surgical approaches to congenital aortic stenosis.docx

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Surgical Approaches to Congenital Aortic Stenosis

Author: Sanjeev Sharma (finescalpel\@gmail.com) Updated: 9/21/2024
10:09:22 AM

Introduction

Managing obstruction of the left ventricular outflow tract (LVOT) in
neonates, infants, and young children with congenital aortic stenosis
(AS) poses significant surgical challenges due to the complexity of the
LVOT\'s anatomy, mechanical function, and the aortic root\'s
performance. Surgical options for relieving AS in this population
require careful consideration, especially when the hypoplastic aortic
annulus is involved. A thorough preoperative assessment is essential to
identify suitable candidates for timely aortic root or LVOT
interventions. Various approaches, including valve-conserving procedures
such as the Ross procedure, sometimes modified with the Konno procedure,
allow children to grow before definitive interventions like aortic valve
replacement become necessary. Determining the optimal timing for aortic
root enlargement is crucial, as delaying surgery can lead to severe
circulatory failure and ventricular hypertrophy.

In neonates and infants with congenital AS, multiple comorbidities such
as borderline left ventricles (LVs), small mitral valves, and pulmonary
hypertension complicate surgical decision-making. The Ross-Konno
procedure, often combined with institution-specific modifications like
endocardial fibroelastosis resection, remains a preferred approach when
valve remodeling is not feasible, offering a wide-open and competent
LVOT. However, alternative techniques such as the Konno-Rastan
procedure, which involves replacing the aortic valve with a mechanical
or bioprosthetic valve, may lead to late complications like prosthesis
mismatch as the child grows or the need for lifelong anticoagulation in
cases of mechanical
prostheses.[\[1\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_37665750) A
careful balance between timely intervention and long-term management of
these complexities is essential for optimizing patient outcomes.

Etiology

Cardiac valves comprise a highly organized extracellular matrix,
including collagen, elastin, and proteoglycans. The proper development
of these valves relies on specific structural proteins. Numerous
transcription factors and promoter genes regulate the intricate process
of
cardiogenesis.[\[2\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_23297764) Variations
in the genes that encode these structural proteins---such as elastin
(ELN), fibrillin 1 (FBN1), and collagen type III alpha 1 chain
(COL3A1)---have been linked to congenital valve defects. Additionally,
gene variants that encode proteins necessary for the precise
localization of cells through cell-cell and cell-matrix interactions,
like elastin microfibril interfacer 1 (EMILIN1), have also been
identified in patients with valve
abnormalities.[\[3\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_37915827)

In higher vertebrates, the heart is not only vital for sustaining life
but also the first functional organ in the developing embryo, beginning
to beat spontaneously by the fourth week of human development. The
primitive bulbus cordis is crucial in forming several vital structures
of the developing heart. Specifically, the proximal third of the bulbus
cordis becomes the trabeculated part of the right ventricle (RV); the
midportion, known as the conus cordis, develops into the outflow tracts
of both ventricles; and the distal third, the truncus arteriosus, forms
the proximal aorta and pulmonary trunk. The area where the primitive
ventricle meets the bulbus cordis is the primary interventricular
foramen. As ventricular septation progresses, the primitive ventricle
evolves into the significant portion of the definitive LV. At the same
time, the proximal third of the bulbus cordis develops into the major
portion of the definitive RV (see **Image.** Bending of the Cardiac
Tube).[\[2\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_23297764)

During the fifth to seventh weeks of development, neural crest cells
migrate into the region of the outflow tract, giving rise to the
conotruncal ridges, which develop along the inner walls of the
conotruncus and spiral toward each other, ultimately fusing to form the
aorticopulmonary septum. This septum divides the outflow tract into the
aorta and pulmonary trunk. Concurrently, the endocardial cushions within
the outflow tract contribute to forming the aortic and pulmonary
semilunar valves, ensuring the unidirectional flow of blood from the
ventricles to the great arteries. By the seventh to eighth weeks, the
aortic and pulmonary roots align with their respective ventricles: the
aorta with the left, forming the LVOT, and the pulmonary trunk with the
right.

The LVOT is incorporated into the developing LV as the interventricular
septum forms, consisting of muscular and membranous parts that close the
ventricular septal defect of earlier stages. The aortic valve, aortic
root, and ascending aorta undergo further refinement, with the aortic
valve emerging from the endocardial cushions, which experience
proliferation, programmed cell death, and remodeling to form its mature
3-leaflet structure. Abnormalities in these developmental processes can
lead to congenital heart defects involving the LVOT, such as AS, aortic
coarctation, or double outlet RV.

Congenital AS can be classified into 4 main types based on the location
of the narrowing (see **Image.** Types of Left Ventricular Outflow Tract
Obstruction).[\[4\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_24983130) They
are:

- Valvular AS

- This is characterized by hypoplastic, dysplastic, or numerically
abnormal valve cusps, with the bicuspid valve being the most
common form. Occurring 4 times more frequently in males than
females and resulting from abnormal development of the
endocardial cushions, it often involves the fusion of the right
coronary cusp with an adjacent cusp. In 20% of cases, bicuspid
valves are associated with other congenital heart defects, such
as coarctation of the aorta. 

- Bicuspid aortic valve (BAV) is the most common form of
congenital AS, and its prevalence ranges from 0.77% to 1.4%,
which may be higher when asymptomatic individuals are
considered. Although BAV patients typically do not experience
significant issues during infancy and childhood, they may
develop various aortic valve abnormalities, such as stenosis and
insufficiency, as well as aortic complications like root
dilatation, rupture, and dissection later in life. Consequently,
BAV is associated with the highest mortality rate among
congenital heart diseases.

- BAV can be categorized into 3 main types using the Sievers
classification (see **Image.** Sievers Classification System for
Bicuspid Aortic Valve):

- Type-0: This type has 2 equal cusps without a raphe.

- Type-1: This is the most common type, accounting for 90% to
95% of cases, and is characterized by the fusion of 2 cusps.
Type-1 is further divided into 3 subgroups:

- R-L

- This is the fusion of the right and left coronary
cusps.

- The R-L subgroup is the most prevalent and linked to
neural crest cell migration
issues.[\[5\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_37754827)

- R-N

- This is the fusion of the right coronary and
noncoronary cusps.

- L-N

- This is the fusion of the left coronary and
noncoronary cusps.

- This is the rarest form.  

- Type-2: This is the rarest, involving the fusion of 3
leaflets. 

- A new international consensus classification for BAV has been
recently introduced, which categorizes BAV based on the type and
phenotype of the valve, its function, the presence and
characteristics of the raphe, cusp shape and size, BAV symmetry,
and the presence or absence of aortopathy or coarctation. This
International Consensus offers several advantages over the
Sievers classification, including a) the ability to define all
BAV phenotypes, such as fused, 2-sinus, and partial fusion
(forme fruste) phenotypes; b) the recognition of fused BAV
without a raphe, distinguishing it from 2-sinus BAV; c)
providing a symmetry assessment crucial for surgical repair
planning of fused BAV; d) the inclusion of aortic phenotypes
(root, ascending, and extended); and e) the use of more
straightforward and descriptive language
(see **Image.** International Consensus Classification for
Bicuspid Aortic
Valve).[\[6\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_38283572) 

- Subvalvular AS

- This type features a thickened ring or collar of dense
endocardial fibrous tissue below the valve cusps, narrowing the
LVOT. Accounting for 10% of AS cases, it is twice as common in
males and is the second most common form of congenital AS.

- Patients often present with mild aortic regurgitation due to the
thickening and immobility of the aortic cusps, sometimes
exacerbated by bacterial endocarditis. A prominent systolic
murmur, occasionally accompanied by a vibratory \"thrill,\" is
common.

- This condition can lead to LV hypertrophy and an increased risk
of sudden death during exertion. The muscular form of
subvalvular AS, a hypertrophic cardiomyopathy (HCM) variant, is
hypertrophic obstructive cardiomyopathy (HOCM). Historically
referred to as idiopathic hypertrophic subaortic stenosis, HOCM
is a genetic disease caused by mutations in contractile
proteins.

- Supravalvular AS

- This type is caused by the narrowing of the ascending aorta just
above the aortic valve and is the least common variant of LVOT
obstruction (LVOTO), occurring with an estimated frequency of 1
in 20,000 live births.

- This condition most frequently presents as a discrete,
hourglass-like constriction of the ascending aorta near the
sinotubular junction. In approximately one-quarter to one-third
of cases, however, the narrowing is more diffuse, extending into
the aortic arch. Modern understanding now recognizes this
condition as a manifestation of a generalized arteriopathy,
marked by a thickening of the aortic media or intima layers,
leading to a progressive constriction of the ascending aorta and
other systemic and pulmonary
arteries.[\[7\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_23250899)

- This congenital anomaly arises from the incomplete expression of
the ELN gene located on chromosome 7q11.23. The ELN gene encodes
tropoelastin, a precursor of elastin expressed in smooth muscle
cells during early development. Elastin, in harmony with other
extracellular proteins, forms elastic fibers within the arterial
media, imparting necessary distensibility to the vasculature.
Disruption of the ELN gene results in reduced and disorganized
elastin fibers, increased hypertrophied smooth muscle cells, and
excessive collagen deposition within the arterial media. The
condition follows an autosomal dominant inheritance pattern with
incomplete penetrance and variable expressivity.

- A microdeletion of the ELN gene is responsible for
Williams-Beuren syndrome, characterized by an elastin
arteriopathy alongside other manifestations, such as
intellectual disability, hypercalcemia, and distinctive facial
features. In this syndrome, the prevalence of supravalvular AS
is estimated to be approximately 70%. Point mutations in the ELN
gene give rise to familial forms of supravalvular AS, in which
the patient exhibits a similar arteriopathy as those with
Williams-Beuren syndrome but generally retains normal cognitive
function and lacks dysmorphic
features.[\[8\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_18452001)[\[9\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_11167112)

- Unicommissural and Acommissural Valves

- These types cause symptoms early in life. Congenital AS
presenting in infancy and childhood often results from a
severely deformed valve associated with a hypoplastic aortic
annulus. This anomaly may be part of hypoplastic left heart
syndrome (HLHS).

Epidemiology

Congenital heart defects are among the most prevalent congenital
malformations, affecting about 9 out of every 1,000 live births. There
are notable geographical variations in the prevalence of congenital
heart defects. The highest prevalence is reported in Asia, with 9.3
cases per 1,000 live births. At the same time, Europe has the second
highest prevalence, at 8.2 cases per 1,000 live births, and Africa has
the lowest prevalence at 1.9 per 1,000 live
births.[\[10\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_22078432)

The distribution of various cardiac malformations is as follows:
ventricular septal defect constitutes 42%, atrial septal defect accounts
for 10%, pulmonary stenosis represents 8%, and patent ductus arteriosus
makes up 7%. Tetralogy of Fallot and coarctation of the aorta occur in
5% of cases. Atrioventricular septal defect and AS are each found in 4%
of cases, while transposition of the great arteries also appears in 4%.
Persistent truncus arteriosus, total anomalous pulmonary venous
connection, and tricuspid atresia each represent 1% of cardiac
malformations.[\[11\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_12084585) 

Pathophysiology

Despite being a short channel, the LVOT involves intricate anatomy,
mechanical function, and performance, all of which are perfectly
integrated (see **Image. **Complex Anatomy of the Left Ventricular
Outflow Tract). The crown-shaped aortic annulus provides structural
support to the aortic valve and anchors it within the aortic root. As an
anchor for the synchronized movement of both the inlet mitral valve and
the outlet semilunar valve, the aortic root also supports the intricate
motions of the aortic valve
cusps.[\[12\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_27060044) Over
the past 2 decades, most morphological studies of stenotic, purely
regurgitant, and infected congenitally malformed aortic valves have
focused on calcium analysis in operatively excised specimens. Studies on
these excised valves have shown that unicuspid valves contain the most
calcium, making them the heaviest and most stenotic. Bicuspid valves
exhibit the next highest level of calcification, while stenotic
tricuspid valves have the least calcific deposits, rendering them the
lightest and least
stenotic.[\[13\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_15519018)

Subvalvular AS includes various conditions and is known for its
progressive nature. Subvalvular AS may present as a solitary subvalvular
membrane within the LVOT or as a small fibrous muscular ridge on the
subvalvular ventricular septum, called discrete subvalvular AS. In more
severe forms, subvalvular AS manifests as a narrow fibromuscular
tunnel-like obstruction in the LVOT. This stenosis leads to turbulent
blood flow, which can damage the aortic valve, potentially causing
aortic regurgitation due to valve prolapse. Membranous subaortic tissue
can also extend onto the aortic valve leaflets, restricting their
mobility and alignment. Aortic regurgitation often progresses after
subaortic resection, with reoperation rates for valve repair or
replacement following initial resection reaching up to 20%. However,
long-term outcomes regarding reoperation and aortic valve intervention
in pediatric patients with subvalvular AS remain poorly
defined.[\[14\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_36531724)

History and Physical

Clinical manifestations of valvular AS vary depending on the patient\'s
presentation age, the severity of the stenosis, and any associated
cardiac conditions.

Valvular AS can be detected in fetuses through fetal echocardiography,
where a thickened or domed aortic valve with increased Doppler flow
velocity greater than 1 m/s indicates the condition. Valvular AS is a
progressive disorder, and in some cases, it may advance to HLHS. This
progression can be identified by reversed flow in the transverse aortic
arch and foramen ovale, monophasic mitral inflow, and LV dysfunction
during the second trimester. A slowed growth rate of left heart
structures can also predict HLHS development.

Neonatal and routine well-baby check-ups often fail to effectively
screen for severe valvular AS. Infants with severe valvular AS typically
present with signs of congestive heart failure by around 2 months of
age. These infants may exhibit symptoms such as pallor, mottled skin,
hypotension, and dyspnea. Clinical examination may reveal a normal first
heart sound, an ejection click, and a gallop in approximately 50% of
affected infants. An ejection systolic murmur of varying intensity is
often detected along the midleft and right upper sternal borders, with
radiation to the carotid arteries. The presence of hypoxia
(PaO~2~ 30--40 mm Hg) and metabolic acidosis signals an urgent need for
medical intervention.

Older children and adolescents with valvular AS are generally
asymptomatic, but about 10% may experience symptoms such as dyspnea,
angina, or syncope, particularly during exercise. The appearance of
these symptoms warrants immediate and thorough evaluation due to the
risk of sudden death, which has been observed in 1% to 10% of
individuals aged 5 to 15 years with moderate to severe valvular AS.

In children, characteristic physical findings associated with valvular
AS, such as a small amplitude and slow-rising pulse (pulsus parvus et
tardus), carotid shudder, and a prominent jugular venous \"a\" wave, are
not consistently present as they are in adults. However, a precordial
systolic thrill over the base of the heart is noted in over 65% of
patients with more than mild valvular AS. Severe valvular AS may also be
indicated by a narrowly split, single, or paradoxically split second and
fourth heart sounds. An ejection click, present in cases with a pliable
valve and absent in severe valvular AS, is not influenced by
respiration. The typical low-pitched crescendo-decrescendo systolic
murmur of valvular AS, which begins just after the ejection click, is
best heard at the base of the heart and radiates to the carotid
arteries. This murmur becomes more pronounced with maneuvers that
increase stroke volume, such as isotonic exercise and premature
ventricular
contractions.[\[15\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_31086112)

Older children and adolescents with valvular AS are often asymptomatic,
but approximately 10% may exhibit symptoms of congestive heart failure,
such as dyspnea, angina, or syncope, particularly during exercise. To
assess the severity of stenosis, a combination of maximum aortic
velocity (Vmax), mean pressure gradient, and aortic valve area is used,
as outlined in the latest guidelines from the American College of
Cardiology (ACC) and the American Heart Association
(AHA).[\[16\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_33332150)[\[17\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_37187784)

The inclusion criteria, aligned with the AHA operative guidelines, are
as follows for critical AS:

- Patients with a small aortic valve annulus, with or without
subvalvular narrowing, and either a peak instantaneous gradient of
≥60 mm Hg, a mean pressure gradient of ≥40 mm Hg, or an aortic valve
area of ≤0.5 cm²/m²

- Patients with a peak gradient of ≥50 mm Hg or an aortic valve area
of 0.5 to 0.8 cm²/m² accompanied by symptoms such as angina,
syncope, or electrocardiographic changes, or those planning for
pregnancy

- Patients with a peak gradient of ≥35 mm Hg or an aortic valve area
of 0.8 to 1.5 cm²/m² with moderate or greater aortic regurgitation
due to valve deformity or previous
ballooning [\[18\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_37847656)

Evaluation

**Imaging Recommendations**

Aortic dilation in patients with BAV can involve the aortic root,
ascending aorta, or both, with the ascending aorta most commonly
affected. In some cases, the dilation may extend into the aortic arch.
The reported prevalence of aortic dilation in BAV varies widely, ranging
from 20% to 84%, depending on the population studied and the specific
definition of aortic dilation used. Patients with both BAV and aortic
dilation are at an increased risk for aortic dissection. To evaluate
aortic valve function, aortic dilation, and potential aortic
coarctation, imaging of the aortic root, ascending aorta, arch, and
proximal descending aorta should be performed using transthoracic
echocardiography (TTE). Additionally, in patients undergoing TTE,
detecting unexplained aortic root or ascending aortic dilation should
raise suspicion for underlying BAV. If TTE results for the aortic valve
are inconclusive, further imaging with cardiac magnetic resonance
imaging (MRI), cardiac computed tomography angiography (CTA), or
transesophageal echocardiography (TEE) can be utilized for a more
detailed
assessment.[\[19\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_28592593) Cardiac-gated
CT or MRI is particularly effective for visualizing the aortic root and
ascending aorta when TTE does not provide sufficient detail. The choice
between CT and MRI depends on various factors, including patient
characteristics, institutional expertise, renal function, cost
considerations, and concerns about radiation
exposure.[\[20\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_33342586)

**Z-score Calculation**

A method for describing clinical and echocardiographic variables is a
Z-score, which quantifies how many standard deviations a particular
measurement is from the mean of a size- or age-specific population. The
Z-score is calculated using the formula:

Z = (x −μ) / σ

Where x represents the observed measurement, μ is the expected
measurement (population mean), and σ is the population\'s standard
deviation. A positive Z-score indicates a value above the population
mean, while a negative Z-score indicates a value below it, reflecting
the extent of deviation from the mean. For instance, if the mean size of
the aortic valve is 20 mm with a standard deviation of 3 mm, a valve
with an annulus measuring 14 mm would have a Z-score of:

Z = (14 − 20) / 3 = −2

To accurately calculate a Z-score, one must establish the population
mean and standard deviation for each body
size.[\[21\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_23129909)

**Hemodynamic Parameters**

In pediatric patients, the severity of valve stenosis, which helps
determine the need and timing for intervention, is often quantified by
measuring the aortic valve pressure gradient. This transvalvular
pressure gradient (P) is typically calculated using peak instantaneous
Doppler echocardiographic velocity (V) measurements from various angles.
The simplified Bernoulli equation is applied to estimate the pressure
gradient:

P = 4V^2^

This equation is a common method for assessing the severity of valvular
AS in this patient
population.[\[15\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_31086112)

**Familial Screening Recommendations**

Certain hereditary thoracic aortic diseases show an increased prevalence
of BAV. For instance, about 10% of patients with Loeys-Dietz syndrome,
associated with pathogenic variants in genes such as TGFBR1, TGFBR2,
SMAD3, TGFB2, and TGFB3, have BAV. Hereditary thoracic aortic diseases
are linked to pathogenic variants in NOTCH1, ACTA2, MAT2A, SMAD6, and
LOX, which also show a higher prevalence of
BAV.[\[22\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_28659821) Notably,
despite the familial nature of BAV and thoracic aortic aneurysms, most
patients with these conditions will not have an identifiable pathogenic
genetic variant even after genetic testing. However, when the condition
is familial, patients with BAV and aortopathy should be evaluated,
counseled, and genetically tested by a medical geneticist or a
specialist in genetic
aortopathy.[\[23\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_32698598)

The prevalence of BAV among first-degree relatives of individuals with
this condition is approximately 10% to 15%. Due to the hemodynamic
consequences and the genetic predisposition to aortic dilation
associated with BAV, early detection and regular monitoring are crucial.
Consequently, American and European guidelines from the past decade
recommend screening primary family members using TEE. The evidence
supporting these recommendations varies, generally falling within class
IIa/b.[\[24\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_36322642)

Treatment / Management

Congenital AS is a progressive condition, and guidelines have been
established to outline the indications for intervention. These
interventions include balloon valvuloplasty in the cardiac
catheterization lab and transcatheter or surgical aortic valve
replacement. A 30-year follow-up study revealed that diagnosing mild AS
before 6 months of age significantly increases the risk of requiring
aortic valvotomy and balloon valvuloplasty as the patient ages. The
probability that the stenosis remains mild is less than 20%,
highlighting the necessity for long-term follow-up of mild AS into
adulthood. Recently, it was shown that the likelihood of requiring
balloon valvuloplasty is 20% for patients with catheter-measured peak
pressure gradients less than 25 mm Hg and increases to 40% and 70% for
those with gradients of 25 to 49 mm Hg and over 50 mm Hg,
respectively.[\[6\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_38283572)

LVOTO is an instantaneous peak pressure gradient of ≥30 mm Hg within the
LVOT, as measured by Doppler echocardiography. LVOTO is dynamic and
sensitive to ventricular preload, afterload, and myocardial
contractility variations. For patients with HCM who do not exhibit LVOTO
at rest, a provocation test is necessary to assess latent LVOTO. This
can be done using methods such as the Valsalva maneuver, transitioning
from a supine to standing or squatting to a standing position or
performing an upright treadmill or semisupine bicycle test. Current
guidelines advise against using dobutamine due to its lack of
specificity.[\[25\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_29054275)[\[26\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_28329285)

Research has shown that LVOTO significantly increases the risk of
adverse events, including sudden cardiac death, progression to moderate
to severe heart failure, stroke, and death in patients with HCM. A
resting or provoked LVOT pressure gradient of ≥50 mm Hg is typically the
threshold for considering septal reduction therapy in patients who have
drug-refractory
symptoms.[\[27\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_16754630)[\[28\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_30994509)

Short- and mid-term outcomes for LVOT abnormalities have improved due to
the implementation of increasingly complex surgical procedures, ie, the
Ross procedure, the Ross--Konno procedure, and the Konno--Rastan
procedure.[\[29\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_36632841)

The Ross procedure is a well-established surgical technique to replace a
severely dysfunctional aortic valve with the patient\'s pulmonary valve,
known as an autograft, with the native pulmonary valve replaced with a
homograft or a
conduit.[\[30\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_4167516) When
the native annulus is too small, the Konno incision can enlarge the LVOT
by incision from the annulus into the ventricular
septum.[\[31\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_8010778) This
combined Ross-Konno procedure offers distinct advantages, particularly
for infants and neonates with competent pulmonic valves. The autograft
in the new aortic position can grow with the patient and does not
require
anticoagulation.[\[32\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_19632419) Alternative
treatments, such as serial balloon dilations, aortic valve repair, and
mechanical valve replacements, have significant drawbacks. However,
there are concerns about the potential for neoaortic root dilatation due
to the pulmonary valve being exposed to unfamiliar systemic pressures,
the need for repeated replacements of the RV to pulmonary artery (RV-PA)
conduit or valve, and cardiac performance in the immediate postoperative
period.[\[33\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_31084313)

Neonates and young infants considered for the Ross-Konno procedure are
often critically ill. They may present with multiple left-sided
anomalies, including complex LVOTO, mitral stenosis, and aortic arch
abnormalities. These patients might have previously undergone partially
successful procedures, such as aortic valve balloon dilatation. Studies
from single and multiple institutions have reported early survival rates
ranging from 78% to 96% for this age
group.[\[34\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_29444227)[\[35\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_34600763)

The traditional Konno--Rastan procedure involves enlarging the aortic
root through anterior aortoventriculoplasty and replacing the aortic
valve with a mechanical or biological prosthetic valve. Reoperation
after the Konno--Rastan procedure presents significant challenges and
carries a risk of high mortality and morbidity, with potential
complications such as heart block, need for anticoagulation, possible
prosthesis patient mismatch later in life, and excessive
bleeding.[\[18\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_37847656)

The peak LVOT gradient determines the indication for surgical
intervention. Surgical treatment is recommended for patients with a peak
LVOT gradient exceeding 50 mm Hg. For those with a gradient between 30
and 50 mm Hg, the decision to proceed with surgery depends on the
presence of symptoms and the progression of aortic regurgitation. While
a subvalvular membrane may be identified during preoperative
echocardiography, the final surgical approach is determined
intraoperatively after inspecting the LVOT.

The specific approach depends on the anatomy of the stenosis, including
the presence of a membrane and the degree of septal hypertrophy. The
extent of myectomy is tailored to the individual\'s anatomy and LVOT
size, with careful attention to the conduction system. At the center,
the standard approach for pediatric patients involves transaortic septal
myectomy, with no transmitral or apical septal myectomy performed during
the study period. During surgery, access to the LVOT is achieved through
an oblique aortotomy. The aortic valve is retracted, enabling resection
of the membrane and septal myectomy in cases of myocardial hypertrophy.
Any redundant subvalvular membrane tissue that extends onto the aortic
valve, mitral valve, or accessory papillary muscle attachments is also
resected. Multiple levels, including subvalvular stenosis and aortic
valve dysfunction, may benefit from anterior aortoventriculoplasty, ie,
the Ross-Konno or Konno-Rastan
procedures.[\[14\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_36531724)

An example of the Ross-Kono procedure is as follows: 

Standard surgical techniques for the Ross-Konno procedure involve
initiating cardiopulmonary bypass via a midline sternotomy, bicaval
cannulation, and moderate hypothermia. Deep hypothermic circulatory
arrest is used for patients requiring concurrent aortic arch repair.
Myocardial protection is achieved using antegrade or retrograde delivery
of cold blood cardioplegia or modified St. Thomas cardioplegia solution
into the coronary sinuses.

The surgery begins by transecting the aorta above the sinotubular
junction, securing commissural stay sutures, and inspecting the aortic
valve. After confirming the Ross-Konno procedure is suitable and
ensuring the pulmonary valve is a trileaflet and viable as an autograft,
the aortic valve leaflets are excised, and the coronary buttons are
mobilized, along with the proximal epicardial coronary course. The
pulmonary autograft is harvested from the right ventricular outflow
tract and interventricular septum while preserving septal perforators.
Antegrade cardioplegia is used to identify and oversew any bleeding in
the autograft bed.

A Konno incision is made to address the size mismatch between the
pulmonary and aortic valves, extending 5 to 30 mm into the
interventricular septum to enlarge the LVOT and accommodate the larger
pulmonary autograft (see **Image.** Ross-Konno Procedure). The RV free
wall patch beneath the left anterior pulmonary sinus on the autograft is
integrated into the LVOT, while the remaining 2 pulmonary sinuses are
sewn horizontally around the inflow, thereby supporting the left
anterior sinus with the free-grafted RV muscle. A separate ventricular
septal defect patch is rarely necessary. The autograft commissures
are marked externally, and a 5-0 or 6-0 polypropylene continuous suture
technique is employed, using a new suture for each sinus. The autograft
is positioned, suture tension is confirmed with a nerve hook, and the
sutures are secured. The autograft is implanted at the previous annulus
level, taking care to avoid the conduction tissue in the membranous
septum. An additional 6-0 polypropylene continuous suture reinforces the
proximal suture line.

The coronary buttons are implanted with continuous sutures into punch
holes, and trapdoor flaps are rarely used. In this age group, specific
annulus reinforcement techniques are not applied. The reconstructed
neocortical root is anastomosed end-to-end to the ascending aorta. A
cryopreserved pulmonary homograft, sized 12 to 14 mm, is preferred for
the RV-PA conduit. An aortic homograft or bovine jugular vein valved
conduit is used if unavailable. The distal conduit anastomosis typically
precedes the distal aortic suture line, using a continuous polypropylene
suture. Before completing the proximal homograft suture line and with
the PA vented, the atrial septal defect is closed primarily, and the
heart is deaired with aortic root suction. The right atrial and proximal
conduit anastomoses are then completed. In some cases, a bovine
pericardial skirt is sewn to cover the rightward part of the orifice
around the neoaorta due to a size mismatch between the proximal conduit
and the autograft harvest site. The conduit and the ventriculotomy edge
are then attached to this.

A postoperative TEE confirms the autograft\'s competence, ventricular
performance, and mitral valve function. A prolonged hemostasis period is
often required, and delayed sternal closure is routinely performed in
neonates and those with extended aortic cross-clamp time or marginal
postoperative status. Extracorporeal membrane oxygenation (ECMO) is
employed postoperatively in patients with significant inotrope
requirements, volume-dependent circulation, or extended cross-clamp time
or who could not be successfully separated from bypass to avoid the need
for emergent cannulation.

Differential Diagnosis

The differential diagnoses for congenital AS include:

- Aortic valve masses

- Masses on the aortic valve are extremely rare in children, with
potential diagnoses including vegetation, thrombus, and primary
cardiac tumors. This condition may manifest as valvular AS,
potentially causing sudden hemodynamic compromise due to aortic
vegetation extending into the ascending aorta and eroding
through its posterior
wall.[\[36\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_37152505)

- The rising survival rates of children with congenital heart
conditions and extended hospital stays in newborns have
contributed to an increase in infective endocarditis cases. In
these instances, the mass on the aortic valve or in the
ascending aorta could be a vegetation, tumor, or thrombus.

- Aortic thrombosis

- In the neonatal population, symptomatic aortic thrombosis occurs
at 0.1 to 1.1 per 100,000 newborns. The clinical presentation
can vary widely, from nonspecific irritability to embolic severe
complications such as stroke, acute limb-threatening ischemia,
mesenteric ischemia, and renal failure.

- Lambl excrescences, an anatomical variant, are typically limited
to older people.

- Papillary fibroelastoma

- This is a primary cardiac tumor with a preference for the
valvular endocardium, primarily affecting older adults, with
only a few cases reported in children. 

Prognosis

The prognosis following surgical approaches to congenital AS varies
depending on the type and severity of the stenosis, the patient\'s age,
and the specific surgical procedure performed. In general, surgical
interventions such as balloon valvuloplasty, aortic valve repair, or
replacement, and more complex procedures like the Ross-Konno procedure
have significantly improved survival rates and long-term outcomes in
patients with congenital AS. However, patients require lifelong
follow-up, as the condition can recur, and there are risks of
reintervention.

The prognosis for patients undergoing the Ross-Konno procedure is
generally favorable, especially in pediatric patients, due to using the
patient\'s pulmonary valve as an autograft. This technique provides good
long-term hemodynamic performance and reduces the need for
anticoagulation. However, patients may face complications such as
autograft dilation or dysfunction, which may necessitate reoperation.
Despite these risks, the Ross-Konno procedure has shown excellent
durability, with survival rates around 90% at 10 years and a low risk of
sudden cardiac death.

A recent study on patients who underwent a Ross or Ross-Konno procedure
reported no early deaths, with all patients surviving until discharge.
However, there was 1 late death caused by cardiac arrest due to a
pulmonary hypertensive crisis. Out of the total, 27 patients (77.1%)
left the operating room with an open sternum, typically closed after a
median of 5 days. Delayed chest closure was almost universally utilized
in neonates, with 12 out of 13 (92.3%) undergoing this approach.
Additionally, 6 patients (17.1%) required mechanical circulatory
support. Since undergoing their Ross or Ross-Konno procedure, 12
patients (34.3%) required at least 1 reoperation, with a median age of
3.4 years (interquartile range, 0.6-8.9 years). These reoperations
included 10 reinterventions for RV-PA conduit issues, 2 mitral valve
repairs, and 1 mechanical mitral valve replacement. Additionally, 1
patient needed a reoperation on the LVOT. Another patient required
right PA stenting and angioplasty at 16 months of age due to progressive
proximal right PA stenosis. Ten patients required RV-PA conduit
replacement at a median of 10.6 years following their Ross or Ross-Konno
procedure. All 34 surviving patients exhibited normal LV systolic
function at the most recent follow-up. Of these, 9 patients (26.5%) had
mild neoaortic regurgitation, while the remaining 25 (73.5%) had none or
only minimal regurgitation. None of the patients developed neoaortic
stenosis.[\[35\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_34600763)

Overall, the prognosis of surgical approaches to congenital AS has
improved with advances in surgical techniques, perioperative care, and
long-term management. However, ongoing surveillance is essential due to
the risk of reoperation and complications such as valve degeneration,
aortic root dilation, and arrhythmias.

Complications

In a recent study of operative complications following the Ross-Konno
procedure, low cardiac output syndrome was observed in 21 patients
(60%), with 4 experiencing postoperative cardiac arrests due to various
causes: tamponade, hypokalemia, transient complete heart block, and an
unidentified cause. One infant required immediate reoperation for
bleeding. Clinically significant arrhythmias were noted in 11 patients
(31.4%), with 1 needing a permanent pacemaker 2 weeks postsurgery due to
a complete atrioventricular heart block (in a patient who had undergone
a Konno incision). Mediastinitis developed in 4 patients (11.4%), and 1
of these cases progressed to fungal endocarditis following a prolonged
ECMO period with an open chest, leading to RV-PA conduit replacement
at 10 weeks after a Ross/Konno procedure. Five patients (14%)
experienced cerebrovascular events, with 3 occurring during ECMO. Two
patients (5.7%) had seizures. Additionally, 13 patients (37.1%) required
peritoneal dialysis, 18 (51.4%) experienced significant bleeding, and 12
(34.3%) needed factor VII
administration.[\[35\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_34600763)

Following the Ross-Konno or Konno-Rastan procedure, replacing the RV
with the PA conduit is the most common reoperation. Most patients with
pulmonary regurgitation do not exhibit symptoms. However, those who do
may initially experience exertional dyspnea due to decreased cardiac
output caused by volume overload in the right heart. Over time, these
patients might notice a gradual reduction in their ability to exercise.
In more severe cases, pulmonary regurgitation can lead to symptoms
indicative of right heart failure, such as swelling in the legs (pedal
edema), an enlarged congested liver (congestive hepatomegaly), and
occasionally, distended neck veins (jugular vein distention).

Similarly, most individuals with mild pulmonary stenosis typically do
not exhibit symptoms. Those who do experience symptoms usually have
moderate to severe pulmonary stenosis and often present with exertional
dyspnea or fatigue, which varies according to the degree of obstruction
and the heart\'s ability to compensate. In severe pulmonary stenosis,
where RV dysfunction develops, systemic venous congestion may occur.

In a recent study, the freedom from reoperation was 66%. Twelve patients
(34.3%) required at least 1 reoperation since their initial Ross or
Ross-Konno procedure, with the median age at reoperation being 3.4
years. These reoperations included 10 RV-PA conduit interventions, 2
mitral valve repairs, and 1 mechanical mitral valve replacement.
Additionally, 1 patient required reintervention on the LVOT, another
needed right PA stenting and angioplasty at 16 months for progressive
proximal right PA stenosis, and 1 patient had a permanent pacemaker
implanted 2 weeks after a Ross-Konno due to complete atrioventricular
block.[\[35\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_34600763)

Aortic valve disease can increase the risk of ventricular arrhythmias.
The pressure or volume overload associated with the disease often leads
to ventricular hypertrophy, which elevates myocardial oxygen demand
while reducing coronary flow reserve. This combination creates a higher
susceptibility to ischemia and scar tissue formation, both of which can
trigger ventricular arrhythmias. Although aortic valve surgery, such as
the Ross procedure, aims to address these issues, it may not eliminate
the risk of arrhythmias. Furthermore, the surgical procedures, including
the Ross procedure and additional interventions, may introduce
proarrhythmic factors. For example, excision of the pulmonary root,
enlargement of the aortic annulus (via Ross-Konno), and muscle resection
in the subaortic area can all lead to scar formation, providing a
substrate for reentrant arrhythmias. Additionally, the first septal
perforator of the left anterior descending coronary artery may be
damaged during the pulmonary root excision, resulting in ischemia and
subsequent ventricular arrhythmias. The process of explanting and
reimplanting the coronary arteries during surgery also carries a risk of
creating ischemic areas, further contributing to the potential for
ventricular
arrhythmias.[\[37\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_18498822)

Deterrence and Patient Education

Deterrence and patient education regarding surgical approaches to
congenital AS are essential for improving outcomes, minimizing
complications, and ensuring long-term management.

Although congenital AS is typically a structural defect that cannot be
entirely prevented, early prenatal and newborn screening detection is
critical. Regular monitoring of valve function LVOTO and associated
cardiovascular anomalies can help clinicians intervene at the optimal
time, potentially delaying the need for surgical intervention. In cases
where congenital AS progresses to severe stenosis, timely referral to a
cardiac specialist is essential to avoid complications such as heart
failure or sudden cardiac death.

Preventive strategies also include managing modifiable risk factors that
can exacerbate the condition, such as hypertension or infections like
bacterial endocarditis. Patients with a history of congenital AS or
BAV should receive prophylactic antibiotics before certain dental or
surgical procedures to prevent infective endocarditis.

Patient education focuses on helping patients and families understand
the nature of congenital AS, its potential progression, and the
importance of regular follow-ups. Clear communication about the various
surgical options---such as balloon valvuloplasty, aortic valve repair,
or the Ross-Konno procedure---along with the risks, benefits, and
recovery expectations---is essential.

Patients should also be informed about postoperative care, including the
importance of medication adherence, particularly for those on
anticoagulants after mechanical valve replacement. Education on
recognizing signs of complications, such as shortness of breath, chest
pain, or palpitations, ensures prompt medical attention when needed.

Long-term lifestyle guidance is equally important. Patients should
understand the need for lifelong monitoring, exercise limitations, and
potential future reoperations. For young patients, this education
extends to school participation, sports activities, and the
psychological impact of living with a congenital heart defect. Educating
families empowers them to support the patient's health and improve their
quality of life while mitigating future risks.

Pearls and Other Issues

An urgent Ross-Konno procedure can be done safely in neonates and
infants, where survival and LV recovery are excellent, but
reintervention for pulmonary valve replacement is high.

Enhancing Healthcare Team Outcomes

Effective surgical management of congenital aortic stenosis (AS) demands
a coordinated, interprofessional team approach to enhance
patient-centered care and outcomes. The team must work closely together,
including congenital cardiac surgeons, pediatric cardiologists,
anesthesiologists, and intensivists. Surgeons use detailed preoperative
assessments from cardiologists, including echocardiographic and imaging
studies, to define left ventricular outflow tract (LVOT) anatomy.
Advanced practitioners and nurses ensure precise perioperative
monitoring, managing patient stability, fluids, and vital signs. At the
same time, pharmacists oversee anticoagulation therapy in cases
involving mechanical valve replacements to mitigate risks such as
thrombosis or hemorrhage. Nurses also provide essential emotional
support to patients and families.

Interprofessional communication and collaboration improve patient safety
and outcomes through structured decision-making. Daily rounds,
preoperative discussions, and postoperative follow-ups foster real-time
adjustments to care plans and ensure that the entire team, from surgeons
to recovery nurses, is aligned in addressing complications like
infection or arrhythmias. The heart team approach, observed in coronary
artery disease management, illustrates the value of diverse perspectives
in clinical decision-making, as noted in American and European
guidelines.[\[29\]](https://www.statpearls.com/Keywords/UserViewPopup/170705#ref_36632841) This
coordinated care continues into outpatient follow-up, with cardiologists
and primary care providers monitoring long-term patient progress.
Patient outcomes are enhanced through teamwork, communication, and
shared decision-making, and surgical risks are minimized.