In Vivo Measurement of Plaque Neovascularization and Thermal
Heterogeneity in Intermediate Lesions of Human Carotids
Georgios Benetos
1
, Konstantinos Toutouzas
1
, Haralampos Grassos
1
, Maria Drakopoulou
1
,
Charalampia Nikolaou
1
, Ioannis Felekos
1
, Constantina Aggeli
1
, Eleftherios Tsiamis
1
,
Elias Siores
2
and Christodoulos Stefanadis
1
1
First Department of Cardiology, Athens School of Medicine, Athens, Greece
2
Center of Materials, Research and Innovation, University of Bolton, Bolton, U.K.
Keywords: Microwave Radiometry, Inflammation, Carotid Artery, Atherosclerosis.
Abstract: Purpose: Both plaque angiogenesis and inflammation contribute to the development and progression of
atherosclerosis. Contrast-enhanced ultrasound (CEUS) allows direct visualization of the adventitia vasa
vasorum. Microwave Radiometry (MWR) is a special technology, which quantifies internal temperature of
tissues, reflecting their inflammatory status. In the present study we aimed to evaluate in human carotid
arteries, whether atherosclerotic plaque temperature, measured by MWR, is associated with plaque
neovascularization assessed by CEUS. Methods: For this purpose, 48 consecutive patients with significant
coronary artery disease and carotid plaques in at least one carotid were included in the analysis .All patients
underwent basic ultrasound carotid imaging, neovascularization evaluation through CEUS and temperature
measurements through MWR. Results: Plaques with vulnerable characteristics showed both higher
temperatures and contrast uptake. There was a positive correlation between temperature and CEUS
measurements. Conclusions: In vivo non-invasive assessment of the functional characteristics of carotid
artery atherosclerotic plaques is feasible, promising and may serve as an additional screening tool to identify
‘high risk’ patients for future cerebrovascular events.
1 INTRODUCTION
Both plaque angiogenesis and inflammation
contribute to the development and progression of
atherosclerosis. Contrast-enhanced ultrasound
(CEUS) provides direct visualization of the
adventitial vasa vasorum and intraplaque
neovascularization. Microwave radiometry (MWR)
is a new non-invasive method, which detects
radiation transmitted from internal tissues in
microwave frequencies and converts these signals
into temperature measurements. It allows this way
the in vivo measurement of internal temperature of
tissues, reflecting inflammatory activation. The aim
of the current study is to assess whether carotid
plaque temperature, measured by MWR, is
associated with plaque neovascularization assessed
by CEUS.
2 METHODS
2.1 Study Population
Consecutive patients undergoing coronary
angiography for stable angina or acute coronary
syndrome were prospective enrolled in the study.
Patients with significant coronary artery disease
(stenosis50% in at least one major epicardial
artery) were evaluated with standard carotid
ultrasound. Only patients with carotid plaques in at
least one carotid artery (defined as intima-medial
thickening of at least 1.2mm) were finally included
in the study. Exclusion criteria included previous
cerebrovascular event, vasculitis, intermittent
inflammatory or neoplastic conditions.
2.2 Standard Carotid Ultrasound
Extracranial (common, internal, external) carotid
arteries were examined with a high resolution B-
Benetos G., Toutouzas K., Grassos H., Drakopoulou M., Nikolaou C., Felekos I., Aggeli C., Tsiamis E., Siores E. and Stefanadis C..
In Vivo Measurement of Plaque Neovascularization and Thermal Heterogeneity in Intermediate Lesions of Human Carotids.
Copyright
c
2014 SCITEPRESS (Science and Technology Publications, Lda.)
mode ultrasound unit (Philips iEE33 ultrasound
machine, Philips, Bothell, Washington), using the
7.5-MHz linear probe L9-3. All carotid plaques were
characterized according to their surface contour
(regular, irregular), echogenicity (homogeneous,
heterogeneous) and texture (fatty, mixed, calcified),
according to predefined criteria.
2.3 Contrast Enhanced Ultrasound
(CEUS)
All CEUS examinations were performed with the
commercially available contrast agent, SonoVue
(Bracco Imaging, Milan). The contrast agent was
infused intravenously via an infusion pump at a rate
of 0.8 ml/min. Contrast enhancement (CE) was
quantified using dedicated software. CE was defined
as the percentage of signal intensity difference, prior
and post contrast infusion.
2.4 Microwave Radiometry
Measurements (MWR)
The MWR measurements were performed with the
RTM 01 RES microwave computer based system
(Bolton, UK) that measures temperature from
internal tissues at microwave frequencies. Briefly,
MWR is based on the measurement of the
electromagnetic thermal noise that is emitted by
lossy materials in the microwave frequency range.
All media with absolute temperature T>0
o
K emit
electromagnetic radiation towards their
surroundings. Microwave radiation is capable of
penetrating human tissue and therefore the emission
provides information related to subcutaneous
conditions within the body. The depth of penetration
of microwave radiation depends on the wavelength,
the dielectric properties, and the water content of the
tissue. The signal which is recorded by the sensor is
given by the equation P=k T ΔF, where K is
Bolzmann coefficient, T absolute temperature and
ΔF the receivers bandwidth.
The sensor of the antenna of the device measures
with an accuracy of 0.20°C the ‘volume under
investigation’ as a rectangular area of 3 cm in width,
2 cm in length, and 3–7 cm in depth depending on
the water content of the body. Temperature
measurements were performed along each carotid
artery over segments 2cm of length. Thermal
heterogeneity (ΔT) was assigned as maximal
temperature along the carotid artery minus
minimum.
3 RESULTS
Eighty-six carotid arteries of 48 patients were
included in the analysis. Fatty plaques (n=9) had
higher CE% compared to mixed (n=55) and calcified
plaques (n=22) (21.4±2.70 versus 17.11±5.23 versus
8.55±2.42%, p<0.01). Heterogeneous plaques (n=9)
had higher CE% compared to homogenous (n=77)
(21.44±2.7 versus 14.66±6.02% p<0.01). Plaques
with irregular surface (n=32) had higher CE%
compared to plaques with regular surfaces (n=54)
(18.29±5.09 versus 13.64±6.06%, p<0.01). Fatty
plaques (n=9) had higher ΔΤ compared to mixed
(n=55) and calcified plaques (n=22) (1.13±0.27
versus 0.96±0.34 versus 0.53±0.26°C p<0.01).
Plaques with irregular surface (n=32) had higher ΔΤ
compared to plaques with regular surfaces (n=54)
(1.05±0.32 versus 0.75±0.36°C, p<0.01).
Heterogeneous plaques (n=9) had higher ΔΤ
compared to homogenous (n=77) (1.13±0.27 versus
0.83±0.37°C p<0.01). There was a positive
correlation between mean ΔΤ and CE (R=0.60,
p<0.001).
4 CONCLUSIONS
In the present study a significant correlation between
two vulnerable plaque characteristics, inflammation
and neoangiogenesis, was shown. The prognostic
significance of the evaluation of those characteristics
in clinical practice warrants further studies.