Keywords:
stroke - atherosclerosis - recurrence - risk factors
Palavras-chave:
Acidente vascular cerebral - aterosclerose - recidiva - fatores de risco
Intracranial atherosclerosis is the mechanism of ischemic stroke in 6a10% of the patients
in Western countries and 50% of patients in Eastern countries[1],[2],[3],[4],[5]. Patients with intracranial atherosclerosis exhibit an ischemic stroke recurrence
rate of 14-19% within two years[6],[7]. Until now, most of the current knowledge about intracranial atherosclerosis has
come from the Northern Hemisphere. The aim of the present study was to analyze the
long-term stroke recurrence rates among the Brazilian patient population with a first-ever
ischemic stroke secondary to intracranial large artery atherosclerosis (LAA), compared
to a first-ever ischemic stroke secondary to other mechanisms.
METHODS
This study was a retrospective analysis of prospective hospital data from all patients
with a first-ever ischemic stroke, admitted to the Hospital de Clinicas of the Federal
University of Paraná, between October 2012 and September 2015. The study was approved
by the local ethics committee and the board waived the need for patient consent.
All patients had a brain scan [computed tomography (CT) or magnetic resonance (MR)]
to confirm the presence of a lesion consistent with the clinical syndrome diagnosed
during admission. The stroke mechanism subtypes were defined according to the SSS-TOAST
classification system as cardioembolism (CE), LAA, small vessel occlusion (SVO), other
determined etiologies (OTH), and stroke of undetermined etiology (UND); the mechanism
was determined if there were evident or probable criteria[8]. To determine the stroke mechanism subtype, patients underwent electrocardiography,
extracranial and intracranial Doppler ultrasound, transthoracic echocardiography,
and at least one brain CT scan. In selected cases, transesophageal echocardiography,
24-hour Holter monitoring, CT angiography, MR angiography, or digital angiography
were also performed.
Patients with LAA were further subclassified as patients with extracranial LAA, patients
with intracranial LAA (≥ 50% stenosis in any of the main arteries – carotid siphon,
middle cerebral artery, anterior cerebral artery, posterior cerebral artery, vertebral
artery and basilar artery) or patients with combined (extracranial plus intracranial)
LAA, based on the topography of the symptomatic vessel. For the analyses, patients
with combined LAA (four patients) were included in the patients with extracranial
LAA group. To substantiate the intracranial LAA, patients underwent at least two distinct
noninvasive scans of contrast-enhanced MR angiography or CT angiography or transcranial
Doppler ultrasound. If there was a contradiction in the results of the two scans,
digital angiography was performed during hospital admission, to either confirm or
exclude intracranial disease. All patients with intracranial LAA underwent a second
noninvasive evaluation (MR angiography, CT angiography, or transcranial Doppler ultrasound)
three months after the first set of scans to confirm the persistence of stenosis and
the diagnosis of intracranial LAA. The intracranial stenosis was based on previously-published
criteria[9],[10]. All patients with intracranial LAA were treated medically.
The following risk factors were analyzed: age, sex, hypertension, diabetes mellitus,
atrial fibrillation, hypercholesterolemia, and current smoking. Skin color was classified
based on the Brazilian Institute of Geography and Statistics criteria[11]. The in-hospital analyses included the National Institutes of Health Stroke Scale
(NIHSS) scores, as well as systolic and diastolic blood pressure at admission. Patients
were evaluated at outpatient visits, after discharge, to assess the follow-up modified
Rankin Scale (mRS) score and risk of stroke recurrence. Stroke recurrence was defined
as a focal neurological impairment of sudden onset lasting more than 24 hours and
confirmed by a brain image during the follow-up period[12]. Patients discharged from the hospital were included in the present study if they
were followed up for at least three months.
Analyses were performed using Stata/SE 14.1 software. Quantitative variables were
described by mean and standard deviations, or median with minimum and maximum values.
Categorical variables were presented as frequencies and percentages. For comparison
of the etiological groups by quantitative variables, one-way analysis of variance
(ANOVA) or the Kruskal-Wallis nonparametric test was used. Categorical variables were
analyzed using a chi-square test. Normality of data was determined using the Kolmogorov-Smirnov
test. Factors associated with recurrence were analyzed using univariate and multivariate
Fine and Gray proportional hazards regression models (mortality as a competing risk)
and the Wald test. For the multivariate model, all significant variables comparing
different ischemic stroke mechanisms and those related to recurrence in the univariate
analyses were considered. The subdistribution hazard ratio was estimated as the measure
of association. Proportional hazard assumption was evaluated by cumulative incidence
curves and analysis of the interaction between each variable and time. No evidence
of violation of this condition was detected. Statistical significance was accepted
for p-values < 0.05.
RESULTS
Three hundred ninety-eight first-ever ischemic stroke patients were admitted to the
hospital during the study period; 39 (9.8%) were excluded for lack of follow-up in
the first three months after discharge. Among the 359 patients evaluated, the mean
age was 64.4 ± 13.6 years, 177 patients (49.3%) were women, and 333 patients (92.8%)
had white skin color. The mean follow-up period was 21.6 ± 15.1 months. Brain CT was
performed on all 359 patients; electrocardiography on 346 patients (96.4%); extracranial
and intracranial Doppler ultrasound on 315 patients (87.7%); transthoracic echocardiography
on 318 patients (88.6%); transesophageal echocardiography on 69 patients (19.2%);
24-hour Holter monitoring on 81 patients (22.6%); CT angiography, MR angiography,
or digital angiography on 184 patients (51.3%); and brain MRI on 168 patients (46.8%).
Eighteen patients (5%) were classified as having intracranial LAA, 61 (17%) as having
extracranial LAA, 107 (29.8%) as having CE, 90 (25.1%) as having UND, 68 (18.9%) as
having SVO, and 15 (4.2%) as having OTH stroke mechanism subtypes.
Hypertension was more common in patients with intracranial LAA (94.4%) and SVO (95.6%).
Twelve patients (66.7%) with intracranial LAA and 48 patients (70.6%) with SVO had
hyperlipidemia. Diabetes mellitus was observed more frequently in patients with extracranial
LAA (39.3%) and SVO (38.2%), followed by intracranial LAA (33.3%). The NIHSS score
at admission was lower in intracranial LAA (2; 0–18), SVO (3.5; 0–13), and OTH (5;
0–20) when compared to the NIHSS scores of other ischemic stroke subtypes. [Table 1] shows the demographic and admission data from different groups of patients. Antiplatelet
therapy was introduced at the time of discharge for 15 patients (83.3%) with intracranial
LAA, 54 patients (93.1%) with extracranial LAA, 67 patients (98.5%) with SVO, 25 patients
(26.3%) with CE, 13 patients (86.7%) with OTH, and 55 patients (88.7%) with UND. Anticoagulation
therapy was prescribed for 70 (73.8%) patients with CE, three (16.7%) with intracranial
LAA, three (5.3%) with extracranial LAA, two (13.3%) with OTH, and four (6.6%) with
UND.
Table 1
Demographic data for first-ever ischemic stroke patients, classified by stroke mechanism.
|
Variable
|
ILAA
|
ELAA
|
CE
|
SVO
|
OTH
|
UND
|
p-value
|
|
Population
|
18
|
61
|
107
|
68
|
15
|
90
|
|
|
Age (Mean ± SD)
|
63.3 ± 16.5
|
63.1 ± 12.9
|
64.8 ± 12.6
|
66.6 ± 14.7
|
58.5 ± 14.9
|
64.5 ± 13.3
|
0.371*
|
|
Female sex (N [%])
|
7 (38.9)
|
28 (45.9)
|
57 (53.3)
|
37 (54.4)
|
9 (60)
|
39 (43.3)
|
0.491**
|
|
White skin color (N [%])
|
16 (88.9)
|
58 (95.1)
|
100 (94.3)
|
63 (92.6)
|
14 (93.3)
|
82 (91.1)
|
0.892**
|
|
Hypertension (N [%])
|
17 (94.4)
|
49 (80.3)
|
91 (85.1)
|
65 (95.6)
|
8 (53.3)
|
65 (73)
|
< 0.001**
|
|
Diabetes mellitus (N [%])
|
6 (33.3)
|
24 (39.3)
|
23 (21.5)
|
26 (38.2)
|
1 (6.7)
|
29 (32.2)
|
0.028**
|
|
Hyperlipidemia (N [%])
|
12 (66.7)
|
38 (62.3)
|
59 (55.1)
|
48 (70.6)
|
7 (46.7)
|
47 (52.2)
|
0.169**
|
|
Current smoker (N [%])
|
5 (27.8)
|
24 (39.3)
|
21 (19.6)
|
14 (20.6)
|
4 (26.7)
|
27 (30)
|
0.088**
|
|
Atrial fibrillation (N [%])
|
0 (0)
|
2 (3.3)
|
62 (57.9)
|
0 (0)
|
0 (0)
|
2 (2.2)
|
< 0.001**
|
|
Systolic blood pressure at admission (Mean ± SD)
|
153.4 ± 23.5
|
150.2 ± 25.3
|
150.1 ± 34.3
|
158.5 ± 31.9
|
133.7 ± 19.1
|
151.5 ± 34.1
|
0.149*
|
|
Diastolic blood pressure at admission (Mean ± SD)
|
86.1 ± 12.1
|
88.0 ± 14.3
|
89.8 ± 20.6
|
92.7 ± 17.1
|
77.6 ± 9.8
|
87.7 ± 20.0
|
0.089*
|
|
NIHSS at admission (Med (min-max])
|
2 (0–18)
|
10.5 (0–24)
|
10 (0–26)
|
3.5 (0–13)
|
5 (0–20)
|
11 (0–29)
|
< 0.001***
|
|
Thrombolysis therapy (N [%])
|
3 (16.7)
|
28 (45.9)
|
51 (47.7)
|
16 (23.5)
|
3 (20)
|
36 (40)
|
0.004**
|
|
Modified Rankin score < 3 at last visit (N [%])
|
13 (81.3)
|
23 (53.5)
|
50 (67.6)
|
48 (82.8)
|
9 (64.3)
|
32 (61.5)
|
0.030**
|
ILAA: intracranial large artery atherosclerosis
ELAA: extracranial large artery atherosclerosis
CE: cardioembolism
SVO: small vessels occlusion
UND: undetermined
*ANOVA
**chi-squared test
***Kruskal-Wallis.
During the follow-up period, stroke recurrence was observed in 48 patients (13.4%):
seven patients (38.9%) with intracranial LAA, 15 patients (24.6%) with extracranial
LAA, 12 patients (11.2%) with CE, five patients (7.3%) with SVO, and nine (10%) UND
patients. Patients classified under OTH did not present with stroke recurrence. Patients
with intracranial LAA and extracranial LAA had higher stroke recurrence rates, as
determined by univariate analyses ([Table 2]). When submitted to a multivariate analysis, the only variables correlated with
stroke recurrence were intracranial and extracranial LAA stroke mechanisms ([Table 3]).
Table 2
Univariate analyses for stroke recurrence for first-ever ischemic stroke patients.
|
Variable
|
p-value
|
SHR
|
95%CI
|
|
Age
|
0.805
|
1.003
|
0.98–1.03
|
|
Sex
|
0.237
|
1.40
|
0.80–2.45
|
|
Skin color
|
0.665
|
0.73
|
0.17–3.04
|
|
Hypertension
|
0.135
|
2.04
|
0.80–5.21
|
|
Diabetes mellitus
|
0.679
|
0.88
|
0.48–1.61
|
|
Hyperlipidemia
|
0.747
|
1.10
|
0.62–1.95
|
|
Current smoker
|
0.464
|
0.76
|
0.37–1.57
|
|
Atrial fibrillation
|
0.819
|
0.92
|
0.43–1.94
|
|
Systolic blood pressure at admission
|
0.501
|
1.003
|
0.99–1.01
|
|
Diastolic blood pressure at admission
|
0.213
|
1.01
|
0.99–1.03
|
|
Thrombolysis
|
0.763
|
0.92
|
0.53–1.60
|
|
NIHSS at on admission
|
0.924
|
1.002
|
0.96–1.05
|
|
Stroke mechanism
|
|
ILAA
|
< 0.001
|
9.64
|
3.35–27.7
|
|
ELAA
|
0.002
|
4.82
|
1.79–13.0
|
|
CE
|
0.313
|
1.68
|
0.61–4.61
|
|
SVO (ref)
|
–
|
–
|
–
|
|
Other*
|
|
|
|
|
UND
|
0.358
|
1.64
|
0.57–4.72
|
SHR: subdistribution hazard ratio
ILAA: intracranial large artery atherosclerosis
ELAA: extracranial large artery atherosclerosis
CE: cardioembolism
SVO: small vessels occlusion
UND: undetermined
*Not analyzed.
Table 3
Multivariate model of stroke recurrence for first-ever ischemic stroke patients.
|
Stroke mechanism*
|
p-value
|
SHR
|
95%CI
|
|
ILAA
|
< 0.001
|
10.3
|
3.56–29.6
|
|
ELAA
|
0.001
|
5.38
|
1.95–14.8
|
|
CE
|
0.521
|
1.50
|
0.44–5.15
|
|
SVO (reference)
|
–
|
–
|
–
|
|
UND
|
0.249
|
2.05
|
0.61–6.93
|
SHR: subdistribution hazard ratio
ILAA: intracranial large artery atherosclerosis
ELAA: extracranial large artery atherosclerosis
CE: cardioembolism
SVO: small vessels occlusion
UND: undetermined. Fine and Gray proportional hazards regression models with mortality
as competing risk
*Adjusted for hypertension, diabetes mellitus, atrial fibrillation, thrombolysis and
NIHSS at admission.
Functional independence (mRS score < 3) at the last review was observed in 13 patients
(81.3%) with intracranial LAA, 23 patients (53.5%) with extracranial LAA, 50 patients
(67.6%) with CE, 48 patients (82.8%) with SVO, nine patients (64.3%) with OTH, and
32 patients (61.5%) with UND (p = 0.03).
DISCUSSION
The present study demonstrated that patients with intracranial and extracranial LAA
presented with the highest stroke recurrence rate. Hypertension and hyperlipidemia
were more common in intracranial LAA patients.
Previously-reported stroke recurrence rates for patients with intracranial LAA were
14% over two years and 23% over three years[7],[13]. In our study, the stroke recurrence rate for patients with intracranial LAA was
38.9% over two years of follow-up. The stroke recurrence rates for other ischemic
stroke subtypes in our study were very similar to previously-reported rates in long-term
studies[14],[15]. The most likely reasons for the higher stroke recurrence observed in patients with
intracranial LAA was the increased vulnerability caused by intracranial stenosis[16]. In addition, the patients in our study presented with a higher number of atherosclerotic
risk factors, predominantly hypertension, hyperlipidemia, and diabetes mellitus when
compared with the patients in another large case-control study[17]. A similar set of risk factors was observed in another recent study done in Southern
Brazil[18]. These findings could be explained by the patients having a more complex atherosclerotic
disease, increasing the recurrence risk of ischemic stroke in this population.
In the current study, intracranial LAA patients showed less severe neurological deficits,
as evaluated by the NIHSS at admission, with a good recovery, as demonstrated by the
mRS. Previous studies have demonstrated that patients with low disability levels showed
reduced compliance towards continuation of stroke prevention therapy[19], thereby abrogating the long-term benefits of aggressive medical management, as
reported in the Stenting and Aggressive Medical Management for Preventing Recurrent
Stroke in Intracranial Stenosis trial[20]. Furthermore, the impact of the low disability in patients with intracranial LAA,
as observed in the present study, did not reduce the recurrence, as recently reported
in a subgroup analysis of the Clopidogrel in High-Risk Patients with Acute Nondisabling
Cerebrovascular Events trial, where patients with intracranial artery stenosis and
previous minor ischemic stroke, or moderate-to-high-risk transitory ischemic attack
had a 12.5% chance of recurrence within 90 days, and patients without intracranial
artery stenosis had a 5.4% chance of recurrence within the same period[21].
The most important limitation of the present study was the fact that it was a retrospective
analysis of data collected from a single hospital. However, we carried out extensive
workups in the majority of patients, confirming the stroke mechanism with a high degree
of accuracy. A second challenge was in the accurate identification of ethnicity, as
much of the Brazilian population is multi-ethnic with a predominance of European ancestry
but some proportion of African and Amerindian ancestry as well[22],[23]. The intracranial investigation was done by transcranial Doppler ultrasound in the
majority of patients and this may have underestimated the frequency of this disease
in the population. Beside this, a diagnosis of intracranial LAA was based on the stenosis
without consideration of the vessel wall. Therefore, the initial study selection may
have included patients with diagnoses other than atherosclerosis and excluded patients
with advanced atherosclerosis in the absence of stenosis[24]. To reduce this bias, a confirmatory vascular image was taken three months later
to identify and exclude potential unrelated mechanisms (evanescent stenosis, dissection,
reversible cerebral vasoconstriction syndrome, and vasculitis). Some important markers
for recurrence and outcome in intracranial LAA, as a collateral pattern and stroke
mechanism, were not considered in the current study[25],[26]. Despite these limitations, to the best of our knowledge, this study is the first
to be performed in a low- to middle-income country in the Southern Hemisphere, to
demonstrate the importance of diagnosing intracranial LAA, given the high rate of
recurrent stroke.
In conclusion, the present study suggests that patients who have suffered a stroke
due to intracranial and extracranial LAA present with a high frequency of other risk
factors and are at high risk for stroke recurrence. Mitigation of risk factors could
reduce the prevalence of stroke recurrence in patients with LAA.
