Dermatology: Practical and Conceptual


Dermatology Practical & Conceptual

Original Article | Dermatol Pract Concept. 2022;12(1):e2022011 1

Prevalence of Atherosclerosis in Psoriatic Patients 
Detected with Epiaortic Color Doppler Ultrasound 

and Computed Tomography Angiography
Annunziata Dattola1, Guglielmo Manenti2, Donatella Ferrari2, Laura Vollono1,  

Salvatore Marsico2, Feliciana Lamacchia2, Maria Esposito1, Mattia Marchesano1,  
Arianna Zangrilli1, Roberto Floris2, Alessandro Giunta1, Luca Bianchi1

1 Dermatology Department, University of Rome “Tor Vergata”, Rome, Italy

2 Biomedicine and Prevention Department, UOC of Diagnostic Imaging, University of Rome “Tor Vergata”, Rome, Italy

Key words: psoriasis, color-doppler ultrasound, angio-CT, IMT, risk-factor

Citation: Dattola A, Manenti G, Ferrari D, et al. Prevalence of atherosclerosis in psoriatic patients detected with epiaortic color doppler 
ultrasound and computed tomograpgy angiography. Dermatol Pract Concept. 2022;12(1):e2022011.  
DOI: https://doi.org/10.5826/dpc.1201a11

Accepted: May 6, 2021; Published: January 2022

Copyright: ©2022 Dattola et al. This is an open-access article distributed under the terms of the Creative Commons  
Attribution-NonCommercial License (BY-NC-4.0), https://creativecommons.org/licenses/by-nc/4.0/, which permits unrestricted 
noncommercial use, distribution, and reproduction in any medium, provided the original authors and source are credited.

Funding: None.

Competing interests: None.

Authorship: AD and GM have equally contributed to this article. 

Corresponding author: Annunziata Dattola, MD, PhD. Dermatology Department, University of Rome “Tor Vergata”, Rome, Italy.  
E-mail: nancydattola@gmail.com

Introduction: Psoriasis (PsO), a chronic inflammatory, multisystemic, and multifactorial disease can 
cause endothelial dysfunction, artery calcification, and atherosclerotic disease. A higher incidence of 
vascular occlusive events has been observed in psoriatic patients compared to healthy controls, and 
multiple studies confirm the association between moderate-severe PsO and atherosclerosis, coronary 
artery calcification, and higher cardiovascular risk. 

Objective: We sought to analyze atherosclerotic disease prevalence in epiaortic vessels of psoriatic and 
non-psoriatic patients to understand if PsO could represent an independent risk factor predisposing 
to atherosclerotic disease.

Methods: We evaluated 47 psoriatic patients without cardiovascular risk factors with color Doppler 
ultrasound (CDUS). If atheromatous plaques were detected, a computed tomography angiography 
(CTA) was performed. We evaluated 47 non-psoriatic patients without cardiovascular risk factors with 
CDUS. Atherosclerosis prevalence in both groups were statistically analyzed. CDUS performance was 
compared to CTA.

Results: In the psoriatic group (mean age 50.9 years), 6 had atheromatous plaques and 12 had an 
intima-media thickness (IMT) > 1 mm (overall prevalence of atherosclerotic disease: 38.2%). All 
plaques detected with CDUS were confirmed at CTA.  In the control group (mean age 51.3 years), 

ABSTRACT



2 Original Article | Dermatol Pract Concept. 2022;12(1):e2022011

Introduction

Psoriasis (PsO) is a chronic inflammatory, multisystemic, and 

multifactorial disease that affects about 3% of the world pop-

ulation [1]. The chronic systemic inflammatory process, that 

primarily affects the skin, also causes endothelial dysfunction, 

artery calcification, and atherosclerotic disease [2]. A higher 

incidence of vascular occlusive events has been observed in 

psoriatic patients compared to healthy controls, and multiple 

studies confirm the association between moderate-severe PsO 

and atherosclerosis, coronary artery calcification, and higher 

cardiovascular risk [3-8]. Young adults affected by severe PsO 

are 3 times more likely to face myocardial infarction than 

controls [9], and the risk of fatal myocardial infarction or 

stroke is even higher in patients hospitalized with PsO [10]. 

Moreover, a higher frequency of ischemic heart disease and 

cerebral and peripheral vascular disease has been observed 

in patients affected by moderate-severe disease compared 

with controls [11]. Thus, current opinion holds that PsO is an 

independent risk factor for cardiovascular disease [2,12,13].

Color Doppler ultrasonography (CDUS) of the carotid 

arteries is a first-level imaging technique performed in the 

diagnosis of carotid atherosclerotic disease. Ultrasonography 

(US) is the modality of choice for screening, diagnosis, and 

monitoring atheromatous disease because it is a fast, non-in-

vasive, low-cost technique that evaluates the macroscopic 

appearance of atheromatous plaques as well as flow char-

acteristics in the carotid artery. Although US is considered a 

useful tool in the assessment of the cardiovascular risk, there 

are few studies so far conducted regarding its use in patients 

affected by psoriasis vulgaris and psoriatic arthritis.

Computerized tomography angiography (CTA) is a very 

accurate technique for evaluating carotid stenosis, outper-

forming CDUS [14], but not as accurate in describing carotid 

plaques and assessing their vulnerability.

Objectives

The aim of this study is to evaluate the prevalence of ath-

erosclerotic disease in epiaortic vessels of psoriatic patients 

without conventional cardiovascular risk factors, using CDUS 

and CTA, and to analyze the presence of any difference in 

prevalence with non-psoriatic patients, in order to understand 

if PsO could be considered as an independent risk factor for 

atherosclerotic disease.

Methods

This study was conduct in collaboration between the Depart-

ments of Dermatology and Diagnostic Imaging at the Uni-

versity of Rome Tor Vergata. The study was conducted from 

January 2017 to July 2017 at the Department of Dermatol-

ogy. We enrolled 280 consecutive patients (males and females) 

with psoriasis vulgaris or arthropathic psoriasis. The patients 

underwent clinical and laboratory exams, including abdom-

inal circumference measurements and arterial pressure. We 

determined if the patients were cigarette smokers and if had 

hypercholesterolemia, hypertriglyceridemia, and glycemia. 

The inclusion criteria of the study were: male and female 

patients aged 35-85 years, with an abdominal circumference  

< 102 cm for males and < 88 cm for females, cholesterol plas-

matic level < 200 mg/dl, plasma glucose level < 126 mg/dl 

on 2 separate analyses, systolic pressure < 140 mmHg and 

diastolic pressure < 90 mmHg, and non-smoker or < 5 ciga-

rettes/day smoker.

The exclusion criteria were: contraindications to iodin-

ated contrast agent administration, pregnancy, regular use of 

alcohol (> 2 drinks/day), oncological history, family history 

of vascular disease, transient ischemic attack or stroke in the 

previous 5 years, and current or past use of intravenous drugs. 

The final study group was composed of 47 psoriatic 

patients (patient group: 26 males and 21 females, aged 35-70 

years), without conventional cardiovascular risk factors, and 

an equal number of non-psoriatic subjects, who had under-

gone epiaortic vessel CDUS at the Department of Diagnostic 

Imaging, recruited retrospectively between January 2017 and 

July 2017, (control group: 27 males and 20 females, aged 

35-70 years). They underwent CDUS as a general exam, and 

from the medical interview carried out before the US exam-

ination it was determined they were in good health with no 

noteworthy diseases or underlying conditions, and without 

conventional cardiovascular risk factors.

Among the psoriatic patients, 37 were affected by psori-

asis vulgaris and 10 by severe psoriatic arthritis, and all of 

CDUS revealed atheromatous plaques in 4 patients and IMT > 1 mm in 4 ones (overall prevalence of 
17%). The difference of atherosclerotic disease prevalence between the groups was statistically signif-
icant (P < 0.05).

Conclusion: Our results highlight that PsO could be considered a predisposing factor for atheroscle-
rotic disease development in epiaortic vessels, as it causes an increased IMT, that is also considered an 
independent cardiovascular risk factor. 



Original Article | Dermatol Pract Concept. 2022;12(1):e2022011 3

them were being treated with systemic drugs including cyclo-

sporine and/or methotrexate and anti-tumor necrosis factor 

α (TNF-α) biologic drugs. All the subjects gave informed 
consent prior to their inclusion in the study.

All the subjects underwent epiaortic vessels CDUS. These 

evaluations were executed with a high-resolution US equip-

ment (Philips iU22 Ultrasound System,), using a high-fre-

quency linear probe (9-3 MHz) and a carotid preset. The 

neck vessels studied were common carotid arteries, internal 

carotid arteries and external carotid arteries, and we evalu-

ated both side regions of the neck for each subject for a total 

of 94 common carotid arteries, 94 internal carotid arteries, 

and 94 external carotid arteries in the psoriatic patients and 

an equal number of vessels in the non-psoriatic subjects. The 

vertebral arteries were examined in all participants, but the 

results obtained were not included in the study.

The US examinations were carried out by a radiologist 

with 5 years of experience, and the images were evaluated 

in consensus with a radiologist with 25 years of experience. 

The US exams were performed at first in B-mode with axial 

and longitudinal scans in order to identify arterial wall inti-

ma-media thickness (IMT) of common carotid arteries and 

the presence of common and internal carotid plaques. 

The IMT measurement was performed automatically with 

dedicated software. The mean value between left and right 

sides was taken into consideration and an IMT <1 mm was 

considered normal. The presence of a plaque was considered 

when a focal IMT was greater than 50% of the surrounding 

area [15]. Subsequently CDUS, and pulsed Doppler spectral 

analysis were performed: peak systolic velocity (PSV cm/s) 

and end diastolic velocity (EDV cm/s) values were analyzed 

to determine the percentage of stenosis and plaque hemo-

dynamics. 

When at least 1 carotid plaque or an increased IMT of the 

common carotid on a side was detected with US examination, 

the patient was considered positive for atherosclerotic disease. 

If both carotids had an IMT >1 mm, the average thickness of 

the 2 was taken into consideration.

In the psoriatic patient group, if CDUS examination 

detected atherosclerotic plaque, the patient had to go simul-

taneous CTA of the extracranial vessels in order to confirm 

its presence, better define plaque features, determine the per-

centage of stenosis, and search for the presence of additional 

plaques in other locations. Psoriatic patients who at CDUS 

presented an IMT >1 mm were asked to follow-up after 12 

months with another CDUS to check for vascular disease. 

The psoriatic patients who did not present any atherosclerotic 

pathology at CDUS were asked to follow-up with regular 

dermatological visits.

Subjects of the control group underwent epiaortic vessel 

CDUS. If a plaque revealed severe stenosis (> 70%) or if signs 

of surface ulceration were detected, they underwent a CTA 

to ensure adequate therapeutic diagnostic planning of the 

incidental finding, according to the current clinical practice. 

The CTA was performed using a Lightspeed VCT 64-slice 

scanner (General Electric), with a pre-contrast phase and an 

arterial phase with bolus tracking, with a non-ionic iodin-

ated contrast agent injection (350 mg/ml) with a flow rate of  

3.5 ml/s, followed by a bolus of 20 ml of saline flush at 

the same speed. The images were also analyzed in 3D, with 

multiplanar reconstruction and volume rendering and inter-

preted in consensus with the same two radiologists. When a 

plaque was detected, the carotid stenosis was quantified by 

the NASCET method: (distal diameter of the internal carotid 

− residual diameter / distal diameter of the internal carotid) 

×100 [16]. The radiological features of the detected plaques 

analyzed with CDUS and CTA were the percentage of steno-

sis, structure, and surface. 

Continuous variables, normally distributed (patient age, 

IMT thickness) were presented as the mean ± standard 

deviation (SD) and categorical variables were presented as 

counts (percentage). Fisher exact test was used to compare 

differences in atherosclerotic disease prevalence between 

psoriatic patients and healthy subjects. Any P value < 0.05 

was considered statistically significant. 

Results

The mean (SD) age of the psoriatic group was 50.9 ± 8 years 

(range 35-70 years), and of the control group 51.3 ± 8 years 

(range 35-70 years). In the psoriatic patients an IMT > 1 mm 

without carotid plaques (Figure 1) was found in 12 patients 

(25.5%), with a mean value of 1.4 mm (range 1.1-1.8 mm). 

Atheromatous plaques were found in 6 patients, mean age 

57.5 ± 4.6 years (range 50-64 years), with a prevalence of 

12.7%. In 4 patients, an increase of IMT coexisted, thus the 

Figure 1. Longitudinal US of the right common carotid artery of a 

51-year-old female psoriatic patient with an IMT > 1 mm without 

plaque. IMT = intima-media thickness; US = ultrasonography.



4 Original Article | Dermatol Pract Concept. 2022;12(1):e2022011

increase of IMT was detected in a total of 16 patients with 

a prevalence of 34%. A total number of 18 patients showed 

carotid atherosclerotic disease with an overall prevalence 

of 38.2%.

Plaques were found in 6 patients and were localized in 

carotid arteries bilaterally in each patient, with a total number 

of 12 plaques. Among these, US revealed 2 plaques located 

in internal carotid artery (ICA), 4 plaques located in carotid 

bifurcations, and 6 plaques located in carotid bifurcations 

extended to the ipsilateral ICA. Moreover, the structure of the 

plaques was hypoechoic in 4 cases (33%) and fibrocalcific in 

8 cases (67%). The plaque surface was smooth (83.4%) or 

irregular (16.6%), no ulceration signs were detected at US 

examination. In these 12 cases the plaques revealed mild ste-

nosis, with a percentage of stenosis variable at 10-30%. Pulsed 

Doppler spectral analysis consistently showed a PSV < 125 

cm/s with an EDV < 40 cm/s in the ICA, demonstrating that 

the stenosis was not hemodynamically significant (Figure 2).

All plaques detected with CDUS analysis were confirmed 

with CTA examination (Figure 3). At the final CTA, 4 plaques 

were in a left bifurcation and ICA (33.3%), 3 plaques were 

in a right bifurcation and ICA (25%), 2 plaques were in a 

Figure 2. (A) Longitudinal ultrasonography of a hypoechoic plaque in the right internal carotid artery of a 50-year-old male psoriatic patient 

with a smooth surface that produced stenosis of about 25%. (B) Axial ultrasonography of the same plaque. (C) longitudinal color Doppler ul-

trasonography and pulsed Doppler spectral analysis of this plaque showing a peak systolic velocity of 40 cm/s, not hemodynamically significant.



Original Article | Dermatol Pract Concept. 2022;12(1):e2022011 5

right bifurcation (16.6%), 1 in a left bifurcation (8.3%), 1 

in a right ICA (8.3%) and 1 in a left ICA (8.3%); 8 plaques 

were fibrocalcific (67%), 2 hypoechoic plaques which were 

previously documented at US showed a wide fibrous cap 

(16.5%), and 2 were lipid-rich plaques (16.5%) (Table 1). 

All of them produced a stenosis < 30% and none of them 

showed features of vulnerable plaques following both CDUS 

and CTA examinations. Our results showed good agreement 

between the two imaging techniques, with a concordance rate 

of 92% between CDUS and CTA regarding plaque localiza-

tion, 83% regarding plaque structure, and 100% regarding 

both percentage of stenosis and plaque surface morphology. 

Figure 3. (A) Axial ultrasound of a fibrocalcific plaque in left internal carotid artery of a 58-year-old male psoriatic 

patient, with a smooth surface that produced stenosis of about 20%. (B) Oblique reconstruction of computed to-

mography angiography of the plaque that produced a stenosis of about 20%.

Table 1. Epidemiological Characteristics of Psoriatic Patients with Plaques (n = 6) and Features of 
These Plaques (n = 12) With CDUS and CTA Examinations*

Psoriatic Patient Technique Location Stenosis Structure Surface

Male, 60 years

CDUS Right bifurcation + ICA 30% Fibrocalcific Irregular

CTA Right bifurcation + ICA 30% Fibrocalcific Irregular

CDUS Left bifurcation + ICA 30% Fibrocalcific Irregular

CTA Left bifurcation + ICA 30% Fibrocalcific Irregular

Male, 50 years

CDUS Right ICA 25% Lipid-rich Smooth

CTA Right ICA 25% Lipid-rich Smooth

CDUS Left bifurcation + ICA 20% Fibrocalcific Smooth

CTA Left bifurcation + ICA 20% Fibrocalcific Smooth

Male, 58 years

CDUS Right bifurcation 15% Fibrocalcific Smooth

CTA Right bifurcation 15% Fibrocalcific Smooth

CDUS Left ICA 20% Fibrocalcific Smooth

CTA Left ICA 20% Fibrocalcific Smooth

Female, 64 years

CDUS Right bifurcation + ICA 30% Fibrocalcific Smooth

CTA Right bifurcation + ICA 30% Fibrocalcific Smooth

CDUS Left bifurcation 20% Lipid-rich Smooth

CTA Left bifurcation + ICA 20% Lipid-rich Smooth

Female, 57 years

CDUS Right bifurcation 20% Lipid-rich Irregular

CTA Right bifurcation 20% Fibrous + lipid core Irregular

CDUS Left bifurcation + ICA 10% Fibrocalcific Smooth

CTA Left bifurcation + ICA 10% Fibrocalcific Smooth

Female, 56 years

CDUS Right bifurcation + ICA 15% Fibrocalcific Smooth

CTA Right bifurcation + ICA 15% Fibrocalcific Smooth

CDUS Left bifurcation 20% Lipid-rich Smooth

CTA Left bifurcation 20% Fibrous + lipid core Smooth

*CDUS errors compared to CTA are highlighted in gray.  
CDUS = color Doppler ultrasonography; CTA = computed tomography angiography; ICA = internal carotid artery.



6 Original Article | Dermatol Pract Concept. 2022;12(1):e2022011

Moreover, CTA did not reveal the presence of additional 

plaques along the carotid axes or along vertebral arteries. 

Regarding subjects of the control group, US examination 

revealed IMT > 1 mm without carotid atheromatous plaques 

in 4 people (8.5%) bilateral or unilateral, with a mean value of 

1.2 mm (range 1.1-1.5). Atheromatous plaques were detected 

in 4 subjects, mean age 62.5 ± 2.6 years (range 59-64), with 

a prevalence of 8.5%. Plaques were unilateral in 2 cases and 

bilateral in 2 cases, with a total number of 6 plaques. The 

structure of these plaques was hypoechoic in 2 cases (33.3%), 

and fibrocalcific in 4 cases (66.7%), with a variable percent-

age of stenosis at 10-20%, and none of them were hemody-

namically significant at color Doppler analysis. Other plaque 

features of the control group subjects are explained in Table 2. 

In 2 cases an increased IMT coexisted, thus an increased IMT 

was detected in a total of 6 subjects with a prevalence of 

12.7%. A total number of 8 cases showed carotid atheroscle-

rotic disease with an overall prevalence of 17%. The Fisher 

exact test statistic value was 0.0368, and this result highlights 

the presence of a statistically significant difference (P < 0.05) 

between the prevalence of carotid atherosclerotic disease 

(increase of IMT and/or atheromatous plaques) in patients 

without cardiovascular risk factors affected by PsO and those 

without cardiovascular risk factors and without PsO. 

Conclusions

PsO is a chronic systemic inflammatory disease. With the term 

“psoriasis march,” Boehncke et al described the process that 

starts from genetic and environmental predisposing factors 

and leads to a dysregulation of the immune system that gives 

rise to a chronic systemic inflammatory state that also causes 

endothelial dysfunction, atherosclerosis, and coronary events. 

Innate and adaptive immune systems are likewise considered 

responsible for pathological changes in both epidermis and 

vascular walls [2].

A recent meta-analysis of 4 genome-wide association 

studies selected a broad number of single nucleotide poly-

morphisms (SNPs) that showed a significant association with 

cardiovascular disease, hypertension, body mass index, hyper-

lipidemia, or type II diabetes. They then investigated which 

one of these polymorphisms was also associated with PsO 

[17] and identified 8 main SNPs codifying for a key protein 

in the process of lymphocyte differentiation, thrombogenesis, 

and in the induction of VCAM1 and E-selectin on the surface 

of endothelial cells under the stimulation of TNF-α. This 
might explain its dual role in establishing a susceptibility 

to multiple immune-mediated and cardiovascular diseases. 

Subcutaneous tissue is able to produce proinflammatory cyto-

kines and C-reactive protein under the influence of mediators 

such as TNF-α [18].
Modifications in the adipocyte metabolic profile, 

including alterations of adiponectin, leptin and resistin, 

are considered responsible in starting or maintaining the 

inflammatory process [19]. In particular, high blood lev-

els of resistin seem to be related to a proinflammatory 

systemic state, insulin-resistance, and atherosclerosis [2]. 

Metabolic syndrome is more frequent in psoriatic patients 

than in the general population [12], and its prevalence 

directly correlates to PsO duration and severity [20]. Of 

note, the abovementioned effects are particularly relevant 

when dealing with central or visceral obesity [21]. A direct 

correlation between severity of PsO, central obesity and 

vascular inflammation has been reported, with concurrent 

reduction of these parameters after 12 months of systemic 

or biologic therapy [22].

Table 2. Epidemiological Characteristics of Non-Psoriatic Patients (n = 8) with Atheromatous 
Pathology (IMT >1 mm and/or plaques) and Features of the Plaques (n°=6) Detected With CDUS

Non-Psoriatic Subjects Location Pathology Stenosis Structure Morphology

Male, 64 years Right bifurcation
Left bifurcation

Plaque
Plaque

15%
20%

Lipid-rich
Fibrocalcific

Smooth
Smooth

Bilateral IMT 1.2 - - -

Male, 65 years Right bifurcation + ICA Plaque 20% Fibrocalcific Smooth

Male, 59 years Left bifurcation + ICA Plaque 10% Lipid-rich Smooth

Female, 62 years Left bifurcation
Right bifurcation + ICA

Plaque
Plaque

15%
15%

Fibrocalcific
Fibrocalcific

Smooth
Smooth

Bilateral IMT 1.2 - - -

Female, 61 years Right IMT 1.2 - - -

Male, 68 years Bilateral IMT 1.3 - - -

Male, 61 years Left IMT 1.1 - - -

Female, 62 years Bilateral IMT 1.1 - - -

CDUS = color Doppler ultrasonography; ICA = internal carotid artery; IMT = intima-media thickness.



Original Article | Dermatol Pract Concept. 2022;12(1):e2022011 7

Recently, sonoelastography has been proposed as a tool 

in monitoring the response to treatment in psoriatic patients, 

as it evaluates hypodermal adipose tissue inflammation 

underneath lesioned plaques at baseline and during systemic 

treatment [23].

Twenty-five years ago, McDonald and Calabresi performed 

the first study showing that patients with PsO had more 

vascular occlusive events than patients without PsO [3]. Sub-

sequently, multiple studies confirmed the association between 

moderate-severe PsO and atherosclerosis, coronary artery 

calcification, higher cardiovascular risk, myocardial infarction, 

stroke and peripheral vascular disease [4-11]. It is hypothesized 

that this association might be due to an overrepresentation in 

the psoriatic population with a Framingham Risk Score (age, 

hypertension, obesity, smoking, diabetes, hypercholesterol-

emia, hyperlipidemia, and familial history) [12]. In addition, 

many traditional systemic therapies for PsO seem to affect 

cardiovascular risk, increasing cardiovascular risk factors such 

as hyperlipidemia, hypertension, and hyperhomocysteinemia. 

Nevertheless, recent studies identified PsO as an independent 

risk factor for cardiovascular disease [9,10,11,12,13,20].

An increased prevalence and severity of coronary artery 

calcification and atherosclerosis (measured by cardiac com-

puted tomography, CTA, or coronary angiography) has been 

reported in psoriatic patients compared to healthy controls 

[24-30]. A lower coronary flow reserve has been observed in 

young subjects, otherwise healthy patients with severe PsO 

compared to controls, suggesting that early impairment of 

coronary microvascular function is independent of conven-

tional cardiovascular risk factors.

Our study reveals abnormalities in the vessel walls of 

carotid arteries in a great percentage of psoriatic patients 

who did not have any cardiovascular risk factors. In par-

ticular, we highlighted a higher prevalence of carotid ath-

erosclerotic disease (increased IMT and/or atheromatous 

plaques) in patients affected by PsO than in healthy subjects 

regardless of cardiovascular risk factors. It was detected in 

an increased IMT, which represents a predisposing risk fac-

tor for stroke events [31]. Analysis of the data also showed 

a higher mean age in the control group affected by athero-

matous plaques than that of psoriatic patients affected by 

atheromatous plaques. In fact, in the control group plaques 

were identified only in subjects with advanced age (subjects 

older than 55 years, the average age of the group); on the 

contrary, in psoriatic group, plaques were also identified in 

younger patients. This also led us to the conclusion that PsO 

can be considered an independent risk factor in the develop-

ment of atheromatous pathology. Our results highlighted a 

good agreement between CDUS and CTA in atheromatous 

plaque detection and plaque analysis, showing a 92% con-

cordance rate between CDUS and CTA regarding plaque 

localization, 83% regarding plaque structure, and 100% 

regarding both percentage of stenosis and plaque surface 

morphology. 

Ultrasound errors were made only in determining the 

plaque composition in 2 cases (2 hypoechoic plaques previ-

ously documented at US showed a wide fibrous cap at CTA), 

and in determining the complete plaque extension along the 

vessel in 1 case (a plaque that at US examination seemed 

localized only in the carotid bifurcation and at CTA appeared 

extended to the ipsilateral ICA). In spite of being a fast, non-

invasive, well tolerated, and low-cost imaging method, US 

is an operator-dependent examination that requires a good 

understanding of Doppler physics and hemodynamic physiol-

ogy. A more precise evaluation of the percentage of stenosis, 

of the composition and of the morphology of the plaque is 

made with CTA, but it uses ionizing radiation and potentially 

allergenic and nephrotoxic contrast agents. In fact, CTA has 

been proved to be an accurate modality for detection of severe 

carotid artery disease and, especially, for detection of occlu-

sions [32]. This means that CDUS should not be replaced as 

the first-line investigation for epiaortic vessels.

Although our results are based on a small cohort of patients, 

we concluded that PsO could be considered a risk factor for the 

development of atheromatous pathology in epiaortic vessels, 

because primarily it causes a thickening of the IMT. Therefore, 

this study contributes to support the hypothesis that PsO should 

be considered as an independent cardiovascular risk factor.

The American Society of Echocardiography more recently 

recommended the cut-off value for IMT at ≥ 1.5 mm, but set 

IMT above 1 mm [15]. The main limitation of this study is the 

small cohort of subjects included and, in this regard, further 

studies with larger cohorts, carried on in close cooperation 

with different medical specialists, finalized to a correct selec-

tion of patients, are necessary to confirm and improve our 

results. This could be relevant in order to aid in the clinical 

management of psoriatic patients and offer them better diag-

nostic/therapeutic pathways to prevent cardiovascular disease. 

We propose that epiaortic CDUS as the most suitable 

method in assessing cardiovascular risk and in the early 

identification of minor changes and atheromatous plaques 

of epiaortic vessels of psoriatic patients.

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