Introduction
Atherosclerosis is a chronic inflammatory disease
(1) involving the cerebral artery,
carotid artery, aorta, coronary artery, renal artery and arteries
of the lower extremities, which is most common in the tunica intima
and media of large and medium-sized arteries. Inflammation can
cause unstable plaques to rupture and induce thrombosis, leading to
subsequent acute ischemic events; an increase in the intima-media
thickness (IMT) of an artery is a marker of systemic and coronary
atherosclerosis (2). Coronary artery
disease (CAD) also known as atherosclerotic heart disease, is
characterized by abnormal lipid metabolism, the deposition of
lipids in the arterial intima and plaque formation, which results
in arterial stenosis, blood flow obstruction and cardiac ischemia
(3).
Numerous researchers have discovered that
atherosclerotic plaque involves not only lipid deposition, but also
occult chronic inflammation in systemic arteries, as described in a
previous review (4). Inflammatory
cytokines are produced and released during coronary stenosis,
which, in turn, may further promote coronary stenosis. C-reactive
protein (CRP), an acute-phase protein that arises rapidly and
reaches high levels in plasma in response to infection or tissue
injury, plays an important role in the occurrence and progress of
inflammation; hence, it has attracted considerable attention. CRP
activates the complement system and enhances phagocytosis to remove
pathogens and damaged, necrotic or apoptotic cells (5,6). Studies
have also demonstrated that CRP is an independent predictor of
carotid IMT (7,8). High-sensitivity CRP (hs-CRP) is a
nonspecific acute-phase protein that has been recognized to be an
independent predictor of cardiovascular events (9,10), and
is thus of particular interest
CAD is a common disease that is a major threat to
middle-aged and elderly individuals worldwide. Atherosclerotic
changes in superficial carotid arteries and their severity
generally reflect systemic atherosclerosis; they are easily
detected with high-frequency ultrasound in the early stage of the
disease. An artery with an elevated IMT is a marker of systemic and
coronary atherosclerosis (2). As a
significant factor in the inflammatory process, hs-CRP is a very
sensitive indicator of the development of atherosclerosis, which is
useful in the diagnosis of CAD and for risk stratification
(11). In the present study, hs-CRP
levels and carotid plaque characteristics were detected and their
correlation with the severity of CAD was explored.
Materials and methods
Subjects
A total of 140 elderly patients (≥60 years) in
accordance with WHO diagnostic standards for angina, myocardial
infarction or chest pain (12) were
selected according to clinical manifestations and coronary
angiography from Beijing Chaoyang Hospital (Beijing, China) between
January 2010 and December 2012. The subjects, comprising 89 males
and 51 females aged 60–85 years with a mean age of 70.43±5.95
years, were divided into a single-vessel disease group (n=11),
double-vessel disease group (n=18), multi-vessel disease group
(n=71) and control group (n=40). The patients in the control group
were 23 males and 17 females that were without stenosis or did not
meet the full diagnostic criteria for stenosis. All the subjects
were of Han origin without any blood relationship. There were no
statistical differences in age, gender, blood glucose levels, lipid
levels and smoking history among the groups. Exclusion criteria:
Patients complicated by organic heart diseases, such as myocarditis
and myocardiopathy, liver and kidney dysfunction, hematologic
diseases, connective tissue disease, tumor and infectious diseases.
The subjects had no history of thromboembolic disease and had not
used anticoagulants recently. This study was conducted in
accordance with the Declaration of Helsinki and with approval from
the Ethics Committee of Capital Medical University. Written
informed consent was obtained from all participants.
Coronary angiography
Selective coronary angiography was performed using
the standard Judkins technique (13)
in multiple positions. The diagnostic criterion was stenosis ≥50%
in ≥1 coronary vessel.
Detection of hs-CRP level
Fasting venous blood was sampled from all the
patients on the first morning following admission and the serum was
isolated for further analysis. The hs-CRP level was detected by
hs-CRP microparticle-enhanced nephelometric immunoassay using a kit
purchased from Orion Diagnostica (Espoo, Finland). The expected
value for healthy individuals is <3 mg/l.
Carotid ultrasound
Color Doppler ultrasound was performed with a probe
frequency of 7.5 MHz, using an Aplio 500 ultrasound device (Toshiba
Corporation, Tokyo, Japan). The patient was examined in the supine
position with his/her head turned contralaterally by 45°. A long
axial section of the carotid artery was probed to show the common
carotid artery (CCA) bifurcation and the internal carotid artery.
The origin, main part and bifurcation of the CCA were examined on
both sides to investigate the blood vessel morphology and
endarterium, and to observe any atherosclerosis plaques. IMT is
defined as the perpendicular distance between the main surface of
the intima and the interface of the tunica media and adventitia.
IMT at the carotid bifurcation and 1.5 cm proximal to the
bifurcation was measured and the maximum value was recorded. An IMT
>1.0 mm was considered as thickening and IMT ≥1.2 mm was labeled
as atherosclerotic plaque. Whether the carotid intima was smooth,
and the location, amount and properties of the atherosclerotic
plaques were observed.
Carotid plaque scoring
The patients were semi-quantitatively scored on a
scale of 0–4 as follows: Score 0, no plaque; score 1, only 1 plaque
with a thickness <2 mm; score 2, 2 plaques with a thickness
<2 mm or only 1 plaque with a thickness >2 mm; score 3, 2
plaques at least one of which had a thickness <2 mm; score 4, 2
plaques with thickness >2 mm or >50% carotid stenosis
(14).
Statistical analysis
Data was analyzed with SPSS software version 19.0
(SPSS, Inc., Chicago, IL, USA). Measurement data are presented as
the mean ± standard error of the mean. Comparison of IMT and plaque
scores between groups was conducted by analysis of variance and
Student's t-test. The correlation of vascular disease with
IMT and plaque score employed single factor analysis. P<0.05 was
considered to indicate a statistically significant difference.
Results
Correlation between serum hs-CRP level
and CAD
The serum level of hs-CRP in the double-vessel
disease group was higher than that of the single-vessel disease
group (P<0.05), and the highest hs-CRP level was observed in the
multi-vessel disease group (P<0.01). The serum level of hs-CRP
was found to increase as the number of vessels involved in CAD
increased (Table I).
 | Table I.Correlation between serum hs-CRP level
and CAD. |
Table I.
Correlation between serum hs-CRP level
and CAD.
| Group | Cases | Hs-CRP (mg/l) |
|---|
| Control | 40 |
1.64±0.98 |
| Single-vessel
disease | 11 |
2.57±1.18 |
| Double-vessel
disease | 18 |
5.22±3.48a |
| Multi-vessel
disease | 71 |
7.46±3.63b |
Comparison of CCA-IMT, carotid
bifurcation IMT and plaque score
The double-vessel disease group exhibited a higher
carotid bifurcation IMT and plaque score than the single-vessel
disease and control groups. These variables, together with the
CCA-IMT were highest in the multi-vessel disease group (Table II).
| Table II.Comparison of CCA-IMT, carotid
bifurcation IMT and plaque score among groups. |
Table II.
Comparison of CCA-IMT, carotid
bifurcation IMT and plaque score among groups.
| Group | Cases | CCA-IMT | Carotid bifurcation
IMT | Plaque score |
|---|
| Control | 40 |
0.83±0.15 |
1.03±0.22 |
2.12±1.91 |
| Single-vessel
disease | 11 |
0.97±0.26 |
1.12±0.14 |
2.98±2.02 |
| Double-vessel
disease | 18 |
1.02±0.17 |
1.23±0.35b |
3.62±2.24b |
| Multi-vessel
disease | 71 |
1.26±0.21a |
1.42±0.40b |
4.28±2.30b |
Comparison of the proportion of cases
with increased CCA-IMT and carotid bifurcation IMT
The proportion of cases with increased carotid
bifurcation IMT was significantly higher in the single-, double-
and multi-vessel disease groups than in the control group
(P<0.05). Compared with the single-vessel disease group, the
multi-vessel disease group showed a distinctly higher proportion of
cases of increased CCA-IMT (P<0.05; Table III). The proportion of cases with
increased CCA-IMT and carotid bifurcation IMT was found to increase
as the number of vessels involved in CAD increased.
| Table III.Proportion of cases with increased
CCA-IMT and carotid bifurcation IMT. |
Table III.
Proportion of cases with increased
CCA-IMT and carotid bifurcation IMT.
| Group | No. of cases | Increased CCA-IMT
(%) | Increased carotid
bifurcation IMT (%) |
|---|
| Control | 40 | 7.5 | 45.0 |
| Single-vessel
disease | 11 | 18.2 | 72.7a |
| Double-vessel
disease | 18 | 22.2 | 83.3a |
| Multi-vessel
disease | 71 | 45.1a,b | 87.3a |
Discussion
The pathogenesis of coronary atherosclerosis is
complex, involving endothelial cell injury, lipid infiltration and
the conversion of macrophages into lipid-laden foam cells, which
closely correlates with inflammation (15). The inflammatory response is of
importance in the occurrence, development and progression of CAD.
Serum levels of inflammatory markers can reflect disease severity
and may be used to predict acute coronary events (16).
In the present study, it was found that the serum
hs-CRP level was associated with CAD severity, as higher serum
levels of hs-CRP were observed in patients with double- and
multi-vessel disease. Previous research (17) has shown that hs-CRP promotes plaque
formation and that the CRP level in peripheral blood parallels the
inflammation severity in plaques. Chambless et al (18) have demonstrated that the incidence of
carotid atherosclerosis and plaques increases with increasing CRP
level, which positively correlates with plaque score and carotid
IMT. CRP may serve as a pathogenic factor in the occurrence and
development of atherosclerosis (19). The serum level of hs-CRP increases as
the severity and extent of CAD increases, indicating that hs-CRP is
associated with CAD occurrence and progress, and thus can serve as
a predictor of CAD severity and cardiovascular events.
Atherosclerosis is a systemic disease that mainly
affects large- and medium-sized arteries and simultaneously affects
carotid and coronary arteries. The severity of a carotid plaque can
reflect the severity of CAD to a certain extent. A large number of
studies have shown that carotid IMT is an independent risk factor
for coronary stenosis, carotid atherosclerosis occurs in parallel
with coronary atherosclerosis and CAD severity significantly
increases with elevated IMT (2,3,17,18).
In the present study, higher CCA-IMT and a greater
number of cases of carotid bifurcation IMT were observed in
patients with CAD than in controls, particularly in the
multi-vessel disease group, which is consistent with previous
findings (20). This suggests that
early carotid ultrasound examination in patients with risk factors
may be used to facilitate the diagnosis of CAD severity. In the
process of atherosclerosis, the endarterium is involved initially
and elevated IMT is a marker of early atherosclerosis (21). The higher the IMT in patients with
CAD the higher the incidence of adverse cardiac events. ELSA
research has demonstrated that IMT measurements in asymptomatic
middle-aged or elderly patients can provide extra information to
facilitate the risk stratification of CAD in addition to
conventional risk factors (22).
Carotid IMT has been recognized as an alternative
marker of atherosclerosis for the evaluation of the severity of
systemic atherosclerosis and directly correlates with the risk of
vascular disease. Elevated carotid IMT may be part of arterial
remodeling in early atherosclerosis, while carotid plaques may
represent late atherosclerosis induced by inflammation, oxidation,
endothelial dysfunction and smooth muscle cell proliferation; thus,
plaques are superior to IMT in reflecting the impact of human
internal factors (22). The present
study demonstrated that CCA and carotid bifurcation IMT closely
correlate with CAD severity. Therefore, carotid IMT and plaque
score can be used for the clinical diagnosis of CAD.
A rapid increase in the number of elderly
individuals has occurred as the population ages. CAD is prevalent
in elderly people; however, some elderly patients refuse to undergo
coronary angiography to determine CAD severity because of age,
social and family factors. Measurements of hs-CRP levels and
carotid ultrasound examinations are practical, valuable, painless,
noninvasive, quantitative, safe, simple, reproducible and easy to
perform, which promotes their application in clinical and
scientific research. If subclinical atherosclerosis, that is,
elevated IMT, is observed, aggressive treatment and the
identification of patients without CAD should be performed to
determine what further drug therapy is required and to reduce
cardiovascular events.
References
|
1
|
Ross R: Atheroscherosis - an inflammatory
disease. N Eng J Med. 340:115–126. 1999. View Article : Google Scholar
|
|
2
|
Kablak-Ziembicka A, Przewlocki T,
Pieniazek P, et al: The role of carotid intima-media thickness
assessment in cardiovascular risk evaluation in patients with
polyvascular atherosclerosis. Atherosclerosis. 209:125–130. 2010.
View Article : Google Scholar : PubMed/NCBI
|
|
3
|
Kabłak-Ziembicka A, Przewłocki T, Stępień
E, et al: Relationship between carotid intima-media thickness,
cytokines, atherosclerosis extent and a two-year cardiovascular
risk in patients with arteriosclerosis. Kardiol Pol. 69:1024–1031.
2011.PubMed/NCBI
|
|
4
|
Rifai N and Ridker PM: High-sensitivity
C-reactive protein: A novel and promising marker of coronary heart
disease. Clin Chem. 47:403–411. 2001.PubMed/NCBI
|
|
5
|
Bokhari SA, Khan AA, Butt AK, et al:
Non-surgical periodontal therapy reduces coronary heart disease
risk markers: A randomized controlled trial. J Clin Periodontol.
39:1065–1074. 2012. View Article : Google Scholar : PubMed/NCBI
|
|
6
|
Cook NR: The case for C-reactive protein
as a risk marker for coronary heart disease. Ann Intern Med.
152:406–407. 2010. View Article : Google Scholar : PubMed/NCBI
|
|
7
|
Toprak A, Kandavar R, Toprak D, et al:
C-reactive protein is an independent predictor for carotid artery
intima-media thickness progression in asymptomatic younger adults
(from the Bogalusa Heart Study). BMC Cardiovasc Disord. 11:782011.
View Article : Google Scholar : PubMed/NCBI
|
|
8
|
Molino-Lova R, Macchi C, Gori AM, et al:
High sensitivity C-reactive protein predicts the development of new
carotid artery plaques in older persons. Nutr Metab Cardiovasc Dis.
21:776–782. 2011. View Article : Google Scholar : PubMed/NCBI
|
|
9
|
Joshi MS, Tong L, Cook AC, et al:
Increased myocardial prevalence of C-reactive protein in human
coronary heart disease: Direct effects on microvessel density and
endothelial cell survival. Cardiovasc Pathol. 21:428–435. 2012.
View Article : Google Scholar : PubMed/NCBI
|
|
10
|
Ko YG, Le VC, Kim BH, et al: Correlations
between coronary plaque tissue composition assessed by virtual
histology and blood levels of biomarkers for coronary artery
disease. Yonsei Med J. 53:508–516. 2012. View Article : Google Scholar : PubMed/NCBI
|
|
11
|
Schlager O, Exner M, Mlekusch W, et al:
C-reactive protein predicts future cardiovascular events in
patients with carotid stenosis. Stroke. 38:1263–1268. 2007.
View Article : Google Scholar : PubMed/NCBI
|
|
12
|
Hannan EL, Samadashvili Z, Cozzens K, et
al: Assessment of the new appropriate use criteria for diagnostic
catheterization in the detection of coronary artery disease
following noninvasive stress testing. Int J Cardiol. 170:371–375.
2014. View Article : Google Scholar : PubMed/NCBI
|
|
13
|
Guillard N, Lefèvre T, Spaulding C, et al:
Coronary angiography by left radial approach: A bi-center
prospective pilot study. Arch Mal Coeur Vaiss. 90:1349–1355.
1997.(In French). PubMed/NCBI
|
|
14
|
Zureik M, Bureau JM, Temmar M, et al:
Echogenic carotid plaques are associated with aortic arterial
stiffness in subjects with subclinical carotid atherosclerosis.
Hypertension. 41:519–527. 2003. View Article : Google Scholar : PubMed/NCBI
|
|
15
|
Libby P, Ridker PM and Maseri A:
Inflammation and atherosclerosis. Circulation. 105:1135–1143. 2002.
View Article : Google Scholar : PubMed/NCBI
|
|
16
|
Blake GJ and Ridker PM: C-reactive protein
and other inflammatory risk markers in acute coronary syndromes. J
Am Coll Cardiol. 41:(4 Suppl). 37S–42S. 2003. View Article : Google Scholar : PubMed/NCBI
|
|
17
|
Johnston SC, Zhang H, Messina LM, Lawton
MT and Dean D: Chlamydia pneumoniae burden in carotid arteries is
associated with upregulation of plaque interleukin-6 and elevated
C-reactive protein in serum. Arterioscler Thromb Vasc Biol.
25:2648–2653. 2005. View Article : Google Scholar : PubMed/NCBI
|
|
18
|
Chambless LE, Folson AR, Cheqq LX, et al:
Carotid wall thickness is predictive of incident clinical stroke:
The Atherosclerosis Risk in Communities (ARIC) study. Am J
Epidemiol. 151:478–487. 2000. View Article : Google Scholar : PubMed/NCBI
|
|
19
|
Heuten H, Goovaerts I, Ennekens G and
Vrints C: Carotid artey intima-media thickness is associated with
coronary artery disease. Acta Cardiol. 63:309–313. 2008. View Article : Google Scholar : PubMed/NCBI
|
|
20
|
Seo WK, Yong HS, Koh SB, et al:
Correlation of coronary artery atherosclerosis with atherosclerosis
of the intracranial cerebral artery and the extracranial carotid
artery. Eur Neurol. 59:292–298. 2008. View Article : Google Scholar : PubMed/NCBI
|
|
21
|
Nguyen-Thanh HT and Benzaquen BS:
Screening for subclinical coronary artery disease measuring carotid
intima media thickness. Am J Cardiol. 104:1383–1388. 2009.
View Article : Google Scholar : PubMed/NCBI
|
|
22
|
Zanchetti A, Hennig M, Hollweck R, et al:
Baseline values but not treatment-induced changes in carotid
intima-media thickness predict incident cardiovascular events in
treated hypertensive patients: Findings in the European Lacidipine
Study on Atherosclerosis (ELSA). Circulation. 120:1084–1090. 2009.
View Article : Google Scholar : PubMed/NCBI
|
