Keywords
endosonography - obstructive jaundice - drainage - EUS-guided biliary drainage
Introduction
Endoscopic ultrasound-guided biliary drainage (EUS-BD) was first reported as an alternative
for failed endoscopic retrograde cholangiopancreatography (ERCP).[1]
[2] Since then, it has been widely spread and is now also used for patients in whom
ERCP is expected to be difficult.[3] Several recent studies have compared EUS-BD and ERCP for primary drainage in ERCP-accessible
cases.[4]
[5]
[6]
[7]
[8]
[9] A systematic review concluded that EUS-BD, which is characterized by no risk of
procedure-related pancreatitis, a short procedure time, and ease of use, is an attractive
primary approach for malignant biliary obstruction in specialized centers that have
expert endoscopists.[10] In particular, EUS-guided choledochoduodenostomy (EUS-CDS) has gained increasing
attention as a primary drainage method due to its direct access route and favorable
outcomes. However, despite its growing adoption in clinical studies, primary EUS-CDS
has not yet been widely implemented in clinical practice. This is likely due to concerns
about procedural safety and the lack of standardized techniques, particularly regarding
adverse event risk. Moreover, evidence remains limited regarding the safety profile
of primary EUS-CDS, especially with respect to early procedure-related adverse events
and their predictors. Existing studies combine different EUS-BD techniques, making
it difficult to isolate risk factors specific to EUS-CDS. Furthermore, there is a
lack of large single-center studies that systematically analyze the technical evolution,
device selection, and procedural nuances that may influence safety in this setting.
To address these gaps, we conducted a retrospective analysis of a large consecutive
cohort undergoing primary EUS-CDS using covered self-expandable metal stents (CSEMS)
at a single high-volume center. Our institution has performed primary EUS-CDS since
2010 and was among the first to report its feasibility and safety.[11] Over time, we have introduced several technical refinements, including the adoption
of forward-viewing (FV) EUS scopes and dilation-free stent delivery systems.
The aim of this study is to evaluate the incidence and predictors of early adverse
events following primary EUS-CDS for malignant distal biliary obstruction. We hypothesize
that procedure-related factors, including scope type and tract dilation method, play
a significant role in early adverse event risk. By elucidating these factors, this
study seeks to inform optimal practice and improve procedural safety in the use of
primary EUS-CDS, potentially facilitating its broader adoption in real-world clinical
settings.
Materials and Methods
Study Design
This study was a single-center retrospective analysis. Of 306 consecutive patients
in whom EUS-CDS was attempted between September 2003 and February 2025, we conducted
a retrospective study of 190 cases of primary EUS-CDS using a CSEMS for malignant
distal biliary obstruction. Some patients included in this study had participated
in previous clinical trials, and consent for the secondary use of their data was appropriately
obtained. Clinical data were retrospectively reviewed, and technical success was assessed
based on an intention-to-treat approach. Informed consent was obtained from all participants
prior to the procedure, and the study received approval from the institutional review
board (approval number: 2024–0-509).
Patient Selection
We included only patients in whom EUS-CDS was chosen as the initial drainage method,
even though ERCP was technically feasible. We excluded patients in whom EUS-CDS was
performed as a rescue procedure after ERCP failure, and those in whom ERCP was not
attempted due to anatomical difficulties such as duodenal stenosis or duodenal stent
placement. Among the 190 patients initially considered for EUS-CDS, 26 cases were
deemed unsuitable (e.g., due to severe ascites or tumor infiltration into the duodenal
bulb) before puncture on preprocedural imaging. As puncture was not performed in these
cases, they were excluded from the intention-to-treat (ITT) analysis ([Fig. 1]).
Fig. 1 Flowchart of patient selection process.
EUS-Guided Choledochoduodenostomy
A total of seven endoscopists performed the EUS-CDS procedures. All patients were
sedated intravenously and were administered prophylactic antibiotics via the same
route. The EUS-CDS technique has evolved over time. In the early period,[11] it was primarily performed using an oblique-viewing (OV) EUS scope (GF-UCT240, GF-UCT260;
Olympus Medical Systems, Tokyo, Japan) or a FV EUS scope (TGF-UC260J, Olympus). The
extrahepatic bile duct was punctured using a 22-G fine needle, after which contrast
medium was injected through the needle to evaluate the biliary tree. A needle knife
(Zimmon Needle Knife Papillotome; Cook Medical, Bloomington, Indiana, United States)
was then inserted into the extrahepatic bile duct under real-time EUS guidance. The
tract was dilated using 6- and 9-Fr tapered biliary dilation catheters (Soehendra
Biliary Dilation catheters; Cook Medical) over the guidewire. Finally, a fully or
partially covered self-expandable metallic stent (CSEMS), 10 mm in diameter and 4
or 6 cm in length (Wallflex, Boston Scientific Co., Natick, Massachusetts, United
States; or X-SuitNIR, Olympus Medical Systems) was inserted. Following stent placement,
the distal end was reoriented from the oral to the anal direction using either endoscopic
manipulation or guidewire assistance.
In the intermediate period (after 2011), coaxial electric cautery became available,
and the standard approach involved puncturing with a 19-G fine needle, followed by
tract dilation using a diathermic dilator (Cysto-Gastro-Set; Endo-Flex, Voerde, Germany)
over the guidewire and placement of an FCSEMS. Regarding endoscopy, both OV and FV
EUS scopes were employed up to 2013, after which FV EUS scopes became the mainstay.
In the technique used currently (since 2020),[12] the extrahepatic bile duct was punctured using a 19-G Franseen needle. After aspirating
bile, contrast medium was injected to visualize the biliary tree and verify the position
of the perihilar duct. Without prior tract dilation, an FCSEMS was delivered through
the duodenal bulb over a guidewire. Regarding the choice of FCSEMS, either an 8 mm × 6 cm
BileRush Advance (7-Fr delivery system; PIOLAX, Yokohama, Japan) or an 8 mm × 6 cm
HANAROSTENT Benefit (5.9-Fr delivery system; Boston Scientific Co.) was used.
Within 24 hours postprocedure, all patients underwent blood tests and imaging, either
computed tomography or plain radiography, to evaluate for potential adverse events,
including stent migration or bile leakage, and to ensure the distal end of the stent
was correctly oriented in the anal direction.
Outcome Measurements and Definitions
In cases in which EUS-CDS was deemed unsuitable due to conditions such as severe ascites
and duodenal bulb infiltration, the procedure was discontinued before puncture and
these patients were excluded from the analysis. Data for patients in whom puncture
was performed were included, with technical success defined as the proper placement
of CSEMS. Clinical success was defined as improvement of symptoms related to biliary
obstruction, such as jaundice or fever, combined with a decrease of total bilirubin
or alkaline phosphatase to less than half of the highest preprocedural levels within
14 days.[12] Early adverse events were defined as complications associated with the procedure
that developed within 14 days after its completion and were evaluated based on the
American Society for Gastrointestinal Endoscopy lexicon.[13]
Statistical Analysis
All data were analyzed using StatMate V statistical software (ATMS). Categorical parameters
were compared using a chi-squared test, and multivariate analysis was performed by
logistic regression analysis. Differences were considered statistically significant
when p-values were less than 0.05.
Results
The patient characteristics are summarized in [Table 1]. The median age was 67 years (range, 37–94 years) and 103 were male. The primary
disease was pancreatic cancer in 159 of 190 (83.7%) cases.
Table 1
Patient characteristics
|
|
N = 190
|
|
Age, median [range]
|
|
66 [37–94]
|
|
Sex
|
|
Male
|
103
|
|
Female
|
87
|
|
Primary disease
|
|
Pancreatic cancer
|
159
|
|
Lung cancer
|
7
|
|
Ampullary cancer
|
5
|
|
Gallbladder cancer
|
3
|
|
Breast cancer
|
3
|
|
Colon cancer
|
2
|
|
Gastric cancer
|
2
|
|
Other
|
9
|
|
Ascites
|
|
Absent
|
124
|
|
Present
|
66
|
EUS-CDS was deemed unsuitable before puncture in 26 of 190 patients (13.7%). The reasons
for ineligibility and the alternative drainage methods are summarized in [Table 2]. The most common reason was the presence of ascites along the puncture route (n = 9). The alternative drainage methods were transpapillary endoscopic biliary stenting
(EBS) (n = 21) and EUS-guided hepaticogastrostomy (EUS-HGS) (n = 5). [Table 3] lists the equipment used in EUS-CDS.
Table 2
Reasons for EUS-CDS ineligibility and alternative drainage
|
N = 26
|
|
Reason for EUS-CDS ineligibility
|
|
Ascites along the puncture route
|
9
|
|
Duodenal invasion
|
5
|
|
Duodenal bulb ulcer
|
2
|
|
Insufficient distal bile duct length below the hilum for safe stent placement
|
2
|
|
Vessel along the puncture route
|
2
|
|
Anatomical deformation
|
2
|
|
Gallbladder along the puncture route
|
1
|
|
Cystic duct along the puncture route
|
1
|
|
Biliary invasion
|
1
|
|
Biliary bleeding
|
1
|
|
Alternative drainage
|
|
EBS
|
21
|
|
EUS-HGS
|
5
|
Abbreviations: EUS-CDS, endoscopic ultrasound-guided choledochoduodenostomy; EBS,
endoscopic biliary stenting; EUS-HGS, EUS-guided hepaticogastrostomy.
Table 3
Equipment used in EUS-CDS
|
Scope
|
FV
|
148
|
(77.9%)
|
|
OV
|
42
|
(22.1%)
|
|
Needle
|
19-G FNA needle
|
88
|
(46.3%)
|
|
19-G FNB needle
|
56
|
(31.1%)
|
|
22-G FNA needle
|
18
|
(9.5%)
|
|
Needle knife
|
2
|
(1.1%)
|
|
Discontinued before puncture
|
26
|
(14.4%)
|
|
Dilator
|
Needle-knife and mechanical dilator
|
16
|
(9.8%)
|
|
Electric cautery
|
85
|
(51.3%)
|
|
Without tract dilation
|
57
|
(34.8%)
|
|
Mechanical dilator
|
2
|
(1.2%)
|
|
Drill dilator
|
1
|
(0.6%)
|
|
Discontinued before dilation
|
3
|
(1.8%)
|
|
Stent
|
Braided CSEMS (8 mm)
|
48
|
(29.8%)
|
|
Braided CSEMS (10 mm)
|
37
|
(23.0%)
|
|
Braided CSEMS (12 mm)
|
5
|
(3.1%)
|
|
Laser-cut CSEMS (10 mm)
|
69
|
(42.9%)
|
|
Discontinued before stenting
|
2
|
(1.2%)
|
Abbreviations: CSEMS, covered self-expandable metal stent; EUS-CDS, endoscopic ultrasound-guided
choledochoduodenostomy; FNA, fine-needle aspiration; FNB, fine-needle biopsy; FV,
forward-viewing ultrasound endoscope; OV, oblique-viewing ultrasound endoscope.
An ITT analysis of the technical success rate in the remaining 164 cases eligible
for EUS-CDS found a technical success rate of 97.0% (159/164). [Table 4] summarizes the clinical outcomes. Among the five unsuccessful cases, three were
discontinued after puncture alone due to insufficient distal bile duct length below
the hilum for safe stent placement, and two due to difficulty in dilation. The alternative
drainage methods were transpapillary EBS (n = 3) and EUS-HGS (n = 2).
Table 4
Clinical outcomes of EUS-CDS
|
Technical success rate, % (n/N)
|
97.0
|
(159/164)
|
|
Clinical success rate, % (n/N)
|
97.5
|
(155/159)
|
|
CBD/CHD diameter, median (mm) [range]
|
13.0
|
[4.8–24.0]
|
|
Early adverse event rate (≤14 days), % (n/N)
|
4.9
|
(8/164)
|
|
Late adverse event rate (>14 days), % (n/N)
|
3.8
|
(6/159)
|
Abbreviations: CBD, common bile duct; CHD, common hepatic duct; EUS-CDS, endoscopic
ultrasound-guided choledochoduodenostomy.
The early adverse event rate was 4.9% (8/164). [Table 5] lists the events and grades. Some patients had more than one early adverse event.
One severe case of acute cholangitis developed due to mucosal double penetration and
required prolonged hospitalization. There were no cases of mortality. In addition,
late adverse events occurred in 3.8% of cases (6/159), consisting of four cases of
cholecystitis and two cases of liver abscess.
Table 5
Early adverse events
|
Event
|
n
[a]
|
Grade (n)
|
|
Acute cholangitis
|
3
|
Severe 1/Moderate 1/Mild 1
|
|
Peritonitis
|
2
|
Mild 2
|
|
Mucosal double penetration
|
2
|
Severe 1/Moderate 1
|
|
Acute cholecystitis
|
2
|
Moderate 2
|
|
Bleeding
|
2
|
Moderate 2
|
a Duplicate entry.
[Table 6] summarizes the incidence of early adverse events for each dilation method. The incidence
varied greatly according to the dilation technique used. The rate was significantly
higher in the group treated with a needle knife and a mechanical dilator (18.8%) than
in the coaxial electric cautery group (4.7%, p = 0.042) and the group without tract dilation (1.8%, p = 0.008). There was no statistically significant difference in adverse event rates between
the coaxial cautery group and the group without tract dilation (p = 0.349).
Table 6
Early adverse events by dilation method
|
Method
|
Total cases
|
Early adverse events
|
%
|
p-Value[a]
|
|
Needle-knife and mechanical dilator
|
16
|
3
|
18.8
|
0.042[b]
|
|
Coaxial electrocautery
|
85
|
4
|
4.7
|
0.008[c]
|
|
Without tract dilation
|
57
|
1
|
1.8
|
0.349[d]
|
a Chi-square test.
b
p = 0.042 needle-knife and mechanical dilator versus coaxial electrocautery.
c
p = 0.008 needle-knife and mechanical dilator versus without tract dilation.
d
p = 0.349 coaxial electrocautery vs. without tract dilation.
[Table 7] summarizes the factors associated with early adverse events (primary disease, presence
of ascites, bile duct diameter, type of endoscope, and whether tract dilation was
performed). Univariate analysis revealed that use of an OV EUS scope was significantly
associated with early adverse events (OR: 4.392, 95% CI: 1.03–18.64, p = 0.030). The presence of ascites also showed a trend toward increased risk (OR:
3.576, 95% CI: 0.82–15.58, p = 0.072), although it did not reach statistical significance. No other factors were
significantly associated with early adverse events. Variables showing a p-value less than 0.10 in the univariate analysis were subsequently entered into a multivariate
logistic regression model to determine independent predictors of early adverse events.
In multivariate analysis, the use of an OV EUS scope was independently associated
with early adverse events (OR: 5.153, 95% CI: 1.15–22.92, p = 0.031). The presence of ascites did not reach statistical significance (OR: 4.202,
95% CI: 0.92–19.18, p = 0.063).
Table 7
Risk factors associated with early adverse events
|
Factor
|
Events
|
n
|
Univariate
|
Multivariate
|
|
OR
|
95% CI
|
p-Value
|
OR
|
95% CI
|
p-Value
|
|
Primary disease
|
PC
|
7
|
134
|
1.322
|
0.15–11.24
|
0.797
|
|
|
|
|
Others
|
1
|
25
|
|
Ascites
|
Present
|
5
|
53
|
3.576
|
0.82–15.58
|
0.072
|
4.202
|
0.92–19.18
|
0.063
|
|
Absent
|
3
|
106
|
|
CBD/CHD diameter
|
≤10 mm
|
2
|
42
|
0.925
|
0.17–0.4.77
|
0.925
|
|
|
|
|
>10 mm
|
6
|
117
|
|
Scope
|
OV
|
4
|
32
|
4.392
|
1.03–18.64
|
0.030
|
5.153
|
1.15–22.92
|
0.031
|
|
FV
|
4
|
127
|
|
Dilation
|
With
|
7
|
102
|
4.126
|
0.49–34.41
|
0.157
|
|
|
|
|
Without
|
1
|
57
|
Abbreviations: CBD, common bile duct; CHD, common hepatic duct; CI, confidence interval;
FV, forward-viewing ultrasound endoscope; OR, odds ratio; OV, oblique-viewing ultrasound
endoscope; PC, pancreatic cancer.
Discussion
This study evaluated the efficacy and safety of primary EUS-CDS using a CSEMS for
malignant biliary obstruction and investigated the factors associated with early adverse
events. Several studies published in recent years have compared EUS-CDS and ERCP as
primary drainage methods, which indicates that EUS-CDS is no longer used only for
cases in which ERCP is difficult or unsuccessful.[4]
[6]
[7]
[8]
[9] However, research focusing on the safety of primary EUS-CDS and the factors related
to early adverse events remains scarce. In our series, primary EUS-CDS had high success
rates and a low early adverse event rate of 4.9%, with the type of endoscope emerging
as a significant factor.
Our findings demonstrate that the type of endoscope used, specifically the use of
an OV EUS scope, was significantly associated with early adverse events in both univariate
and multivariate analyses. Previous studies have reported that EUS-CDS is a technically
feasible and clinically effective alternative to ERCP, particularly in expert centers.[10]
[14] However, safety concerns, particularly regarding adverse events such as bile leakage,
perforation, and stent misplacement, remain an important consideration. Our data support
the growing body of evidence that procedure-related factors, rather than patient characteristics
alone, may significantly influence safety outcomes. In our cohort, the use of an OV
EUS endoscope was associated with a 5.2-fold increased risk of early adverse events
(OR: 5.153, 95% CI: 1.15–22.92, p = 0.031), compared with the use of an FV EUS scope. Because this study spans a long
period (2003–2025), it is important to acknowledge that procedural techniques and
devices have evolved substantially over time. OV scopes were primarily used in the
early period of our series; this risk factor may therefore also reflect improvements
in technique and equipment over time. Nonetheless, even after accounting for the dilation
method, scope choice remained significant, reinforcing that the FV scope inherently
offers a safety advantage.
Matsumoto et al[15] demonstrated that the use of an FV EUS scope can prevent double penetration of the
gastrointestinal tract during EUS-CDS. In contrast, with an OV EUS scope, the scope
and the needle are misaligned, causing the needle to enter the gastrointestinal wall
at an angle. This can lead to double penetration of the mucosa or reduced control
during device advancement.[16] Kawakami et al[17] also reported cases of double penetration during EUS-CDS with an OV EUS scope. They
concluded that caution is required to avoid its occurrence when using an OV EUS scope,
and that using an FV EUS scope may help prevent this complication. The FV EUS scope
addresses these challenges by providing better alignment of the needle with the endoscope's
axis and clearer endoscopic visualization. This enables safer and more accurate stent
placement.[18]
Although the presence of ascites was associated with a higher odds ratio for adverse
events in univariate analysis (OR: 3.576, 95% CI: 0.82–15.58, p = 0.072), this association did not reach statistical significance and was not confirmed as
an independent risk factor in multivariate analysis (OR: 4.202, 95% CI: 0.92–19.18,
p = 0.063). Nevertheless, ascites is theoretically associated with an increased risk
of bile leakage into the peritoneal cavity and is generally considered a relative
contraindication for EUS-BD.[19] In this study, EUS-CDS was performed as the primary drainage procedure in patients
who were also technically eligible for ERCP. Importantly, 26 cases were deemed ineligible
for EUS-CDS prior to the procedure, with the most common reason being the presence
of ascites along the intended puncture route (n = 9). Our findings suggest that, although ascites may not be an independent predictor,
careful patient selection and procedural planning remain essential in such cases.
There were no significant differences in adverse events with or without dilation,
but interestingly, the choice of tract dilation technique also influenced early adverse
event rates. Use of a needle-knife and a mechanical dilator had the highest adverse
event rate (18.8%), significantly higher than coaxial electrocautery (4.7%) and procedures
performed without tract dilation (1.8%). Importantly, performing EUS-CDS without tract
dilation was associated with the lowest adverse event rate, without compromising technical
or clinical success. These results highlight the importance of device selection and
support a move to safer, more controlled dilation techniques such as coaxial electrocautery
or even dilation-free approaches, when technically feasible.
Notably, our observed technical success rate (97.0%) and clinical success rate (97.5%)
are slightly higher than those typically reported in studies of primary EUS-CDS (∼90–95%).[4]
[8]
[9] These findings emphasize that, when performed by experienced endoscopists, primary
EUS-CDS can achieve excellent outcomes.
More importantly, the early adverse event rate in our study was 4.9%, substantially
lower than the ∼10 to 15% reported in many prior series.[4]
[8]
[9] This improvement likely reflects the evolution of procedural techniques, including
the use of FV scopes, minimal or no tract dilation, and careful patient selection
at our center. Notably, there were no procedure-related deaths, and most adverse events
were classified as mild or moderate in severity, further underscoring the safety of
this approach.
This study is subject to several limitations. Primarily, it was a retrospective single-center
analysis, which may limit the generalizability of the results. Second, although the
procedures were performed by experienced endoscopists, variations in operator technique
could have influenced the outcomes. Third, due to the relatively low number of adverse
events, the statistical power for detecting associations with some variables may have
been limited.
Conclusion
In conclusion, our findings indicate that the use of an OV EUS scope is an independent
risk factor for early adverse events in EUS-CDS, and that the method of tract dilation
significantly influences the rate of early adverse events. These results highlight
the importance of procedural planning and suggest that using an FV EUS scope and the
selection of an appropriate dilation technique, or the decision to avoid dilation
when feasible, may lead to improved safety in EUS-CDS. Appropriate patient selection
is also crucial, as careful evaluation of anatomical and clinical factors, such as
the presence of severe ascites, can help reduce the risk of early adverse events.
These findings support the preferential use of FV EUS scope when available and advise
against traditional needle-knife dilation in favor of safer alternatives, such as
no tract dilation. Finally, prospective studies and multicenter data are warranted
to validate these risk factors and further refine best practices in primary EUS-CDS.
