upper GI hemorrhage (UGIH) and variceal bleeding compared with NSBBs (relative
risk [RR] 0.69 and 0.67, respectively). There was a beneficial effect of EBL on primary
prevention of EVH, yet this did not reduce mortality [16 ]. In the most recent systematic review/meta-analysis evaluating carvedilol versus
EBL, Tian et al. reported no significant difference in variceal bleeding between the
carvedilol and EBL groups (RR 0.86, 95 %CI 0.60 to 1.23). Moreover, no significant
difference was observed for all-cause mortality (RR 0.82, 95 %CI 0.44 to 1.53) or
for bleeding-related deaths (RR 0.85, 95 %CI 0.39 to 1.87) [18 ].
4 Pre-endoscopy management of acute EGVH
4 Pre-endoscopy management of acute EGVH
4.1 Hemodynamic resuscitation
ESGE recommends urgent assessment of the hemodynamic status in patients presenting
with suspected acute EGVH.
Strong recommendation, low quality evidence.
ESGE recommends prompt, yet careful, intravascular volume replacement, initially using
crystalloid fluids, if hemodynamic instability exists, to restore tissue perfusion
while avoiding intravascular volume overexpansion.
Strong recommendation, low quality evidence.
ESGE does not recommend the transfusion of fresh frozen plasma as part of the initial
management of EGVH.
Strong recommendation, low quality evidence.
ESGE does not recommend the use of recombinant factor VIIa as part of the initial
management of EGVH.
Strong recommendation, high quality evidence.
The goals of hemodynamic resuscitation are to correct intravascular hypovolemia, restore
adequate tissue perfusion, and prevent multiorgan failure. Early intensive hemodynamic
resuscitation of patients with acute UGIH has been shown to significantly decrease
mortality ([Fig. 1 ] and [Fig. 2 ]) [19 ]. However, uncertainty remains regarding the optimal rate of fluid resuscitation
(aggressive vs. restrictive), especially for EGVH.
Fig. 1 ESGE algorithm for the management of acute esophageal variceal hemorrhage (EVH).
Fig. 2 ESGE algorithm for the management of acute gastric variceal hemorrhage (GVH).
Existing limited evidence, derived from patients with hemorrhagic shock from all causes
including trauma, suggest that, as compared with a conventional fluid resuscitation
strategy, a restrictive fluid resuscitation regimen may lead to fewer AEs and may
reduce mortality [20 ]
[21 ]
[22 ]
[23 ]. The optimal choice of intravenous fluid for initial resuscitation is unclear, with
crystalloids or colloids often being used while the need for the transfusion of blood
products is assessed [24 ]
[25 ]
[26 ]. In both a large RCT and a meta-analysis of critically ill patients, as compared
with saline, use of a “balanced” crystalloid solution (e. g. lactated Ringer’s solution)
was shown to reduce both mortality and major adverse renal events [25 ]
[26 ]. Whether these data can be fully extrapolated to patients with EGVH is uncertain.
Care should be taken to avoid aggressive intravascular volume overexpansion in patients
presenting with suspected EVGH in order to avoid a paradoxical increase in portal
hypertension and subsequent bleeding risk.
Mohanty et al. in a retrospective study evaluating whether the transfusion of fresh
frozen plasma (FFP) affected mortality and bleeding outcomes in patients with cirrhosis
and acute variceal hemorrhage [27 ], reported that FFP transfusion was associated with significantly increased mortality
at 42 days (odds ratio [OR] 9.41, 95 %CI 3.71 to 23.90), failure to control bleeding
at 5 days (OR 3.87, 95 %CI 1.28 to 11.70), and longer hospital stay (OR 1.88, 95 %CI
1.03 to 3.42). Lower volume factor replacements such as prothrombin complex concentrate
(PCC) and recombinant factor VIIa appear to be more effective than FFP in decreasing
international normalized ratio (INR) values in patients with cirrhosis [28 ], while not carrying the risk of intravascular volume overload. However, two RCTs
failed to show any benefit for recombinant factor VIIa infusion in EGVH [29 ]
[30 ].
4.2 Endotracheal intubation
ESGE suggests endotracheal intubation prior to upper GI endoscopy in patients with
suspected variceal hemorrhage and ongoing hematemesis, encephalopathy, and/or with
agitation and inability to control their airway to protect against the potential aspiration
of gastric contents.
Weak recommendation, low quality evidence.
ESGE recommends that, if prophylactic endotracheal intubation is performed, extubation
should occur as soon as clinically safe following upper GI endoscopy.
Strong recommendation, very low quality evidence.
Studies evaluating the outcomes and safety of prophylactic endotracheal intubation
prior to upper GI endoscopy in patients presenting with acute UGIH, including EGVH,
are limited and of low quality. Their results have varied regarding important outcomes
such as aspiration, pneumonia, and mortality [31 ]
[32 ]
[33 ]
[34 ]. Meta-analyses pooling these small observational studies show that prophylactic
endotracheal intubation before upper GI endoscopy in all patients with acute UGIH
may be associated with a higher risk of aspiration and pneumonia, longer hospital
stays, and potentially higher mortality [35 ]
[36 ]
[37 ].
The most recent meta-analyses [36 ]
[37 ] conducted subgroup analyses stratified by the type of UGIH (variceal vs. other),
hypothesizing that variceal bleeding would be associated with a greater benefit from
prophylactic endotracheal intubation. These subgroup analyses included two observational
studies (n = 172 patients) with more EGVH patients (62 %) in the prophylactic intubation
group. Alshamsi et al. [36 ] reported that prophylactic endotracheal intubation in patients with variceal bleeding
was associated with higher rates of aspiration (OR 4.60, 95 %CI 0.53 to 39.91), pneumonia
(OR 5.31, 95 %CI 0.63 to 44.76), and longer hospital length of stay (mean difference
1.60 days, 95 %CI −0.66 to 3.86). Moreover, there was significantly increased mortality
observed (OR 3.47, 95 %CI 1.24 to 9.74) in the variceal hemorrhage group [36 ]. Chaudhuri similarly reported that prophylactic intubation conferred increased mortality
in patients presenting with variceal bleeding (OR 4.45; 95 %CI 1.46 to 13.56), with
no study heterogeneity observed in the variceal group (I
2 0 %) [37 ]. Intubation prior to urgent EGD for EGVH did not improve clinical outcomes, suggesting
against the use of routine prophylactic intubation in patients with EGVH who have
only mild encephalopathy and no ongoing hemorrhage. The benefits and risks of prophylactic
endotracheal intubation should be carefully weighed when considering airway protection
before upper GI endoscopy in patients with EGVH.
4.3 Platelet and FFP transfusion
ESGE does not recommend routine platelet transfusion or a specific minimum platelet
count threshold for triggering platelet transfusion. If variceal bleeding is not controlled,
the decision to transfuse platelets should be made on a case-by-case basis.
Strong recommendation, moderate quality evidence.
Limited data are available on the requirement for platelet transfusion in acute variceal
bleeding and thrombocytopenia [38 ]. There are no studies evaluating adequate platelet thresholds for the purpose of
enhancing hemostasis in the bleeding cirrhotic patient. At steady state in cirrhosis,
there is a balance in all phases of hemostasis that is marked by compensatory changes
in both the prohemostatic and antihemostatic systems.
Some experts recommend the use of thromboelastography (TEG) to help determine the
need for factor and platelet replacement therapy in patients with cirrhosis. TEG is
a method of testing the efficiency of blood coagulation and is primarily used in surgery
and anesthesiology, although increasingly it is used in emergency departments, intensive
care units, and labor and delivery suites. There is one recently published open label
RCT [38 ] comparing the use of TEG with routine blood tests (platelet count, prothrombin time,
and fibrinogen) as a guide to platelet transfusion in patients with cirrhosis. In
this study, 60 cirrhotic patients were randomized to either the TEG group (patients
received FFP when the R time [reaction time] was > 15 minutes and 3 units of platelets
over 30–60 minutes when the MA [maximum amplitude] was < 30 mm) or the conventional
transfusion group (patients received FFP when the INR was > 1.8 and received 3 units
of platelets when the platelet count was < 50 × 109 /L). The authors found that TEG findings were within the normal range in most cirrhotic
patients, which led to a significant decrease in the use of both platelet and FFP
transfusions in the TEG group. The use of TEG-guided blood product transfusion strategy
reduced blood product transfusions and rebleeding at day 42 in cirrhotic patients
with acute variceal bleeding and coagulopathy. These findings suggest that hemostatic
competence is maintained, even in the bleeding cirrhotic patient.
4.4 Red blood cell transfusion strategy
ESGE recommends, in hemodynamically stable patients with acute UGIH and no history
of cardiovascular disease, a restrictive red blood cell (RBC) transfusion strategy,
with a hemoglobin threshold of ≤ 70 g/L prompting RBC transfusion. A post-transfusion
target hemoglobin of 70–90 g/L is desired.
Strong recommendation, moderate quality evidence.
ESGE recommends, in hemodynamically stable patients with acute UGIH and a history
of acute or chronic cardiovascular disease, a more liberal RBC transfusion strategy
with a hemoglobin threshold of ≤ 80 g/L prompting RBC transfusion.
Strong recommendation, low quality evidence.
For patients with cirrhotic liver disease, a liberal red blood cell (RBC) transfusion
strategy has been shown to increase portal pressures, which can directly mediate rebleeding.
In a systematic review/meta-analysis that included five RCTs comparing restrictive
versus liberal RBC transfusion for acute UGIH (1965 patients [93 % from two RCTs],
with 919 patients on the restrictive RBC transfusion strategy and 1064 on the liberal
strategy), Odutayo et al. reported that a restrictive RBC transfusion policy was associated
with a significant overall reduction in mortality (RR 0.65, 95 %CI 0.44 to 0.97) and
rebleeding (RR 0.58, 85 %CI 0.40 to 0.84), and no difference in the risk of ischemic
events [39 ].
The effect on rebleeding was consistent across subgroups. The treatment effect for
mortality was greatest in patients with cirrhosis (413/1965; 21 %), with a 48 % reduction
in the risk of death with a restrictive RBC transfusion policy (RR 0.52, 95 %CI 0.29
to 0.94; P = 0.03). Moreover, the absolute risk reduction was 4.21 % (95 %CI 1.44 % to 6.03 %)
for overall rebleeding and 5.87 % (95 %CI 0.75 % to 8.74 %) for rebleeding in the
cirrhosis group. The number needed to treat to prevent one rebleeding event using
a restrictive transfusion strategy was 24 (95 %CI 17 to 70) in the group overall and
17 (95 %CI 11 to 134) in the subgroup of patients with cirrhosis [39 ].
4.5 Risk stratification
ESGE recommends that patients with ACLD presenting with suspected acute variceal bleeding
be risk stratified according to the Child–Pugh score and MELD score, and by documentation
of active/inactive bleeding at the time of upper GI endoscopy.
Strong recommendation, high quality of evidence.
ESGE recommends the following risk stratification definitions:
patients with Child–Pugh A or Child–Pugh B without active bleeding at upper GI endoscopy
or MELD < 11 points are at low risk of poor outcome
patients with Child–Pugh B with active bleeding at upper GI endoscopy despite vasoactive
agents or Child–Pugh C are at high risk of poor outcome
patients with MELD ≥ 19 points are considered at high risk of poor outcome.
Strong recommendation, high quality evidence.
In the setting of acute variceal hemorrhage in patients with ACLD, validated risk
stratification scores evaluating the severity of the underlying liver disease can
be used to predict patient outcomes including: mortality (at 6 weeks) related to the
acute episode of variceal bleeding and rebleeding, and both failure to control the
acute bleeding episode and early rebleeding (within 5 days of index endoscopy). The
best predictor of poor outcome in cirrhotic patients with variceal bleeding is the
hepatic venous pressure gradient (HVPG) measurement, which defines high risk patients
as those with an HVPG ≥ 20 mmHg [40 ]
[41 ]; however, HVPG measurement is an interventional procedure and is not usually readily
available. Therefore, clinical scores have been validated as risk stratification tools
including: the Child–Pugh score ([Table 3 ]) [42 ]
[43 ]
[44 ]
[45 ] and the MELD score ([Table 4 ]) [43 ]
[46 ]
[47 ]
[48 ]
[49 ]
[50 ].
Table 3
The Child–Pugh score.
Clinical and laboratory criteria
Points
1
2
3
Encephalopathy
None
Mild to moderate
Severe
Ascites
None
Mild to moderate
Severe
Bilirubin, µmol/L
< 34
34–50
> 50
Albumin, g/L
> 35
28–35
< 28
INR
< 1.7
1.7–2.3
> 2.3
Class
Total points[1 ]
Severity of liver disease
A
5–6
Least severe
B
7–9
Moderately severe
C
10–15
Most severe
INR, international normalized ratio.
1 Obtained by adding the points for each of the five parameters.
Table 4
The MELD score[a ].
Components of the MELD score
3.78 × loge serum bilirubin (mg/dL)[b ]
11.20 × loge INR[b ]
9.57 × loge serum creatinine (mg/dL)[b ]
[c ]
6.43 (= constant for liver disease etiology)
INR, international normalized ratio.
a The MELD score is the sum of each of its four components, with scores ranging from
6 to 40.
b Any value < 1.0 is given the value 1, as loge 1 = 0 and values < 1.0 would give a negative result.
c For patients dialyzed twice within the last 7 days, a value of 4.0 is used.
Patients with Child–Pugh C ≤ 13 points or Child–Pugh B > 7 points with active variceal
bleeding at GI endoscopy (defined as variceal jet/oozing, despite the use of vasoactive
drugs) are at high risk of a poor outcome, so may benefit from pre-emptive transjugular
intrahepatic portosystemic shunt (TIPS) placement and these criteria have been validated
in a recent meta-analysis of individual patient data [44 ]. Although there are concerns about the prognostic capacity of these variables because
of the subjectivity of evaluating the presence/severity of ascites and/or hepatic
encephalopathy, as well as the true risk of Child–Pugh B patients, recent studies
have shown they are effective in classifying patient risk [45 ]
[51 ]. MELD ≥ 19 also defines high risk ACLD patients and has been evaluated in several
studies [43 ]
[48 ]
[51 ].
4.6 Use of vasoactive agents
ESGE recommends the vasoactive agents terlipressin, octreotide, or somatostatin be
initiated at the time of presentation in patients with suspected acute variceal bleeding
and be continued for a duration of up to 5 days.
Strong recommendation, high quality evidence.
ESGE suggests, following successful endoscopic hemostasis, vasoactive agents may be
stopped 24–48 hours later in selected patients.
Weak recommendation, moderate quality evidence.
Several systematic reviews/meta-analyses, including numerous RCTs with thousands of
patients, have evaluated the efficacy and safety of vasoactive agents in acute EGVH
[52 ]
[53 ]
[54 ]
[55 ]
[56 ]
[57 ]. In summary, vasoactive agents are superior to no vasoactive treatment in terms
of rates of in-hospital mortality, overall mortality, variceal bleeding control, variceal
rebleeding, and blood transfusion requirement. Octreotide and somatostatin appear
to have equal efficacy to terlipressin and vasopressin, and are associated with lower
rates of AEs. Vasopressin is no longer used owing to its extrasplanchnic vasoconstrictive
properties and high AE profile.
Vasoactive agents as adjuvant treatment following successful endoscopic hemostasis
have also been shown to significantly reduce early rebleeding rates (within 5 days
after index variceal hemorrhage). Moreover, following successful endoscopic hemostasis,
an abbreviated course of vasoactive treatment may be equally as effective as a treatment
duration of 3–5 days [56 ]
[58 ]
[59 ]. In their systematic review/meta-analysis, Yan et al. reported no significant difference
in 42-day mortality rate (RR 0.95, 95 %CI 0.43 to 2.13) when comparing a 3- to 5-day
vasoactive drug regimen with a shorter course. Moreover, when evaluating the very
early rebleeding rate, a shorter course also appeared to be beneficial (RR 1.77, 95 %CI
0.64 to 4.89), although this difference was not statistically significant. Continuous
infusion of terlipressin may be more effective than intermittent infusion [60 ].
4.7 Use of antibiotic prophylaxis
ESGE recommends antibiotic prophylaxis using ceftriaxone 1 g/day for up to 7 days
for all patients with ACLD presenting with acute variceal hemorrhage, or in accordance
with local antibiotic resistance and patient allergies.
Strong recommendation, high quality evidence.
Patients with ACLD presenting with acute EGVH are at high risk for bacterial infection,
especially respiratory tract infection [61 ]. Bacterial infection leads to a higher risk of rebleeding and an increased overall
mortality rate. In a multicenter retrospective cohort study including 371 adult patients
with cirrhosis and acute EGVH, all of whom had received antibiotic prophylaxis, Lee
et al. reported that 14 % of patients developed bacterial infection within 14 days
despite antibiotic prophylaxis [61 ]. Respiratory infections accounted for more than 50 % of infections, and there was
a high proportion of culture-positive infections caused by organisms resistant to
the recommended fluroquinolones and third-generation cephalosporins [61 ].
Two systematic reviews/meta-analyses of RCTs investigated the benefits and outcomes
of antibiotic prophylaxis in patients with ACLD and acute EGVH [62 ]
[63 ]. In both studies, antibiotic prophylaxis was shown to reduce the risk of bacterial
infection as well as overall mortality, risk of rebleeding, and length of hospital-stay,
especially among patients with more advanced chronic liver disease.
Third-generation cephalosporins have been shown to be superior to fluoroquinolones
in the prevention of bacterial infection. In an RCT (n = 111), Fernandez et al. reported
that intravenous ceftriaxone was significantly better than norfloxacin in the prevention
of bacterial infections, bacteremia, and spontaneous bacterial peritonitis in patients
with ACLD and EGVH (11 % vs. 33 %, P = 0.003; 11 % vs. 26 %, P = 0.03; and 2 % vs. 12 %, P = 0.03, respectively) [64 ]. Ceftriaxone (1 g/24 hours) should be the first choice of treatment, especially
considering the higher rates of microbial resistance to fluoroquinolones, which can
lead to treatment failure [61 ].
Antibiotic stewardship programs recommend the critical use of antibiotics with the
shortest possible duration of therapy. The duration of antibiotic prophylaxis in patients
with ACLD and EGVH has been studied. The general recommendation for the duration of
antibiotic prophylaxis is a maximum of 7 days; however, some data suggest that a 3-day
duration of antibiotic treatment may suffice. Lee et al., in an RCT including 71 patients,
compared a 3-day treatment regimen of ceftriaxone 500 mg every 12 hours to a 7-day
regimen and reported no difference between the groups in the rate of variceal rebleeding,
nor in 28-day mortality [65 ]. For patients with compensated Child–Pugh A liver disease, the rate of bacterial
infection is low. Chang et al. evaluated the use of antibiotic prophylaxis in this
subset of patients and compared antibiotic prophylaxis to an on-demand antibiotic
regimen. The rate of bacterial infection within 14 days and the overall mortality
rate within 42 days did not differ between the groups [66 ].
Antibiotic prophylaxis in patients with ACLD and acute EGVH reduces the overall mortality
rate, rate of variceal rebleeding, and length of hospital stay. Third-generation cephalosporins,
especially ceftriaxone 1 g/24 hours, appear superior to fluoroquinolones with a maximum
treatment duration of 7 days.
4.8 Management of patients on antiplatelet agents
ESGE recommends that antiplatelet agents be temporarily withheld in patients presenting
with acute variceal hemorrhage.
Strong recommendation, low quality evidence.
ESGE recommends that the restarting of antiplatelet agents be determined on the basis
of the patient’s risk of rebleeding versus their risk of thrombosis.
Strong recommendation, low quality evidence.
Coagulation disorders are common in patients with chronic liver disease; inappropriate
clotting is now considered to be the main disorder and is attributed to changes in
the hemostatic balance [67 ]. Antiplatelet agents (aspirin and P2Y12 receptor inhibitors) represent a severe
aggravating factor for patients with ACLD and acute EGVH. Antiplatelet agents typically
must be withheld at the onset of variceal bleeding; however, the restoration of normal
platelet function is not observed until a minimum of 5–7 days later. Platelet transfusion
has been suggested for patients with life-threatening active bleeding, but outcome
data have not demonstrated a clinical benefit with this strategy [68 ]. In patients with coronary artery stents who are receiving dual antiplatelet therapy,
management should be coordinated with an interventional cardiologist. In such cases,
it is recommended that aspirin is continued with only temporary interruption of the
P2Y12 receptor antagonist [69 ].
According to the recently published collaborative guideline from the British Society
of Gastroenterology (BSG) and ESGE on the management of anticoagulants during endoscopy,
low dose aspirin should not be resumed if it is used for primary prophylaxis [70 ]
[71 ]. This is because low dose aspirin has a relatively small benefit, with no reduction
in vascular mortality and an annual absolute risk reduction for any serious vascular
event of only 0.06 % [70 ]
[71 ].
In contrast, restarting low dose aspirin for secondary prophylaxis should be considered
only in patients at very high individual risk for cardiovascular events, or if there
is no further evidence of bleeding. Discontinuation of low dose aspirin in patients
with known cardiovascular disease and GI bleeding is associated with an increase in
death and acute cardiovascular events after hospital discharge [72 ]
[73 ]
[74 ]. The timing of the restarting of antiplatelet therapy for secondary cardiovascular
prophylaxis following acute variceal bleeding should be determined by weighing the
risk of variceal rebleeding and the risk of thrombosis. P2Y12 receptor antagonists
in patients with coronary artery stents should be restarted within 5 days owing to
the high risk of stent occlusion if further delayed. This timeframe represents an
optimal balance between hemorrhage and thrombosis [69 ].
4.9 Management of patients on anticoagulation
ESGE recommends that anticoagulants be temporarily withheld in patients presenting
with suspected acute variceal hemorrhage and appropriate reversal agents be used in
patients with hemodynamic instability.
Strong recommendation, low quality evidence.
ESGE recommends that the restarting of anticoagulants should be guided by the patient’s
risk of rebleeding versus their risk of thrombosis.
Strong recommendation, low quality evidence.
The management of variceal bleeding occurring while on anticoagulant therapy is challenging.
According to a multicenter retrospective case–control study, patients who have UGIH
while on anticoagulant therapy are more likely to be hemodynamically unstable (i. e.
have hypotension and/or shock) and present with lower hemoglobin and hematocrit values
when compared with patients not taking anticoagulants [75 ]. However, anticoagulant therapy did not significantly influence treatment failure
at 5 days (i. e. failure to control bleeding, early rebleeding, or death within 5
days), nor 6-week mortality, when anticoagulant therapy was provided for portal vein
thrombosis. There was however an observed three- to four-fold increase in mortality
when anticoagulants were administered to treat cardiovascular disease (i. e. prosthetic
valves or atrial fibrillation) [75 ], suggesting that co-morbidity and not anticoagulation treatment was influencing
survival.
According to the recently published collaborative guideline from the BSG and ESGE
on the management of anticoagulants during endoscopy, in cases of acute variceal bleeding,
anticoagulant therapy should be promptly withheld, and coagulopathy corrected according
to the severity of hemorrhage and the patient’s underlying thrombotic risk [70 ]. It should be stressed however that correction of coagulopathy, when required, should
not delay endoscopic intervention because endoscopy can be safely performed at therapeutic
levels of anticoagulation.
Briefly, in patients with hemodynamic instability who take vitamin K antagonists,
it is recommended that intravenous vitamin K and four-factor PCC be administered,
with FFP considered if PCC is not available. The use of FFP has been questioned recently
by a multicenter observational study which highlighted that FFP transfusion in patients
with acute variceal bleeding was associated with poor clinical outcomes, in particular
increased odds of mortality at 42 days, failure to control bleeding at 5 days, and
length of hospital stay > 7 days [27 ].
In patients who are taking direct oral anticoagulants (DOACs), DOAC reversal agents
should be considered only in those with hemodynamic instability and then in coordination
with a local hematologist. Idarucizumab should be used in dabigatran-treated patients
and andexanet in anti-factor Xa-treated patients (i. e. apixaban and rivaroxaban),
or intravenous four-factor PCC if andexanet is not available. In patients who do not
have hemodynamic instability, because of the short half-life of DOACs, withholding
the drug is sufficient to manage most cases of UGIH.
The timing of the restarting of anticoagulation depends on the patient’s underlying
thrombotic risk. In patients at low thrombotic risk, it is suggested that anticoagulation
be restarted 7 days after successful hemostasis of the acute variceal bleeding episode.
In patients at high thrombotic risk, an earlier resumption of anticoagulation with
heparin bridging, within 3 days, is recommended.
4.10 Use of a prokinetic agent
ESGE recommends, in the absence of contraindications, intravenous erythromycin 250 mg
be given 30–120 minutes prior to upper GI endoscopy in patients with suspected acute
variceal hemorrhage.
Strong recommendation, high quality evidence.
Blood in the esophagus and stomach in patients with variceal bleeding often obscures
the endoscopic view and makes endoscopic intervention difficult to perform. The use
of an intravenous prokinetic agent has been shown to be helpful in promoting gastric
emptying of blood and clots, and providing improved endoscopic visualization. Barkun
et al., in a meta-analysis, found that an intravenous infusion of different prokinetic
agents administered up to 2 hours before endoscopy in patients with acute UGIH improved
endoscopic visualization and significantly decreased the need for repeat endoscopy
[76 ]. Most studies assessing the use of pre-endoscopy prokinetics in acute UGIH have
used intravenous erythromycin.
Erythromycin, a macrolide antibiotic, is a potent motilin agonist that induces rapid
gastric emptying when given intravenously in doses ranging from 1 to 3 mg/kg in healthy
individuals [77 ]. The effect of erythromycin on endoscopic visibility and its outcome in patients
with acute variceal bleeding was investigated in a randomized, double-blind placebo-controlled
trial [78 ]. Patients received either 125 mg erythromycin or placebo administered intravenously
30 minutes before endoscopy. Erythromycin infusion significantly improved the quality
of endoscopic visualization, shortened the duration of the index endoscopy, and decreased
the length of hospital stay. Although there was a trend toward a decrease in the need
for repeat endoscopy and endoscopy-related pulmonary complications, these clinical
end points failed to reach statistical significance, perhaps because of the small
sample size [79 ]. Insufficient data were identified to provide evidence-based recommendations for
the use of metoclopramide [79 ]
[80 ] in this clinical situation. However, if erythromycin is not available, metoclopramide
may be considered as an alternative (10 mg intravenously 30–120 minutes prior to upper
GI endoscopy) if there are no contraindications.
5 Endoscopic management
5.1 Timing of endoscopy
ESGE recommends that, in patients with suspected variceal hemorrhage, endoscopic evaluation
should take place within 12 hours from the time of patient presentation, provided
the patient has been hemodynamically resuscitated.
Strong recommendation, moderate quality evidence.
ESGE recommends that the timing of upper GI endoscopy in patients with suspected acute
variceal hemorrhage should not be influenced by the INR level at the time of patient
presentation.
Strong recommendation, low quality evidence.
In patients with acute EGVH, the optimal timing of upper GI endoscopy is controversial,
given that all published studies to date have been observational in nature, have disparate
definitions of “early” and “late” endoscopy and study conclusions, meaning there is
a lack of high level evidence on which to base guideline recommendations. A systematic
review/meta-analysis by Jung et al. [81 ] of patients with acute variceal bleeding (843 urgent endoscopy patients [≤ 12 hours]
and 453 nonurgent endoscopy patients [> 12 hours]) reported similar overall mortality
(OR 0.72, 95 %CI 0.36 to 1.45; P = 0.36) and rebleeding rates (OR 1.21, 95 %CI 0.76 to 1.93; P = 0.41) between the groups. Other outcomes, including successful primary hemostasis,
need for salvage therapy, length of hospital stay, and number of blood transfusions,
were also similar; however, the investigators reported high heterogeneity between
the included studies, and this may produce misleading results and conclusions.
In a more recent systematic review/meta-analysis by Bai et al. [82 ] that included 2824 patients with ACLD and acute variceal bleeding, overall mortality
was significantly lower in the early endoscopy group (≤ 12 hours) as compared with
the delayed endoscopy group (> 12 hours; OR 0.56, 95 %CI 0.33 to 0.95; P = 0.03) [82 ].
Regarding the INR value at the time of patient presentation and its influence on the
timing of upper GI endoscopy, we were unable to identify any high level evidence that
has evaluated this specific question in the setting of acute variceal hemorrhage.
Limited retrospective data often failed to include important baseline characteristics
of patients (e. g. INR level at presentation) and their impact on decisions regarding
the timing of upper GI endoscopy [83 ]
[84 ]. However, extrapolating from the recent ESGE guideline on nonvariceal UGIH, it is
recommended that the use of a predetermined INR cutoff value to define the timing
of endoscopy be avoided in the setting of acute UGIH [85 ]
[86 ].
5.2 Esophageal variceal hemorrhage
5.2.1 Initial management
ESGE recommends EBL for the treatment of acute EVH.
Strong recommendation, high quality evidence.
ESGE does not recommend the use of hemostatic sprays/powders for the definitive endoscopic
treatment of acute esophageal or gastric variceal hemorrhage. Hemostatic sprays/powders
may be considered as a bridge to definitive therapy when standard endoscopic treatment
is not effective or is not available.
Strong recommendation, high quality evidence.
ESGE recommends that, in patients at high risk for recurrent esophageal variceal bleeding
following successful endoscopic hemostasis (Child–Pugh C ≤ 13 or Child–Pugh B > 7
with active EVH at the time of endoscopy despite vasoactive agents, or HVPG > 20 mmHg),
pre-emptive TIPS within 72 hours (preferably within 24 hours) must be considered.
Strong recommendation, high quality evidence.
The endoscopic diagnosis of acute esophageal variceal bleeding is made when there
is active hemorrhage from a varix or a sign of recent hemorrhage (nipple sign, platelet–fibrin
plug) is seen. An esophageal variceal source of UGIH can also be inferred when there
is blood in the stomach with no other source of bleeding except for esophageal varices.
There are two main endoscopic treatment modalities for acute EVH, EBL and injection
sclerotherapy. Numerous RCTs have compared these modalities. In a seminal meta-analysis
by Laine and Cook, EBL was shown to be superior to sclerotherapy in reducing both
rebleeding (OR 0.47, 95 %CI 0.29 to 0.78) and mortality (OR 0.67, 95 %CI 0.46 to 0.98)
[87 ]. Furthermore, EBL resulted in fewer AEs (esophageal strictures, OR 0.10, 95 %CI
0.03 to 0.29) and required fewer endoscopic sessions to achieve variceal obliteration.
In an updated meta-analysis that included 36 RCTs with 3593 patients, Onofrio et al.
[88 ] reported that EBL was associated with a significant improvement in bleeding control
(RR 1.08, 95 %CI 1.02 to 1.15), mortality (RR 0.72, 95 %CI 0.54 to 0.97), and AEs
(RR 0.29, 95 %CI 0.20 to 0.44) when compared with sclerotherapy. Furthermore, the
risk of rebleeding was greater with sclerotherapy (RR 1.41, 95 %CI 1.03 to 1.94) [88 ]. Moreover, in a subanalysis, the authors evaluated five trials that compared EBL
versus the combination of EBL and sclerotherapy. The risk of AEs was significantly
lower with EBL alone (RR 0.58, 95 %CI 0.39 to – 0.88; P = 0.01) when compared with the combination of EBL and sclerotherapy. There were no
statistically significant differences in other outcomes [88 ]. Injection sclerotherapy has largely been replaced by EBL.
Typically, 5–10 bands are applied on esophageal varices starting at the site of active
or recent bleeding if such a spot is identified. The remaining varices are then treated,
beginning from the gastroesophageal junction and continuing in a spiral cephalad manner.
An RCT suggested that placing more than six bands did not impact outcomes; however,
it did result in a longer procedure time and a greater number of misfired bands [89 ]. Other studies have suggested that placing more bands than appropriate for the actual
variceal size is associated with an increased risk of rebleeding [90 ]
[91 ].
The use of hemostatic sprays/powders in GI bleeding is relatively new, with most studies
being conducted in patients with nonvariceal UGIH. Ibrahim et al. performed an RCT
evaluating TC-325, a hemostatic powder, in 86 patients with cirrhosis and acute variceal
hemorrhage [92 ]. Patients were randomized to either TC-325 application within 2 hours of hospital
admission followed by elective endoscopy within 24 hours or elective endoscopy within
24 hours. In the study group, TC-325 failed to achieve immediate hemostasis in five
patients (11.6 %), while the remaining 38 patients had no bleeding (active bleeding
or blood in stomach) at the time of elective endoscopy. In the control group, 13 patients
(30.2 %) had a second episode of hematemesis within 12 hours and required rescue endoscopy
and hemostasis therapy; all of the remaining 30 patients had active variceal bleeding
at elective endoscopy. The 6-week survival was significantly improved in the TC-325
group (7 % vs. 30 %; P = 0.006) [92 ]. The application of a hemostatic spray/powder may be considered as a bridge to definitive
therapy and may allow for early patient stabilization when expertise in endoscopic
hemostasis for variceal bleeding is not readily available.
Randomized trials have demonstrated the benefit of pre-emptive TIPS in patients at
high risk of rebleeding. In a proof-of-concept study, Monescillo et al. demonstrated
a reduction of treatment failure and a survival benefit of pre-emptive TIPS in high
risk patients when compared with sclerotherapy [40 ]. In a study by Garcia-Pagan and colleagues, patients with Child–Pugh C ≤ 13 or Child–Pugh
B and active bleeding at the time of endoscopy were randomly assigned to treatment
with TIPS within 72 hours after randomization (TIPS group) or continuation of vasoactive
pharmacological therapy with EBL (pharmacotherapy–EBL group) [42 ]. There were 63 patients with cirrhosis and endoscopically confirmed EVH included
and all received initial treatment with endoscopic therapy plus vasoactive drugs.
The 1-year probability of control of acute bleeding or prevention of severe bleeding
was 50 % in the pharmacotherapy–EBL group versus 97 % in the TIPS group (P < 0.001). The 1-year survival was 61 % in the pharmacotherapy–EBL group versus 86 %
in the early-TIPS group (P < 0.001). The early use of TIPS was not associated with an increase in severe hepatic
encephalopathy [42 ].
These results were recently validated in two studies from China including patients
with viral hepatitis as the predominant etiology of ACLD [43 ]
[93 ]. In an observational study, a lower cumulative incidence of failure to control variceal
bleeding or rebleeding at 6 weeks and 1 year were reported [43 ]. In an RCT, 132 consecutive patients with advanced cirrhosis (Child–Pugh B or C)
and acute variceal bleeding who had been treated with vasoactive drugs plus endoscopic
therapy were randomly assigned to receive either early TIPS (done within 72 hours
after initial endoscopy; n = 86) or standard treatment (vasoactive drugs continued
to day 5, followed by propranolol plus EBL for the prevention of rebleeding, with
TIPS as rescue therapy when needed; n = 46). The investigators reported that transplantation-free
survival was higher in the early TIPS group than in the control group (HR 0.50, 95 %CI
0.25 to 0.98; P = 0.04) [93 ]. Transplantation-free survival at 6 weeks was 99 % (95 %CI 97 % to 100 %) in the
early TIPS group compared with 84 % in the standard treatment group (95 %CI 75 % to
96 %; absolute risk difference 15 % [95 %CI 5 % to 48 %]; P = 0.02) and at 1 year was 86 % (95 %CI 79 % to 94 %) versus 73 % (95 %CI 62 % to
88 %; absolute risk difference 13 % [95 %CI 2 % to 28 %]; P = 0.046). There was no significant difference in AEs between the groups [93 ].
In a recent meta-analysis of individual patient data (including 3 RCTs and 4 observational
studies) comprising 1327 patients, pre-emptive TIPS significantly increased the proportion
of high risk ACLD patients with acute variceal bleeding who survived for 1 year compared
with pharmacological therapy and endoscopy (HR 0.44, 95 %CI 0.32 to 0.61; P < 0.001). Pre-emptive TIPS also significantly improved control of variceal bleeding
and ascites without increasing the incidence of hepatic encephalopathy [45 ].
5.2.2 Management of failed endoscopic hemostasis in acute esophageal variceal hemorrhage
ESGE recommends that, for persistent esophageal variceal bleeding despite vasoactive
pharmacological and endoscopic hemostasis therapy, urgent rescue TIPS should be considered
(where available).
Strong recommendation, moderate quality evidence.
ESGE suggests that, for persistent esophageal variceal bleeding despite vasoactive
pharmacological and endoscopic hemostasis therapy, self-expanding metal stents (where
available) are preferred over balloon tamponade for bridging to definitive hemostasis
therapy.
Weak recommendation, low quality evidence.
TIPS is an established salvage/rescue modality for patients with persistent/refractory
EVH despite vasoactive pharmacological and endoscopic therapy. Although there are
no high level RCTs, several retrospective studies have evaluated the role of salvage
TIPS. In a review of 15 studies, therapeutic success was reported in up to 100 % of
patients, with a variceal rebleeding rate up to 16 % and mortality up to 75 % [94 ]. In a recent retrospective study of 144 patients with refractory esophageal variceal
bleeding, TIPS failure occurred in 16 % of patients. The 6-week and 12-month mortality
rates were 36 % and 42 %, respectively. All patients with a Child–Pugh score > 13
died [95 ].
Balloon tamponade tubes, including the Sengstaken–Blakemore tube (250 mL gastric balloon,
an esophageal balloon, and a gastric suction port) or the Minnesota tube (a Sengstaken–Blakemore
tube with an added esophageal suction port above the esophageal balloon) are effective
as a temporizing measure in treating esophageal variceal bleeding in cases where endoscopic
hemostasis has failed or is unavailable. Balloon tamponade as salvage/rescue therapy
can control bleeding in up to 90 % of patients; however, it is associated with several
potential AEs, including esophageal ulceration, esophageal perforation, and/or aspiration
pneumonia, in up to 20 % of patients [96 ]. Therefore, balloon tamponade tubes should not remain in place for more than 24
hours, by which time definitive treatment should be administered because the rate
of variceal rebleeding is approximately 50 % once the balloon tamponade tube is removed.
There are several small observational studies suggesting that the use of fully covered
self-expanding metal stents (SEMSs) may be a viable alternative to balloon tamponade
tubes. Stent deployment in the esophagus provides variceal tamponade and bleeding
control. Stents can remain in place for up to 14 days, allowing more time for further
management including definitive therapy. Potential AEs include stent migration and
ulcer development [97 ]
[98 ].
In a meta-analysis including 155 patients pooled from 12 studies (11 retrospective
observational studies and 1 RCT), the pooled clinical success rate in achieving hemostasis
within 24 hours was 96 % (95 %CI 90 % to 100 %) and technical success of SEMS placement
was 97 % (95 %CI 91 % to 100 %). AEs (variceal rebleeding, ulceration and stent migration)
were reported in 36 % (95 %CI 23 % to 50 %) of the patients. The pooled survival rate
at 30 days and 60 days were 68 % (95 %CI 56 % to 80 %) and 64 % (95 %CI 48 % to 78 %),
respectively [99 ].
In the only randomized study in patients with esophageal variceal bleeding refractory
to medical and endoscopic treatment, balloon tamponade was compared with placement
of a fully covered SEMS. Stent therapy was shown to be superior in achieving esophageal
variceal bleeding control (85 % vs. 47 %; P = 0.04), reducing the need for blood transfusion (P = 0.08), and AEs (15 % vs. 47 %; P = 0.08). However, no difference in 6-week survival was observed (54 % vs. 40 %; P = 0.46) [100 ].
It should be noted that there is no role for balloon-occluded retrograde transvenous
obliteration (BRTO) in treating esophageal variceal bleeding. BRTO is indicated in
patients with gastric variceal bleeding in the presence of a gastrorenal shunt [101 ]. BRTO may aggravate nongastric varices (esophageal and duodenal) [102 ].
5.2.3 Management of recurrent esophageal variceal bleeding after initial endoscopic
hemostasis
ESGE suggests that recurrent EVH in the first 5 days following successful initial
endoscopic hemostasis be managed by a second attempt at endoscopic therapy or salvage
TIPS.
Weak recommendation, low quality evidence.
Recurrent esophageal variceal bleeding in the first 5 days may occur in 10 %–20 %
of patients following endoscopic treatment. In such patients, a second attempt at
endoscopic hemostasis may be made, although the optimal approach remains without consensus
[3 ]. For patients with severe rebleeding or endoscopically uncontrollable bleeding,
patients should be referred for TIPS. Balloon tamponade or a SEMS may be needed to
bridge the patients while awaiting TIPS [3 ].
5.3 Acute gastric variceal hemorrhage
5.3.1 Initial management
ESGE recommends classifying gastric or gastroesophageal varices according to the Sarin
classification.
Strong recommendation, low quality evidence.
ESGE recommends endoscopic cyanoacrylate injection for acute gastric (cardiofundal)
variceal (GOV2, IGV1) hemorrhage.
Strong recommendation, high quality evidence.
ESGE makes no formal recommendation regarding the use of endoscopic thrombin injection
in acute gastric (cardiofundal) variceal (GOV2, IGV1) hemorrhage because of the currently
limited and disparate data.
ESGE recommends endoscopic cyanoacrylate injection or EBL in patients with GOV1-specific
bleeding.
Strong recommendations, moderate quality evidence.
ESGE suggests that EUS-guided management of bleeding gastric varices combining injection
of coils and cyanoacrylate may be used in centers with expertise and familiarity with
this technique.
Weak recommendation, low quality evidence.
While acute gastric variceal hemorrhage (GVH) is not as prevalent as EVH, GVH is more
severe, with higher associated mortality and treatment failure [103 ]. Sarin et al. categorized gastric varices into gastroesophageal varices (GOV), also
sometimes referred to as “junctional varices,” and isolated gastric varices (IGV;
e. g. cardiofundal varices) [104 ]. Type 1 GOV (GOV1) extend below the gastroesophageal junction along the lesser curvature
of the stomach. Type 2 GOV (GOV2) extend below the gastroesophageal junction into
the gastric fundus. Type 1 IGV (IGV1) are located only in the fundus and type 2 IGV
(IGV2) are located elsewhere in the stomach (e. g. the antrum) ([Fig. 3 ]).
Fig. 3 An illustration of the different types of gastric varices according to the Sarin
classification. GOV1/2, gastroesophageal varices type 1/2; IGV1/2, isolated gastric
varices type 1/2.
The currently available endoscopic options for treating acute GVH include injection
sclerotherapy (e. g. using ethanol, ethanolamine, or polidocanol), EBL, and cyanoacrylate
injection. However, high quality data for the optimal endoscopic therapy of acute
gastric variceal bleeding remain limited, with there being inconsistencies between
trials regarding mortality, and the incidence of rebleeding and AEs.
Several systematic reviews/meta-analyses have evaluated the efficacy of cyanoacrylate
injection for the treatment of GVH [105 ]
[106 ]
[107 ]
[108 ]
[109 ]. Qiao et al. reported on three RCTs, which included 194 patients with active gastric
variceal bleeding, comparing endoscopic cyanoacrylate injection versus EBL [106 ]. Control of active bleeding was achieved in 35/44 (79.5 %) in the EBL group and
46/49 (93.9 %) patients in the cyanoacrylate injection group (P = 0.03), with a pooled OR of 4.44 (95 %CI 1.14 to 17.30). Rebleeding was similar
between the two interventions for GOV2 (35.7 % vs. 34.8 %, P = 0.90), but cyanoacrylate injection was superior for reducing rebleeding in both
GOV1 (26.1 % vs. 47.7 %; P = 0.04) and IGV1 (17.6 % vs. 85.7 %; P = 0.02). Cyanoacrylate injection, as compared with EBL, was also significantly better
in preventing the recurrence of gastric varices (36.0 % vs. 66.0 %; P = 0.002). There was no difference in AEs or mortality between the two groups.
Also in 2015, in a Cochrane meta-analysis, Rios Castellanos et al. reported on six
RCTs (including 493 patients) comparing cyanoacrylate injection versus other endoscopic
methods (sclerotherapy using alcohol‐based compounds or EBL) for acute GVH in patients
with ACLD and portal hypertension [107 ]. Endoscopic cyanoacrylate injection was possibly more effective than EBL in terms
of preventing rebleeding from gastric varices (RR 0.60, 95 %CI 0.41 to 0.88); however,
the authors commented that there was very low quality evidence with uncertainty regarding
the derived estimates on all‐cause and bleeding‐related mortality, failure of intervention,
AEs, and control of bleeding. Moreover, in the single included trial that compared
cyanoacrylate injection versus alcohol-based sclerotherapy, the investigators also
reported very low quality evidence for evaluating 30‐day mortality (RR 0.43, 95 %CI
0.09 to 2.04), failure of intervention (RR 0.36, 95 %CI 0.09 to 1.35), prevention
of rebleeding (RR 0.85, 95 %CI 0.30 to 2.45), fever as an AE (RR 0.43, 95 %CI 0.22
to 0.80), and control of bleeding (RR 1.79, 95 %CI 1.13 to 2.84).
Two more recent systematic reviews/meta-analyses have reported similar results. Hu
et al., after correcting for study heterogeneity, reported that, when gastric varices
were treated with cyanoacrylate alone (n = 309), the risk of rebleeding was 15 % (95 %CI
11 % to 18 %) [108 ]. Chirapongsathorn et al. included seven RCTs (n = 583) comparing endoscopic injection
of N‐butyl‐2‐cyanoacrylate glue with any other treatment approach not involving cyanoacrylate
(propranolol only, EBL, or sclerotherapy with alcohol or ethanolamine). The investigators
reported that cyanoacrylate use was associated with significantly lower all‐cause
mortality (RR 0.59, 95 %CI 0.36 to 0.98) and rebleeding after hemostasis (RR 0.49,
95 %CI 0.35 to 0.68). The use of endoscopic cyanoacrylate injection was not associated
with an increase in serious AEs. The quality of evidence was moderate and was downgraded
owing to the small number of events and wide CIs [109 ].
El Amin et al. performed an RCT where 150 patients with bleeding junctional varices
(GOV1) were randomized to receive either EBL or cyanoacrylate injection [110 ]. Cessation of active variceal bleeding was achieved in 61/75 (81 %) in the EBL group
and 68/75 (91 %) in the cyanoacrylate-treated group (P = 0.07). The time to variceal obliteration was significantly faster with cyanoacrylate
injection therapy. There were no observed differences between the groups in terms
of AEs. Although the groups were similar in terms of baseline characteristics, including
severity of underlying liver disease, a significantly higher survival rate at 6-month
follow-up was observed in the EBL-treated group.
It should be noted that there are potential AEs that may occur with use of cyanoacrylate.
These include, but are not limited to, sepsis, distal embolic events (e. g. pulmonary,
cerebral), and ulceration at the varix injection site [111 ].
We identified an additional systematic review/meta-analysis evaluating the efficacy
and safety of endoscopic injection of thrombin for GVH [112 ]. Thrombin converts fibrinogen to fibrin, thereby promoting clot production, leading
to hemostasis. Bhurwal et al. included eleven studies (6 retrospective, 2 RCTs, 1
prospective) including 222 patients. Six studies used human thrombin alone, three
studies used bovine thrombin alone, and two studies used a combination of thrombin
and fibrin [112 ]. The investigators reported a pooled early gastric variceal rebleeding rate of 9.3 %
(95 %CI 4.9 % to 17 %) and a late gastric variceal rebleeding rate of 13.8 % (95 %CI
9 % to 20.4 %). The pooled rescue therapy rate after injecting thrombin in bleeding
gastric varices was 10.1 % (95 %CI 6.1 % to 16.3 %). The pooled 6-week gastric variceal-related
mortality rate after injecting thrombin in bleeding gastric varices was 7.6 % (95 %CI
4.5 % to 12.5 %). The pooled AE rate after injecting thrombin in bleeding gastric
varices was 5.6 % (95 %CI 2.9 % to 10.6 %). Because of these limited and disparate
data regarding the role of endoscopic thrombin injection (including both human and
bovine types) for GVH, there is currently inadequate evidence to make any formal recommendation
regarding its use.
Binmoeller and colleagues first described endoscopic ultrasound (EUS)-guided injection
of coils combined with cyanoacrylate for treating GVH in 2011 [113 ]. They reported a gastric variceal obliteration rate of 96 % in a single treatment
session, without signs of cyanoacrylate embolization. Since that initial report, multiple
retrospective studies, two RCTs, and systematic reviews/meta-analyses on this topic
have been published. Mohan et al., in their meta-analysis evaluating EUS-guided therapy
of gastric varices (23 studies; n = 851), reported that the pooled treatment efficacy
was 93.7 % (95 %CI 89.5 % to 96.3 %), gastric variceal obliteration 84.4 % (95 %CI
74.8 % to 90.9 %), gastric variceal recurrence 9.1 % (95 %CI 5.2 % to 15.7 %), and
the early and late rebleeding rates were 7.0 % (95 %CI 4.6 % to 10.7 %) and 11.6 %
(95 %CI 8.8 % to 15.1 %), respectively [114 ]. These rates were comparable with endoscopic glue injection monotherapy (28 studies;
n = 3467) used as a historical comparator. Gastric variceal obliteration was significantly
better with EUS-guided therapy and, on subgroup analysis, EUS-guided coil/glue combination
showed superior outcomes. This study is however significantly limited by the inclusion
of retrospective and heterogeneous studies, and the historical comparators used.
McCarty et al., in their systematic review/meta-analysis evaluating combination therapy
versus monotherapy for EUS-guided treatment of gastric varices (11 studies; n = 536),
reported that, on subgroup analysis, EUS-guided coil embolization plus cyanoacrylate
injection resulted in better technical and clinical success compared with cyanoacrylate
injection alone (100 % vs. 97 % and 98 % vs. 96 %, respectively; both P < 0.001) or coil embolization alone (99 % vs. 97 % and 96 % vs. 90 %, respectively; both P < 0.001) [115 ]. Coil embolization plus cyanoacrylate also resulted in lower AE rates compared with
cyanoacrylate injection alone (10 % vs. 21 %; P < 0.001) and was comparable with coil embolization alone (10 % vs. 3 %; P = 0.06).
AEs may include abdominal pain, fever, pulmonary embolism, and/or procedure-related
bleeding. Overall, EUS combination therapy using coil embolization plus cyanoacrylate
injection appears to be the preferred strategy for the treatment of gastric varices
over EUS‐based monotherapy.
5.3.2 Management of failed endoscopic hemostasis and early recurrent bleeding
ESGE suggests urgent rescue TIPS or BRTO for gastric variceal bleeding when there
is a failure of endoscopic hemostasis or early recurrent bleeding.
Weak recommendation, low quality evidence.
There are very limited high level data (e. g. RCTs) comparing TIPS and BRTO for cases
where endoscopic hemostasis has failed and/or early recurrent gastric variceal bleeding
occurs [116 ]
[117 ]. In summary, BRTO and TIPS have similar technical success rates and AE rates. TIPS
is associated with higher rates of hepatic encephalopathy and BRTO with long-term
aggravation of esophageal varices. Patient selection is important; however, given
the limited quality of comparative data, specific selection criteria are not currently
available.
6 Post-endoscopy management
6 Post-endoscopy management
6.1 Secondary prophylaxis: prevention of recurrent esophageal or gastric variceal
hemorrhage
ESGE recommends that patients who have undergone EBL for acute EVH should be scheduled
for follow-up EBLs at 1- to 4-weekly intervals to eradicate esophageal varices (secondary
prophylaxis).
Strong recommendation, moderate quality evidence.
ESGE recommends the use of NSBBs (propranolol or carvedilol) in combination with endoscopic
therapy for secondary prophylaxis in EVH in patients with ACLD.
Strong recommendation, high quality evidence.
ESGE recommends an individualized approach for secondary prophylaxis of cardiofundal
variceal hemorrhage (GOV2, IGV1) based upon patient factors and local expertise owing
to the current lack of definitive high level evidence regarding specific eradication
therapies for cardiofundal varices (e. g. endoscopic cyanoacrylate injection ± NSBB,
EUS-guided injection of coils plus cyanoacrylate, TIPS, or BRTO) and appropriate treatment
intervals.
Strong recommendation, low quality evidence.
Current guidelines for treating acute EVH recommend EBL is performed at 1- to 2-weekly
intervals over several endoscopy sessions until the varices are eradicated [3 ]
[118 ]
[119 ]. Others have suggested that an EBL interval of less than 3 weeks may be associated
with an increased risk of rebleeding and that a longer interval (> 20 days) may reduce
the risk of treatment-related AEs [120 ]. However, the optimal time interval for EBL sessions remains without consensus owing
to the limited evidence [121 ].
Wang et al. randomly assigned post-acute EVH patients (n = 70) to either monthly or
biweekly EBL sessions to achieve esophageal variceal eradication [122 ]. Patients receiving monthly EBL had similar rebleeding rates (17 % vs. 26 %; P = 0.38) to those receiving biweekly EBL. Both treatment groups had similar rates
of esophageal variceal recurrence and mortality. Moreover, the incidence of post-EBL
ulcers in the monthly treatment group was significantly lower than that in the biweekly
group (11 % vs. 57 %; P < 0.001).
In another RCT involving 90 patients who had all undergone successful initial EBL
and started NSBB therapy, Sheibani et al. compared the effectiveness of 1- and 2-weekly
intervals for EBL in achieving eradication of esophageal varices following acute variceal
hemorrhage [123 ]. Esophageal variceal eradication at 4 weeks was achieved more frequently in the
1-week interval EBL group (37/45 [82 %]) versus the 2-week group (23/45 [51 %]), a
difference of 31 % (95 %CI 12 % to 48 %). Eradication occurred more rapidly in the
1-week group (18.1 vs. 30.8 days), a difference of −12.7 days (95 %CI −20.0 to −5.4 days).
Rebleeding rates at both 4 weeks and 8 weeks, and mortality rates were similar between
the groups. Upper gastrointestinal symptoms (e. g. dysphagia and chest pain) were
more frequent in the 1-week interval EBL group (9 % vs. 2 %).
NSBB therapy is the mainstay of portal hypertension treatment. Beta-adrenergic blockade
decreases the heart rate and reduces splanchnic vasodilation leading to a decrease
in the portal hyperdynamic state [124 ]. The currently recommended first-line treatment to prevent esophageal variceal rebleeding
(secondary prophylaxis) is the combination of endoscopic therapy and NSBB, irrespective
of the presence or absence of ascites/refractory ascites [3 ]
[118 ]
[119 ]. This recommendation is supported by several meta-analyses that compared alternative
treatment combinations and found that the reduction in esophageal variceal rebleeding
rates was superior with combination therapy compared with monotherapy [125 ]
[126 ]
[127 ]
[128 ]. Moreover, this benefit is greater in patients with more severe liver disease (e. g.
Child–Pugh B or C) particularly, in whom combination therapy not only prevents rebleeding,
but also increases survival [129 ].
There is no clear consensus regarding the optimal approach for secondary prophylaxis
of gastric variceal bleeding in patients with ACLD. Recurrent GVH is a frequent occurrence
(up to 45 % at 3 years) despite endoscopic efforts at gastric variceal eradication
[103 ]. Therefore, effective treatment modalities are an ongoing need. NSBBs are recommended
as an adjunctive treatment for gastric varices in patients with concomitant esophageal
varices [103 ]; however, the effectiveness of adding NSBB therapy to endoscopic treatment of gastric
varices to decrease recurrent GVH remains unclear. Neither of the two published RCTs
evaluating the efficacy of adding propranolol [130 ] or carvedilol [131 ] demonstrated a statistically significant benefit on survival or rebleeding.
In addition, a recently published network meta-analysis (nine RCTs with 647 patients
who had a history of GVH and follow-up of more than 6 weeks) compared the efficacy
of available secondary prophylaxis treatments [132 ]. BRTO was associated with a lower risk of rebleeding when compared with NSBB therapy
alone (RR 0.04, 95 %CI 0.01 to 0.26) and endoscopic injection of cyanoacrylate alone
(RR 0.18, 95 %CI 0.04 to 0.77). Moreover, NSBB therapy alone did not demonstrate a
benefit in terms of preventing gastric variceal rebleeding compared with most interventions,
nor reduce mortality compared with endoscopic injection of cyanoacrylate alone (RR
4.12, 95 %CI 1.50 to 11.36) and endoscopic injection of cyanoacrylate plus NSBB (RR
5.61, 95 %CI 1.91 to 16.43). This study suggested that BRTO may be the best intervention
in preventing gastric variceal rebleeding (secondary prophylaxis), whereas an NSBB
given as monotherapy cannot be recommended; however, head-to-head direct comparator
studies are much needed [132 ].
6.2 Use of proton pump inhibitor therapy
ESGE suggests against the routine use of proton pump inhibitors (PPIs) in the post-endoscopic
management of acute variceal bleeding and, if initiated before endoscopy, PPIs should
be discontinued.
Weak recommendation, low quality evidence.
Proton pump inhibitors (PPIs) are often prescribed prior to upper GI endoscopy in
patients with cirrhosis who present with acute UGIH. The rationale for continuing
PPIs after proven EGVH is to reduce the risk of rebleeding from post-EBL or post-injection
ulceration. The frequency of post-EBL bleeding secondary to ulceration is reported
to be between 2.7 % and 5.7 % [133 ]
[134 ]
[135 ]
[136 ] and it appears to be higher following EBL performed in the acute setting, as compared
with prophylactic EBL [137 ]. Shaheen et al., in a small RCT, evaluated the efficacy of PPIs as an adjunct to
elective EBL. The investigators suggested that use of adjunctive PPIs following EBL
may decrease the risk of post-EBL ulcer bleeding and reduce ulcer size [138 ].
In GVH, there are two studies suggesting that the administration of PPIs after the
injection of N-butyl-2-cyanoacrylate may reduce the risk of rebleeding or delay rebleeding;
however, these studies are retrospective, include small numbers of patients, and the
duration/dosage of PPI use was variable [139 ]
[140 ]. Moreover, and importantly, the use of PPIs in cirrhotic patients has been associated
with an increased risk of bacterial infection, especially spontaneous bacterial peritonitis
and infections caused by multidrug-resistant bacteria [141 ]
[142 ]
[143 ]
[144 ].
6.3 Prevention/treatment of hepatic encephalopathy
ESGE recommends the rapid removal of blood from the GI tract, preferably using lactulose,
to prevent or to treat hepatic encephalopathy in cirrhotic patients with acute variceal
hemorrhage.
Strong recommendation, moderate quality evidence.
Hepatic encephalopathy is common in patients with cirrhosis and its prevalence increases
during GI bleeding, to as high as 40 %. This is secondary to hyperammonemia in the
context of blood protein digestion, liver failure, systemic inflammation, and infection.
Hepatic encephalopathy at the time of admission during GI bleeding negatively impacts
outcome and is independently associated with mortality [50 ].
Treatment of hepatic encephalopathy with lactulose improves survival in patients with
cirrhosis and is recommended for patients with GI bleeding and concomitant hepatic
encephalopathy [145 ]
[146 ]. Oral lactulose and/or lactulose enema when the GI bleeding remains uncontrolled
is recommended [145 ]
[146 ]. In two RCTs, lactulose, as compared with no lactulose, has been shown to significantly
reduce hepatic encephalopathy [147 ]
[148 ]. The reduction in hepatic encephalopathy ranged from 14 % to 40 % (P < 0.03) and 3.2 % to 16.9 % (P < 0.02), without any observed effect on patient survival. The use of mannitol has
also been suggested as an effective therapy to reduce hepatic encephalopathy in patients
with GI bleeding [149 ]
[150 ], reinforcing the beneficial role of the rapid removal of nitrogenous waste products
in the prevention of hepatic encephalopathy. Although other ammonium-lowering strategies
(e. g. L-ornithine, L-aspartate, and rifaximin) have been suggested to be as effective
as lactulose in preventing the development of hepatic encephalopathy in patients with
GI bleeding, more studies are needed before these can be recommended [151 ].
