1Department of Internal Medicine, Patliputra Medical College and Hospital, Dhanbad, India; 2Department of Cardiology, Sree Chitra Tirunal Institute for 
Medical Sciences & Technology, Trivandrum, India; 3Department of Cardiovascular Radiology, All India Institute of Medical Sciences, New Delhi, India
*Corresponding Author’s e-mail: avinashmani1@gmail.com

Causal Relationship of the Transverse Left 
Ventricular Band and Bicuspid Aortic Valve

Manoj K. Dubey,1 *Avinash Mani,2 Vineeta Ojha3

Sultan Qaboos University Med J, August 2021, Vol. 21, Iss. 3, pp. 403–407, Epub. 29 Aug 21
Submitted 5 Jul 20
Revision Req. 3 Sep 20; Revision Recd. 17 Sep 20
Accepted 4 Oct 20

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

https://doi.org/10.18295/squmj.4.2021.020

CLINICAL & BASIC RESEARCH

The bicuspid aortic valve (bav) is the most common congenital lesion found in the adult population, with an overall incidence 
of 0.4–2.2%.1 Aortic stenosis and aortic regurgitation 
develop over time, with aortic stenosis being more 
common among those whose age has advanced. 
The development of aortic stenosis imposes undue 
haemodynamic stress on the left ventricle.2 BAVs 
are also associated with aortopathy which may be 
due to genetic or haemodynamic factors. These 
have far-reaching consequences as they can lead to 
aortic aneurysm and aortic dissection.3 Detection of 
BAV is done mainly with the help of transthoracic 
echocardiography (TTE). The diagnosis relies on the 
visualisation of two aortic cusps with or without a raphe 
and two commissures in the short-axis view. TTE has 
a sensitivity of 87.7% and specificity of 88.3% in the 
diagnosis of BAV.4 However, the identification of BAVs 
can be difficult in the presence of severe calcification 
and fibrosis or a very prominent raphe, which may be 

masquerading as a third coaptation line. Detection of 
bicuspid aetiology is necessary as these valves tend 
to undergo stenosis at an earlier age as compared to 
the tricuspid valves and can more commonly develop 
infective endocarditis.6,7 Regular follow-up is required 
for the detection of any complications. 

The transverse left ventricular (LV) band has 
been considered to be a benign anatomical variant, 
with similar incidence in patients with structural 
heart disease and a normal heart.8 Several studies 
have shown the presence of the conduction tissue 
and myocardial cells in LV bands, which are in 
continuity with left bundle branch of the conduction 
system.8,9 The transverse LV band has been associated 
with the presence of early repolarisation changes 
on an electrocardiogram.10 However, they are not a 
specific substrate for arrhythmias such as ventricular 
tachycardia.11 Thick robust transverse LV bands are 
believed to be associated with increased wall stress of 
the left ventricle. Increased wall stress can be noted 

abstract: Objectives: Bicuspid aortic valve (BAV) is the most common congenital lesion found in adults. It can 
be seen in combination with a transverse left ventricular (LV) band. This study aimed to find an essential relationship 
between the presence of transverse ventricular band and BAV. Methods: A total of 13 patients from a tertiary care 
centre in India with transverse LV band were investigated during a six-month period from January 2019 to July 2019. 
LV band thickness and gradients at the site of the LV band were evaluated as part of its effect on LV haemodynamics. 
The morphology of the aortic valve and LV outflow tract gradients was assessed. Results: The mean age of the 
participants was 41 years. A majority had a BAV (n = 11). Average thickness of the LV band was 6.2 mm and the 
average mean aortic gradient was 4 mmHg. Sequestration of blood was noted at the level of the transverse band in 
all the patients with two separate jets at the left ventricular outflow tract. The anterolateral jet was deflected from the 
transverse band and showed higher velocity compared to the other jet, causing turbulence at the BAV. No correlation 
was found between the thickness of the transverse band and aortic valve gradient. Conclusion: Presence of a robust 
transverse LV band can serve as a surrogate marker for BAV. 

Keywords: Bicuspid Aortic Valve; Aortic Stenosis; Ventricular Outflow Obstruction; Hemodynamics. 

Advances in Knowledge
- Transverse left ventricular (LV) band has been considered a vestigial part of the ventricle. However, the role played by this band in 

presence of other disorders is insufficiently known. 
- LV band is likely to play an important role in the haemodynamics of the bicuspid aortic valve (BAV). 
- Bidirectional flow at the level of the LV band may help reduce the ventricular strain imposed by the increased afterload in the presence 

of the BAV. 

Application to Patient Care 
- In patients with aortic stenosis, determination of aortic valve morphology plays a crucial role in determining future management. 
- In heavily calcified valves where valve morphology is unclear, detection of a thick robust left ventricular (LV) band may serve as an 

indicator to the presence of a bicuspid aortic valve (BAV).

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


Causal Relationship of the Transverse Left Ventricular Band and Bicuspid Aortic Valve

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

in conditions with raised afterload and LV outflow 
obstruction (LVOTO) or in the case of BAV.12 Thus, 
the presence of BAVs could be associated with thick 
robust LV bands. This study aimed to evaluate the 
relationship between BAVs and the presence of 
transverse LV bands. Another aim of this study was to 
determine whether the presence of a robust LV band 
can give an indirect evidence of bicuspid morphology 
of stenosed aortic valve. 

Methods

This is a prospective observational single-centre study, 
conducted at a tertiary care hospital in India, over a 
period of six months from January 2019 to July 2019. 
All patients who underwent two-dimensional TTE for 
the diagnosis of a cardiac disease were screened for the 
presence of transverse LV band. The patients, above 
18 years of age who were detected to have transverse 
LV band via TTE were included in this study, whereas 
patients with LV dysfunction, poor echo window and 

ambiguous aortic valve morphology were excluded. 

Baseline demographics and clinical character- 
istics, including risk factors, of all the study participants 
were collected. Prior history of cardiac disease was 
evaluated. Coronary artery disease was defined in 
terms of a patient having a history of myocardial 
infarction or angina on regular anti-anginal and 
anti-platelet drugs. All the patients in the current 
study underwent TTE on the Vivid T8 machine (GE 
Healthcare Systems, Chicago, USA), using a linear 
echocardiography probe of 3.5 MHz frequency. Those 
LV bands that were visible in at least two views were 
considered to be definite. The internal LV dimensions 
and ejection fraction were recorded. The presence of 
wall motion abnormality and valvular disease was also 
noted alongside the characteristics of the LV bands 
in terms of position, extent, point of insertion and 
average dimension. Thereafter, the effect of the LV 
bands on LV haemodynamics was evaluated and the 
dimensions of the LV band were correlated with the 
severity of the outflow gradient. 

Baseline data were collected using a structured 
questionnaire and have been presented as summary 
statistics. Categorical variables have been presented 
as proportions, whereas continuous variables have 
been presented as means and standard deviations. The 
correlation analysis was conducted using Spearman’s 
correlation coefficient to evaluate the relationship 
between the dimensions of the LV bands and aortic 
valve gradients. All statistical analyses were performed 
using Statistical Package for the Social Sciences (SPSS) 
Version 25.0 (IBM Corp., Armonk, New York, USA). 
Informed and written consent was obtained from the 
patients. This study was approved for exemption from 
institutional permission by the Institutional Review 
Board. 

Results

A total of 13 patients were included in this study. The 
mean age of the study population was 41.1 years with 
males comprising 53.8% (n = 7) of the participants 

Table 1: Baseline demographic characteristics of patients 
with a bicuspid aortic valve (N =13) 

Baseline Characteristics Mean ± SD

Age in years 41.1 ± 12.9

Body surface area in metres 1.62 ±0.34

Left ventricular internal dimension (in mm)

LVEDD 43.6 ± 6.3

LVESD 26.8 ± 5.4

Left ventricular ejection fraction 69.6 ± 4.5

Peak aortic gradient in mmHg 24.5 ± 16.3

Mean aortic gradient in mmHg 14.1 ± 11.3

Aortic valve area in cm2 1.62 ± 0.67

Indexed aortic valve area in cm2/m2 1.05 ± 0.47

Transverse LV band thickness in mm 6.2 ± 1.8

Baseline Characteristics n (%)

Males 7 (53.8)

Females 6 (46.2)

Diabetes mellitus 3 (23.1)

Hypertension 7 (53.8)

Dyslipidaemia 4 (30.7)

Family history of cardiac disease 0 (0)

Coronary artery disease 2 (15.4)

AR grade 2+ 2 (15.4)

SD=standard deviation; LVEDD = left ventricular end-diastolic dimension; 
LVESD = left ventricular end-systolic dimension; LV = left ventricle; AR 
= aortic regurgitation.

Figure 1: Parasternal short axis view showing a bicuspid 
aortic valve (A) in the open state during ventricular 
systole (B) with a raphe in a patient obtained via 
transthoracic echocardiography. 



Manoj K. Dubey, Avinash Mani and Vineeta Ojha

Clinical and Basic Research | 405

[Table 1]. Majority (85%) of the patients had a BAV 
[Figure 1] and transverse LV band was noted in all the 
patients [Figure 2]. 

The average thickness of the LV band imaged was 
6.2 mm. The most robust LV band had a dimension 
of 8 mm (n = 5), whereas the slenderest band had a 
dimension of 3 mm (n = 1). The average aortic valve 
area for patients with LV band was 1.62 ± 0.67 cm2, 
whereas the average indexed aortic valve area was 
1.05 ± 0.47 cm2/m2. The average peak gradient across 
the aortic valve was noted to be 24.5 mmHg and 
the average peak velocity was 2.3 m/s. Mean aortic 
gradient in the study population was 14.1 ± 11.3 
mmHg. Sequestration of blood was noted at the level 
of the transverse band in all the patients [Figure 3]. 

Most cases (80%) demonstrated two separate jets 
at the left ventricular outflow tract (LVOT). The septal 
side of the LVOT demonstrated a straight jet from 
the LV apex, while the anterolateral jet was deflected 
from the transverse LV band towards the LVOT. Pulse 
wave Doppler analysis revealed that the anterolateral 
jet had a higher velocity than the septal jet and caused 
turbulence at the bicuspid valve [Figure 4]. 

The correlation analysis showed that there was 
no significant correlation between the aortic valve 
gradient and thickness of the LV band (r = 0.423; P = 
0.15). Furthermore, the aortic valve area did not show 

any significant correlation with LV band thickness (r = 
−0.48; P = 0.09). 

Discussion

The current study aimed to evaluate the relationship 
between transverse LV band and BAV. A majority 
of the patients participating in this study were 
young individuals without major comorbidities. 
All the patients had normal ventricular function 
on echocardiography with a majority of them 
having a BAV. Distinct transverse LV bands were 
noted in all of these patients. A previous study had 
associated the presence of LV band with structural 
and functional changes involving LV systolic and 
diastolic dysfunction.13 However, none of the patients 
in the current study had any evidence of systolic or 
diastolic dysfunction. The same study had also found 
that transverse LV bands are associated with mitral 
regurgitation.13 

Based on the orientation of the LV band, different 
types of LV bands have been described in the relevant 
literature. The most common location of the LV band 
is between the posteromedial papillary muscle and 
ventricular septum.14 It has been proposed that the 
transverse LV band which straddles the septum and 
the lateral wall of the ventricle prevents ventricular 
dilatation in the event of ventricular remodelling.15 
The presence of LV band between the posteromedial 
papillary muscle and septum can prevent ventricular 
dilatation after an infero-posterior wall myocardial 
infarction. Similarly, the LV band located between 
the free wall and the septum can inhibit ventricular 

Figure 2: Parasternal and apical long axis views showing a robust left ventricular band (arrows) extending from the 
interventricular septum to the posterior wall of the left ventricle obtained via transthoracic echocardiography.

Figure 3: Pulse wave Doppler at the level of transverse 
band showing bidirectional flow due to deflection of 
blood by the band in a patient with a bicuspid aortic 
valve. 

Figure 4: Pulse wave doppler analysis of (A) septal jet 
and (B) anterolateral jet in the left ventricular outflow 
tract showing higher velocity of anterolateral jet in a 
patient with a bicuspid aortic valve. 



Causal Relationship of the Transverse Left Ventricular Band and Bicuspid Aortic Valve

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

dilatation after an anterior wall myocardial infarction. 
A reduction in the ventricular dilatation during 
remodelling can also reduce tethering of mitral 
leaflets, which can effectively reduce functional mitral 
regurgitation.15 Thus, the presence of a transverse LV 
band may be associated with the preservation of the 
ventricular architecture. This can account for the non-
dilated ventricles observed during the present study 
despite the presence of increased haemodynamic 
stress of BAV and aortic stenosis. 

The presence of BAV with or without the valvular 
dysfunction can impose a significant haemodynamic 
burden on the left ventricle. Studies using cardiac 
magnetic resonance imaging (MRI) have demonstrated 
markedly abnormal helical flow in ascending aorta in 
BAV patients. This abnormal flow was also seen in BAV 
patients without any degree of stenosis.16 An abnormal 
leaflet motion during cardiac cycle (wrinkling of valve 
tissue and excessive doming of valve leaflets) was noted 
in the current study, which resulted in an increased 
turbulence across the valve even when the valve was 
not stenotic. The cause of such abnormal motion 
is probably the unequal leaflet length. A turbulent 
helical flow across the aortic orifice can produce 
shear stress and lead to medial degeneration via the 
activation of matrix metalloproteinase pathways.17 
Barker et al. used computational flow dynamics in 
MRI to investigate wall shear stress (WSS) in patients 
with BAV.18 All patients with BAV had abnormal flow 
in the ascending aorta and transverse arch, while the 
flow was completely normal in patients with tricuspid 
aortic valve. BAV patients are likely to have jet flow 
impingement along the greater curvature of the 
ascending aorta, leading to WSS.19 LV parameters have 
also been studied in the presence of BAV. In a cohort 
of 58 children with BAV, cardiac MRI showed that 
elevated aortic peak velocity and WSS had a negative 
correlation with LV global longitudinal strain.20 
Cardiac MRI analysis in a cohort of BAV subjects 
showed that patients with valvular dysfunction had 
significantly elevated LV mass and peak WSS in the 
ascending aorta.21 A positive correlation was noted 
between extracellular volume fraction and aortic WSS, 
indicating significant ventricular remodelling in the 
face of elevated shear stress. All this evidence points 
to the presence of elevated haemodynamic stress 
on the left ventricle in the presence of BAV, which 
predisposes it to ventricular remodelling. 

The left ventricle needs a compensatory mechanism 
to counteract this haemodynamic burden. This can 
manifest in the form of the hypertrophied LV band. 
The hypertrophied LV band contains myocardial 
tissue and conductive tissue having properties of 

contraction and relaxation. Thus, they can prevent the 
overstretching of the left ventricle.22 The transverse 
LV band helps to sequester blood proximally during 
diastole and diverts it towards the LVOT in an effort 
to reduce the haemodynamic stress during systole.21 
The hypertrophy of the LV band is likely related to the 
added haemodynamic stress posed by the BAV where 
it attempts to prevent LV dilatation and remodelling. 
The authors hypothesise that this may be the probable 
reason for hypertrophied LV bands in BAV patients 
with low aortic gradients. The thickness of the 
transverse band was usually similar to the moderator 
band of the right ventricle as observed in this study. 
Furthermore, no definite correlation was found 
between the thickness of the LV band and the aortic 
valve gradient or the aortic valve area in the current 
study. However, the presence of a robust LV band in 
all patients with BAV could not be demonstrated in 
this series. There is paucity of data on the presence of 
transverse LV band in patients with BAV and aortic 
stenosis. Further studies are required to delineate the 
LV haemodynamics in patients with BAV and LV band. 
MRI studies can help in determining the changes in 
ventricular remodelling observed in patients with BAV 
and transverse LV band. Echocardiography has been 
a robust modality for the detection of transverse LV 
bands.15 Thus, in conditions where the aortic valve 
morphology is not clear due to heavy calcification, the 
presence of a robust LV band may offer an indication 
of the presence of BAV in the absence of other 
confounding factors such as ventricular dilatation and 
mitral regurgitation. 

This study had some limitations. First, the sample 
size was small due to financial constraints. Second, 
complete dimensions of the LV band could not be 
measured by echocardiography and only thickness was 
taken as a marker of the robustness of the structure. 
Finally, cardiac MRI could not be performed to evaluate 
LV remodelling in patients with BAV and LV band due 
to financial constraints and lack of availability of MRI 
facilities at our centre. Larger studies are warranted 
in patients with BAV and LV band to understand the 
interplay of haemodynamics. 

Conclusion

The presence of a robust transverse LV band may 
serve as a surrogate marker for BAV. Larger studies 
using cardiac MRI are required to prove a definite 
association between robust LV band and dysfunctional 
BAV. 

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. 



Manoj K. Dubey, Avinash Mani and Vineeta Ojha

Clinical and Basic Research | 407

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
MKD and AM were involved with the conceptualisation 
and design of the study as well as data collection and 
analysis. MKD, AM and VO equally contributed to the 
preparation of the manuscript. VO was responsible 
for image preparation and graphics. All the authors 
reviewed and approved the final version of the 
manuscript. 

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