1Department of Pediatric Intensive Care, Royal Hospital, Muscat, Oman; 2Department of Research, Oman Medical Specialty Board, Muscat, Oman
*Corresponding Author’s e-mail: dr.samishaikh@gmail.com

This work is licensed under a Creative Commons Attribution-NoDerivatives 4.0 International License.

abstract: Objectives: A modified Blalock-Taussig (mBT) shunt procedure is a common palliative surgery used to 
treat infants and children with cyanotic congenital heart disease (CCHD). This study aimed to report the outcomes 
of infants and children undergoing mBT shunt procedures in Oman. In addition, risk factors associated with early 
mortality, inter-stage mortality and reintervention were assessed. Methods: This retrospective cohort study was 
conducted from January 2016 to December 2018 at the National Heart Centre, Muscat, Oman. All paediatric patients 
with CCHD undergoing mBT shunt procedures as a primary palliative procedure during this period were included. 
Data were retrieved from electronic hospital records. Kaplan-Meier survival curves were used to describe overall 
survival. Results: A total of 50 infants and children were included in this study. The in-hospital mortality and inter-
stage mortality rates were 10% and 6.7%, respectively. Preoperative mechanical ventilation (odds ratio [OR] = 3.00, 
95% confidence interval [CI]: 1.98–4.76; P = 0.007) and cardiopulmonary bypass (OR = 4.09, 95% CI: 2.44–6.85; P = 
0.002) were significant risk factors for early mortality. In-hospital and interval surgical reintervention rates were 12% 
and 13.3%, respectively. Following the primary shunt procedure, the median time to second-stage surgery was 15.5 
months (range: 5.0–34.0 months). Conclusion: The findings of this study support those reported in international 
research regarding the risks associated with mBT shunt surgeries. In particular, preoperative mechanical ventilation 
and cardiopulmonary bypass were significant risk factors for early mortality. 

Keywords: Pediatrics; Congenital Heart Diseases; Cardiovascular Surgical Procedures; Modified Blalock-Taussig 
Procedure; Patient Outcome Assessment; Hospital Mortality; Risk Factors; Oman.

Outcomes of Infants Undergoing Modified 
Blalock-Taussig Shunt Procedures in Oman

A retrospective study

*Samiuddin Shaikh,1 Khaloud S. Al-Mukhaini,1 Abdul Hakeem Al-Rawahi,2 Omer Al-Dafie1

Sultan Qaboos University Med J, August 2021, Vol. 21, Iss. 3, pp. 457–464, Epub. 29 Aug 21
Submitted 9 May 20
Revision Req. 9 Jul 20; Revision Recd. 6 Aug 20
Accepted 26 Aug 20 https://doi.org/10.18295/squmj.8.2021.125

CLINICAL & BASIC RESEARCH

Advances in Knowledge
- Outcomes following modified Blalock-Taussig (mBT) shunt procedures vary worldwide. To the best of the authors’ knowledge, this is the 

first study to report outcomes following mBT shunt procedures performed in Oman. 
- This study identifies various risk factors for mortality following this procedure in the local population.
- These findings provide a baseline for future comparative analysis at both the regional and international level.

Application to Patient Care
- Knowledge of likely outcomes following mBT shunt procedures in a local setting will be useful to help the parents of infants and children 

with cyanotic congenital heart disease make informed treatment choices.
- Moreover, the findings of this study may result in modifications to clinical practice, thereby improving outcomes. In particular, certain 

high-risk patient categories warrant extra vigilance, such as those requiring preoperative mechanical ventilation or intraoperative 
cardiopulmonary bypass.

In oman, the incidence of congenital heartdisease is approximately 7.1 per 1,000 live births; of these, 21.7% are diagnosed with cyanotic 
congenital heart disease (CCHD).1 Many infants 
with CCHD and inadequate pulmonary blood flow 
require palliative interventions early in life in order to 
alleviate severe cyanosis.2 These include maintaining 
the patency of the ductus arteriosus, either by using 
a cardiac catheter to percutaneously insert a stent or 
by surgically creating a systemic-to-pulmonary artery 
shunt.3

A modified Blalock-Taussig shunt (mBT) is the 
most common type of systemic-to-pulmonary artery 
shunt wherein the ipsilateral innominate or subclavian 
artery is connected to the pulmonary artery using a 

prosthetic graft made of polytetrafluoroethylene.3 
However, despite considerable improvements in 
congenital heart surgery in recent years, mBT shunt 
procedures are still associated with significant 
morbidity and mortality.4–6 For instance, in-hospital 
mortality rates following mBT shunt procedures range 
from 7.3–9.8%.4,5 Moreover, even after discharge, 
between 5–13.9% of patients do not survive long 
enough to undergo the next stage of surgery in the 
form of a Glenn shunt or total correction procedure.5,6

Various risk factors have been identified as 
resulting in worse outcomes for patients receiving 
mBT shunts, including the age and weight of the 
child at the time of surgery, the size of the shunt, 
pulmonary atresia with intact ventricular septum 

https://creativecommons.org/licenses/by-nd/4.0/


Outcomes of Infants Undergoing Modified Blalock-Taussig Shunt Procedures in Oman 
A retrospective study

458 | SQU Medical Journal, August 2021, Volume 21, Issue 3

(PAIVS) and preoperative shock or acidosis.5,7–9 The 
immediate postoperative period following insertion of 
the mBT shunt is when the patient is most vulnerable. 
According to Petrucci et al., 33% of deaths in neonates 
undergoing mBT shunt procedures occurred within 
24 hours of surgery, with 75% occurring within the 
first month.10 Moreover, the procedure can result in 
complications such as pulmonary overcirculation 
(30%) and shunt failure including shunt thrombosis 
or stenosis (8–23%).11,12 Risk factors for shunt failure 
include the use of small shunts or a central shunt, 
as well as postoperative extracorporeal membrane 
oxygenation (ECMO) support.11,12 

To the best of the authors’ knowledge, no 
established data have yet been reported regarding the 
outcomes of mBT shunt procedures among paediatric 
cases in Oman, particularly in terms of morbidity and 
mortality. As such, this study aimed to determine 
outcomes of infants with CCHD following mBT 
shunt procedures in Oman and evaluate risk factors 
associated with early mortality, inter-stage mortality 
and reintervention.

Methods

This retrospective cohort study was conducted from 
January 2016 to December 2018 at the National Heart 
Centre in Muscat, Oman. This centre receives referrals 
from all over the country for infants and children with 
congenital heart diseases who require assessment, 
surgical intervention or cardiac catheterisation. 
All neonates and infants who underwent mBT 
shunt procedures as a primary palliative procedure 
during the study period were identified using the 
surgical database. Patients were excluded if they had 
undergone mBT shunt surgeries as part of a Norwood 
procedure—i.e. an aortic arch reconstruction plus 
atrial septectomy and mBT shunt or a right ventricle-
to-pulmonary artery conduit, usually performed 
in cases of hypoplastic left heart syndrome—or to 
alleviate hypoxia after pulmonary artery banding.

Information regarding the patients’ demographic 
characteristics, underlying anatomical details, surgical 
notes, postoperative clinical notes, outpatient follow-
up visits and outcome data were collected from the 
surgical database and electronic hospital record 
system. Patients were classified as duct-dependent if 
they required an infusion of prostaglandins to ensure 
ductus arteriosus patency and/or if the patent ductus 
arteriosus was the main source of pulmonary blood 
flow. All patients were followed-up either until they 
underwent the next stage of surgery—consisting of 
either a total correction or stage 2 palliation (i.e. a 

Glenn procedure)—or for a minimum of one year after 
the index procedure (i.e. December 2019).

Data were analysed using the Statistical Package 
for the Social Sciences (SPSS), Version 22.0 (IBM Corp., 
Armonk, New York, USA). The outcome variables of 
interest included early mortality, inter-stage mortality 
and survival to next stage of surgery. Early mortality 
was defined as mortality occurring within 30 days of 
the index operation, while inter-stage mortality (i.e. 
interval mortality) was defined as mortality occurring 
between 30 days after the index operation and the 
next surgical stage. Survival to the second stage 
of surgery was defined as survival from the initial 
surgery to the next planned surgical intervention. 
Categorical variables were presented as frequencies 
and percentages, while continuous variables were 
presented as medians and interquartile ranges (IQRs). 
Kaplan-Meier survival curves were used to describe 
overall survival. Univariate associations were assessed 
using a Chi-squared test, along with odds ratios 
(ORs) and 95% confidence intervals (CIs) wherever 
applicable. A P value of <0.050 was considered 
statistically significant.

Ethical approval for this study was obtained 
through the institutional ethical approval board of 
the Royal Hospital as well as the Centre of Studies 
and Research of the Ministry of Health in Oman 
(SRC#120/2018 code #9368). The need for patient 
consent was waived in view of the retrospective nature 
of the study. 

Results

A total of 50 paediatric patients with CCHD underwent 
mBT shunt procedures as a first palliative surgery 
during the study period. The primary indication 
for the procedure was to provide a stable source of 
pulmonary blood flow sufficient to maintain systemic 
oxygen saturation (SpO2) at 75–85%. The median age 
at surgery was 22.5 days (IQR: 7.2–90.0 days) and the 
median weight was 3.2 kg (IQR: 2.7–4.2 kg). Over 
half of the patients (n = 26; 52%) were neonates (i.e. 
≤28 days old). The underlying diagnosis was either 
single ventricle (n = 25; 50%) or biventricular (n = 
25; 50%) defects. A total of 20 patients (40%) received 
preoperative mechanical ventilation. Nine patients 
(18%) had previously undergone failed attempts at 
cardiac catheterisation (e.g. ductal stents) prior to the 
mBT shunt procedure [Table 1].

Among those with single ventricle defects, the 
majority had PAIVS (n = 7; 28%), followed by tricuspid 
atresia and pulmonary atresia (n = 4; 16%), tricuspid 
atresia and restrictive ventricular septal defect (VSD; 



Samiuddin Shaikh, Khaloud S. Al-Mukhaini, Abdul Hakeem Al-Rawahi and Omer Al-Dafie

Clinical and Basic Research | 459

n = 4; 16%), unbalanced atrioventricular septal defect 
(AVSD) and hypoplastic right ventricle (n = 2; 8%), 
pulmonary atresia and double-inlet left ventricle 
(n = 2; 8%), pulmonary atresia with AVSD and total 
anomalous pulmonary venous connection (n = 2; 
8%) and other defects (n = 4; 16%). For those with 
biventricular defects, the most common underlying 
diagnosis was pulmonary atresia and VSD (n = 10; 
40%), followed by tetralogy of Fallot (n = 7; 28%), 
dextro-transposition of the great arteries with VSD 
and pulmonary stenosis (n = 3; 12%), AVSD and 
tetralogy of Fallot (n = 2; 8%) and other defects (n = 
3; 12%). 

A sternotomy was the most common approach 
for the surgery (n = 45; 90%). A total of 16 patients 
(32%) required cardiopulmonary bypass during the 
shunt procedure due to haemodynamic instability or 
for other concomitant procedures. The innominate 
or subclavian artery was used as the proximal arterial 
connection in 35 cases (70%). The median shunt size 
was 4 mm (range: 3–5 mm), with a mean shunt-to-
weight ratio of 1.25 in neonates. The median duration 
of mechanical ventilation, length of stay in intensive 
care and total length of postoperative hospital stay 
was two days (range: 0–19 days), six days (range: 1–31 
days) and 13 days (range: 1–76 days), respectively 
[Table 2]. Upon arrival to intensive care, all patients 
received an infusion of unfractionated heparin and 
were subsequently transitioned to low-dose aspirin 
once they could be fed enterally. After the primary 
shunt procedure, three patients (6%) required ECMO 
support and six (12%) had to undergo shunt revision 
during the same hospitalisation period. 

A total of five patients died within 30 days of the 
index operation; subsequently, three of the remaining 
45 patients died after discharge but before the second- 

Table 1: Baseline characteristics of infants and children 
with cyanotic congenital heart disease undergoing modified 
Blalock-Taussig shunt procedures in Oman (N = 50)

Characteristic n (%)

Age in days at time of surgery

≤28 26 (52)

>28 24 (48)

Median (IQR) 22.5 (7.2–90.0) 

Gender

Male 27 (54)

Female 23 (46)

Weight in kg at time of surgery

<2.5 7 (14)

≥2.5 43 (86)

Median (IQR) 3.2 (2.7–4.2)

Underlying diagnosis

Single ventricle defect 25 (50)

Biventricular defect 25 (50)

Circulation status

Duct-dependent 30 (60)

Non-duct-dependent 20 (40)

Preoperative mechanical ventilation

Yes 20 (40)

No 30 (60)

Preoperative acidosis*

Yes 9 (18)

No 41 (82)

Unsuccessful preoperative cardiac catheter interventions

Yes 9 (18)

No 41 (82)

IQR = interquartile range. *Defined by an arterial blood pH value of <7.3.

Table 2: Surgical details and outcomes of infants and children 
with cyanotic congenital heart disease undergoing modified 
Blalock-Taussig shunt procedures in Oman (N = 50)

Variable n (%)

Surgical approach

Sternotomy 45 (90)

Thoracotomy 5 (10)

Cardiopulmonary bypass

Yes 16 (32)

No 34 (68)

Arterial connection

Innominate/subclavian 35 (70)

Other 15 (30)

Other surgical/non-surgical details

Median shunt size in mm (range) 4 (3–5)

Mean postoperative SpO2 in % ± SD 82.6 ± 6.3

Median duration of postoperative MV in 
days (range)

2 (0–19)

Median duration of ICU stay in days 
(range)

6 (1–31)

Median duration of hospital stay in days 
(range)

13 (1–76)

Median age at second-stage surgery in 
months (range)

15.5 (5–34) 

SpO2 = oxygen saturation; SD = standard deviation; MV = mechanical 
ventilation; ICU = intensive care unit.



Outcomes of Infants Undergoing Modified Blalock-Taussig Shunt Procedures in Oman 
A retrospective study

460 | SQU Medical Journal, August 2021, Volume 21, Issue 3

stage surgery, resulting in early mortality and inter-
stage mortality rates of 10% and 6.7%, respectively. Of 
the five early mortalities, four (80%) had single ventricle 
defects and one (20%) had biventricular defects. 
The biventricular patient died due to myocardial 
dysfunction and low cardiac output syndrome on 
the sixth postoperative day. Among the four early 
mortalities in the single ventricle group, two (50%) 
died due to myocardial dysfunction, one (25%) due 
to septic shock and one (25%) due to preoperative 
hypoxic-ischaemic encephalopathy and cardiac arrest 
during an attempt at ductal stenting. All three patients 
who died during the inter-stage period had single 
ventricle defects; of these one (33.3%) died due to a 
chest infection and sepsis, while cause of death could 
not be determined in the other two patients (66.7%) as 
they died at home. 

During the inter-stage period, in addition to the 
three patients (6.7%) who died, one patient (2.2%) 
was labelled as not suitable for further surgeries and 
three patients (6.7%) were lost to follow-up. The 
median interval before the second stage of surgery 

was 15.5 months (range: 5.0–34.0 months). Overall, 
11 patients (24.4%) who survived >30 days from the 
index operation required reintervention in the form of 
either surgical shunt revision (n = 6; 54.5%) or catheter 
interventions (n = 5; 45.5%). Most of these interventions 
were performed for patients with biventricular defects 
(n = 9; 81.8%) and those with an underlying diagnosis of 
pulmonary atresia and VSD (n = 8; 72.7%). Differences 
in baseline variables and outcomes between the single 
ventricle and biventricular groups are shown in Table 3. 

The majority of in-hospital deaths occurred 
within the first 10 days of surgery [Figure 1]. According 
to the univariate analysis, preoperative mechanical 
ventilation (OR = 3.00, 95% CI: 1.98–4.76; P = 0.007) 
and intraoperative cardiopulmonary bypass (OR = 4.09, 
95% CI: 2.44–6.85; P = 0.002) were the only statistically 
significant risk factors for in-hospital mortality. While 
other factors such as prematurity and underlying 
genetic conditions showed an increased association 
with in-hospital mortality, these differences were not 
statistically significant [Table 4].

Table 3: Outcomes according to diagnosis among infants and children with cyanotic congenital heart disease undergoing 
modified Blalock-Taussig shunt procedures in Oman (N = 50)

Variable Type of diagnosis, n (%) P value

Single ventricle (n = 25) Biventricular (n = 25)

Median age in days at time of surgery (IQR) 13 (4–50) 74 (15–107) 0.020

Median weight in kg at time of surgery (IQR) 3.1 (2.6–3.6) 3.4 (2.9–5.2) 0.271

Early mortality* 4 (16) 1 (4) 0.048

Inter-stage mortality† 3 (12) 0 (0)

Median age at second-stage surgery in months (IQR) 12 (6.8–14) 22 (16–24) 0.019

Reintervention during initial hospitalisation‡ 2 (8) 4 (16) 0.049

Reintervention during the interval period§ 2 (8) 9 (36)

IQR = interquartile range.
*Defined as mortality occurring within 30 days of the index operation.  †Defined as mortality occurring between 30 days after the index operation and 
the next surgical stage.  ‡Surgical shunt revision.  §Surgical shunt revision or catheter intervention.

Figure 1: Kaplan-Meier curves showing (A) overall survival and (B) hazard of death after index surgery among infants 
and children with cyanotic congenital heart disease undergoing modified Blalock-Taussig shunt procedures in Oman 
(N = 50).



Samiuddin Shaikh, Khaloud S. Al-Mukhaini, Abdul Hakeem Al-Rawahi and Omer Al-Dafie

Clinical and Basic Research | 461

Discussion

In this study, the rate of in-hospital mortality among 
paediatric CCHD cases following primary mBT shunt 
procedures was 10%, while the rate of inter-stage 
mortality was 6.7%. These results are in line with 
those reported in the literature.7,11 Indeed, several 
studies have indicated a paradoxical rise in mortality 
following mBT shunt procedures in recent years; for 
instance, Dorobantu et al. observed that overall 30-day 

mortality increased from 5.1% between 2000–2006 to 
9.8% between 2007–2012, while Bove et al. reported a 
rise in mortality from 7% between 1995–2002 to 11% 
between 2002–2013.5,6 

Brown et al. noted that systemic-to-pulmonary 
artery shunt procedures were the only type of cardiac 
surgery to demonstrate increased mortality in a 
large national paediatric population.13 A number of 
factors could explain this disturbing phenomenon. 
First, it appears that fewer patients with biventricular 
defects (especially those with tetralogy of Fallot) are 
offered mBT shunts as a treatment option.5,11 Second, 
palliative shunt surgery may be employed in more 
complex cases such as those involving underlying 
univentricular heart defects. Third, it is possible that 
cardiac catheterisation is used with greater frequency 
among patients with suitable anatomies, thus resulting 
in surgical shunt procedures being reserved for those 
with more complex or challenging anatomies.5,11

Patients with single ventricle defects have a 
high risk of adverse outcomes following mBT shunt 
surgeries, including death.5–7,11,14 In the current study, 
all but one of the patients who died within 30 days 
of the index procedure had single ventricle defects; 
moreover, the early mortality rate for this group was 
16%. Similar findings have been reported in larger 
cohorts.6,7 In a study of 730 patients with mBT shunts, 
McKenzie et al. reported an in-hospital mortality rate of 
15% in single ventricle cases versus 3% in biventricular 
cases.15 In another study of 1,273 neonatal patients 
who received mBT shunts, Petrucci et al. found rates 
of discharge mortality to be 5.1%, 7.2% and 15.6% for 
patients with biventricular defects, single ventricle 
defects (excluding those with hypoplastic left heart 
syndrome) and PAIVS, respectively.10 

Similar trends regarding lesion-specific variations 
in mortality have been described elsewhere. Alsoufi et 
al. observed higher mortality following mBT shunt 
procedures among patients with atrial isomerism and 
PAIVS in a single ventricle cohort.7 In the present 
study, patients with single ventricle defects had an 
increased risk of in-hospital mortality, although this 
association was not statistically significant. It is likely 
that the higher incidence of concomitant anomalies 
and underlying genetic syndromes, the complex 
nature of the cardiac anatomical structures and the 
coexistence of coronary pathologies serve to make 
patients with single ventricle defects more vulnerable 
to adverse outcomes. Moreover, the volume overload 
imposed on a single ventricle heart by systemic-to-
pulmonary artery shunts—including mBT shunts—
may predispose these patients to adverse outcomes 
even in the long term.16

Table 4: Risk factors associated with early mortality among 
infants and children with cyanotic congenital heart disease 
undergoing modified Blalock-Taussig shunt procedures 
in Oman (N = 50)

Variable Number of 
deaths per 
category

OR 
(95% CI)

P 
value

Age (≤28 versus 
>28 days)

- 0.58 
(0.09–3.83)

0.661

Weight (≤2.5 
versus >2.5 kg)

- 1.000

Prematurity 3/11 6.94 
(0.99–47.61)

0.064

Genetic condition 2/5 9.34 
(1.10–76.92)

0.072

Comorbidity 2/13 2.06 
(0.30–13.88)

0.595

Single ventricle 
defect

4/25 4.56 
(0.47–43.47)

0.349

Duct dependency 4/30 2.92 
(0.30–2.85)

0.636

Preoperative 
mechanical 
ventilation

5/20 3.00 
(1.98–4.76)

0.007

Unsuccessful 
preoperative 
shunt-related 
procedures

2/9 3.60 
(0.50–25.64)

0.216

Non-innominate/
subclavian arterial 
connection

3/15 4.13 
(0.61–27.78)

0.152

Cardiopulmonary 
bypass

5/16 4.09 
(2.44–6.85)

0.002

Associated 
procedure (e.g. PA 
plasty)

3/12 5.98 
(0.87–41.66)

0.080

Postoperative 
SpO2 of >85%

2/16 1.47 
(0.10–4.52)

0.518

Shunt revision 
during initial 
hospitalisation

2/6 6.84
(0.66–52.63)

0.103

Shunt size-to-
weight ratio of 
>1.2

2/21 1.09 
(0.17–7.19)

>0.999

OR = odds ratio; CI = confidence interval; PA = pulmonary artery; 
SpO

2 = oxygen saturation.



Outcomes of Infants Undergoing Modified Blalock-Taussig Shunt Procedures in Oman 
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462 | SQU Medical Journal, August 2021, Volume 21, Issue 3

In the current study, preoperative mechanical 
ventilation and intraoperative cardiopulmonary bypass 
were the only statistically significant risk factors for 
early mortality. Preoperative mechanical ventilation 
is a known predictor of adverse outcomes following 
paediatric cardiac surgery.17 In an analysis of 25,476 
paediatric congenital heart surgeries, Jacobs et al. 
found that discharge mortality was significantly higher 
in patients who were mechanically ventilated preop- 
eratively compared to overall mortality for neonates 
(15.1% versus 9.88%), infants (11.5% versus 2.91%) and 
children (14.4% versus 0.92%; P <0.001).18 Similar 
observations have been described post-mBT shunt 
surgery.10,14 On the whole, the need for preoperative 
mechanical ventilation reflects the precarious 
condition of these infants, which may explain the greater 
occurrence of adverse outcomes following surgery 
in such cases. It is also plausible that mechanical vent- 
ilation itself contributes to poor outcomes by altering 
the systemic-to-pulmonary blood flow ratio and 
increasing the need for sedation and neuromuscular 
blockade and the risk of pulmonary complications. 
Therefore, it is advisable to avoid elective intubation in 
this high-risk population, if possible.19,20

Moreover, performing a cardiopulmonary bypass 
during an mBT shunt procedure has frequently been 
associated with mortality, particularly among single 
ventricle patients.7,15 In this context, a cardiopulmonary 
bypass is generally performed due to preoperative 
haemodynamic instability or the need for concomitant 
cardiac surgery. There are several possible explanations 
for the association between cardiopulmonary bypass 
and adverse outcomes following mBT shunt procedures 
including activation of the inflammatory and coagulation 
cascades, alterations in pulmonary compliance and 
myocardial dysfunction and the decrease in diastolic 
pressure.7,15 In addition, previous studies have reported 
other predictors of mortality following mBT shunt 
procedures among paediatric CCHD cases such as 
low birth weight, underlying genetic syndromes, duct 
dependency and higher mBT shunt size-to-weight 
ratios.7 While these factors were not statistically 
significant predictors of mortality in the present study, 
it is possible that the small sample size precluded 
further analysis.

In the immediate postoperative period following 
mBT shunt procedures, two predominant reasons 
for increased early morbidity and mortality include 
the occurrence of shunt blockade (due to kinking or 
thrombosis) and pulmonary overcirculation (also 
known as over-shunting).21 In the current study, 12% of 
patients required surgical shunt revision due to shunt 
blockade during the same hospital admission period, 
of which one-third later died. In contrast, pulmonary 

overcirculation (i.e. maintaining SpO2 at >85%) was 
not a significant risk factor for early mortality. This 
probably reflects an underestimation of the prevalence 
of this factor, given that the majority of in-hospital 
deaths were due to myocardial dysfunction and low 
cardiac output. Over-shunting is one of the major 
causes of ventricular dysfunction and low cardiac 
output syndrome after mBT shunt procedures.21

Palliative mBT shunt procedures lead to unstable 
circulation, with patients at high risk of death even 
after being discharged from hospital. Previous 
research indicates that the rate of inter-stage mortality 
after mBT shunt surgeries varies from 3–11%.9 In the 
present study, the inter-stage mortality rate was 6.7%; 
this finding is in line with other published research, 
despite being calculated over a longer period of time.11 
During the interval period, patients with mBT shunts 
are at an increased risk of acute adverse events caused 
by alterations to the systemic-to-pulmonary blood 
flow or due to acute shunt thrombosis, especially 
during periods of concomitant illness (e.g. diarrhoea 
or sepsis). Longer interval periods can also render the 
shunt inadequate due to neointimal proliferation or 
somatic growth, mandating reintervention.22

Cardiac catheterisation using a ductal or right 
ventricle outflow tract (RVOT) stent has been proposed 
as an alternative to an mBT shunt.23 Comparative 
research has indicated that this alternative strategy 
is not inferior to mBT shunts in terms of clinical 
outcomes and is superior in terms of other variables 
like hospital mortality.23–25 However, a sizeable number 
of cases in which attempts at ductal/RVOT stenting fail 
have been found to eventually require mBT shunts.23 
While this subgroup of patients were observed to have 
a higher risk of death in the current study, the small 
study population precluded further analysis. As such, 
further research to compare outcomes between ductal 
stenting and mBT shunt procedures in a local setting 
might be helpful to guide patient selection.

The overall rate of surgical reintervention in the 
current study was 24%. While this is similar to the 
rate reported by Bentham et al., it remains unarguably 
high.24 Moreover, half of these interventions took place 
prior to hospital discharge. O’Connor et al. reported 
that 9.7% of 207 patients required reintervention 
before discharge, whereas Do et al. observed the rate 
of in-hospital shunt failure requiring reintervention to 
be 7.3% among 9,172 at-risk infants.26,27 Prevention of 
early shunt failure and reintervention is very important 
as these events entail considerable mortality and 
morbidity.26,27

Reasons for the high rate of reintervention in 
the current cohort are not entirely clear and require 
further evaluation; however, it is worth mentioning 



Samiuddin Shaikh, Khaloud S. Al-Mukhaini, Abdul Hakeem Al-Rawahi and Omer Al-Dafie

Clinical and Basic Research | 463

that most reinterventions were performed for 
biventricular patients with underlying diagnoses of 
pulmonary atresia and VSD, especially during the 
interval period. This is understandable considering 
the complex nature of this lesion, with many surgeons 
preferring to employ a staged approach with regards to 
the initial placement of the mBT shunt to allow for the 
growth of the pulmonary arteries.28,29 As pulmonary 
atresia and VSD was the most common underlying 
diagnosis in the biventricular group, this could also 
possibly explain the longer interval period before the 
second-stage surgery among these patients. 

Worldwide, outcomes following mBT shunt proc- 
edures are still poor compared to other types of conge- 
nital heart surgery.5,6,13 However, there nevertheless 
remains room to improve outcomes of this surgery 
among infants in Oman. Suggestions to decrease 
early mortality include improved patient selection 
with regards to the decision for surgical intervention 
compared to interventional cardiac catheterisation, the 
selection of appropriate shunt sizes, optimum anticoag- 
ulation to prevent shunt thrombosis and standardised 
postoperative management.30 Similarly, shorter interval 
periods, pre-emptive patient management during 
periods of concomitant illness and greater awareness 
of risk factors among community healthcare profess- 
ionals and parents may serve as strategies to improve 
survival after discharge.

This study was subject to certain limitations. As 
the study was conducted at a single centre, utilised 
a retrospective design, involved non-standardised 
procedures and included a comparably small number 
of patients, it may have been affected by bias. Thus, 
the results need to be interpreted in the background of 
institutional practices and the specific study population. 
Notwithstanding these limitations, the findings of this 
study contribute to knowledge regarding the outcomes 
of palliative mBT shunt procedures in infants with 
CCHD in Oman. Moreover, these results may serve as 
a platform for targeted strategies to improve outcomes 
in this setting.

Conclusion

In the current study, mBT shunt procedures were 
found to carry an extremely high risk of mortality 
and reintervention in the treatment of CCHD 
in a paediatric population. These findings reflect 
those reported in the existing global literature. In 
particular, preoperative mechanical ventilation and 
cardiopulmonary bypass represented significant risk 
factors for early mortality. Further studies are needed 

to compare outcomes between mBT shunt procedures 
and cardiac catheter interventions in order to guide 
patient selection in this setting.

a c k n o w l e d g m e n t

Authors would like to thank Dr. Hamood Al Kindi 
BSc,MSc,MD,FRCSC, Consultant Pediatric cardiac 
Surgery , National Heart Center , Royal Hospital and 
Sultan Qaboos University Hospital , Muscat , Sultanate 
of Oman; for  valuable suggestions in  manuscript 
writing.

c o n f l i c t o f i n t e r e s t
The authors declare no conflicts of interest. 

f u n d i n g

No funding was received for this study.

a u t h o r s’ c o n t r i b u t i o n 
SS and KSM conceived and designed the study and 
drafted the manuscript. SS, KSM and OD collected 
the data. AHR performed the statistical analysis and 
interpreted the results. All authors approved the final 
version of the manuscript.

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