Keywords
cerebral aneurysm - clinical vasospasm - delayed cerebral ischemia - subarachnoid
hemorrhage - vasospasm
Introduction
Spontaneous subarachnoid hemorrhage (SAH) is a neurosurgical emergency. Approximately
80% of SAH are due to ruptured cerebral aneurysms (aneurysmal subarachnoid hemorrhage,
aSAH). Significant complications related to aSAH are postprocedure hemorrhage, hydrocephalus,
or cerebral vasospasm (CV), which might increase morbidity and mortality. CV is known
as the narrowing of cerebral blood vessels, resulting in reduced distal blood flow.
The vasospasm can be either symptomatic, known as clinical vasospasm or delayed ischemic
neurologic deficit or delayed cerebral ischemia (DCI), or radiographic vasospasm,
known as angiographic vasospasm. Radiographic vasospasm is detected by digital subtraction
angiography, transcranial Doppler, and computed tomography (CT) angiography. Clinical
vasospasm or DCI is the development of increasing intensity of headaches, focal neurological
signs, or deterioration in the patient's consciousness level with aSAH.[1]
[2] Seventy percent of aSAH patients develop angiographic vasospasm, while only 30%
develop evident clinical vasospasm. Clinical vasospasm leads to poor functional outcomes
and increased mortality.[1]
[2] About half of the patients who experience clinical vasospasm suffer severe permanent
neurological dysfunction or death.[3] In this study, we aim to determine the clinical relevance of risk factors for vasospasm
in aSAH in a cohort representative of the Arabian Gulf region. We identified demographic,
clinical, and radiographic risk factors and determined the strength of association
of these risk factors with vasospasm.
However, there is not much literature about aSAH and symptomatic CV in the Arabian
Gulf region. The population of countries in the Arabian Gulf region is unique in being
more heterogeneous than any other country due to the significant number of expatriates,
compared to other parts of the world. Qatar's general population during the period
of study was about 2.3 million. About 15% of the population is Qatari National, and
the remaining is expatriates, with about 60% from South Asia. Women account for just
25% of the population, due to Qatar's male-dominant construction sector. The analysis
is of interest as it is performed in Qatar's only center to handle cases of SAH. Hence,
the data represents the entirety of SAH cases requiring admission to an intensive
care unit in Qatar with aSAH for 10 years.
Methods
Patient Population: In this single-center study conducted in Hamad General Hospital, the main tertiary
care center in Qatar, a total of 259 subjects admitted to the surgical intensive care
unit were enrolled retrospectively from January 2007 to December 2016. The institutional
medical research committee approved the study. As the data was collected retrospectively,
a waiver of informed consent was approved by the ethical committee at the medical
research center, Hamad Medical Corporation, Qatar, with IRB #16387/1. All patients
with aSAH were identified from the surgical intensive care unit registry, patient's
demography, including arterial blood pressures (BPs) on admission, history of pre-existing
hypertension, World Federation of Neurological Surgeons (WFNS) score, Hunt and Hess
(H&H) score, and modified Fisher grades. The neurological deficit, pupillary size
and reaction, location of cerebral aneurysms, presence of intraventricular, intracerebral,
and intracerebellar hemorrhage, treatment modality (coiling vs. clipping), and the
presence of CV were recorded.
aSAH was diagnosed by the noncontrast CT of the brain. In contrast, cerebral aneurysms
were identified either by CT angiography or by cerebral catheter angiography. Pediatric,
traumatic subarachnoid, cerebral arterial venous malformation, and patients with other
brain vascular pathologies were excluded from this study. Enrolled patients were managed
postintervention with the standard of care, irrespective of aneurysms that were clipped
or coiled endovascularly. Patients requiring external ventricular drain (EVD) and
decompressive craniotomy followed the standards of care protocols. SAH patients with
increasing headaches, altered sensorium, and/or new focal neurological deficits were
investigated for CV by using transcranial Doppler, CT angiogram, CT perfusion, or
conventional catheter cerebral angiography.
Definition of Vasospasm
Symptomatic or clinical vasospasm was defined as the development of increasing intensity
of headaches, new focal neurological signs, or deterioration in consciousness level
after other possible causes of worsening had been excluded. Angiographic vasospasm
was defined as moderate-to-severe arterial narrowing on digital subtraction angiography
or CT angiography attributable to SAH as determined by a neuroradiologist. Vasospasm
on transcranial Doppler was defined as a mean flow velocity in any vessel more than
120 cm/s.[4]
[5]
[6]
Clinical Management: After identification, aneurysms were either clipped or coiled endovascularly. Enrolled
patients were managed postintervention with the standard of care, irrespective of
the intervention type for the aneurysm. Patients requiring EVD and decompressive craniotomy
also followed the standards of care protocols. SAH patients with an increasing headache,
altered sensorium, or new focal neurological deficits were investigated for CV using
transcranial doppler, CT angiogram, or digital subtraction angiography.
Clinical and Radiographic Assessment
Clinical and Radiographic Assessment
We recorded baseline demographic data and patient's comorbidities, including a history
of pre-existing hypertension. Neurological status was evaluated with the H&H, the
WFNS score, and modified Fisher grades. Clinical variables included arterial BP on
admission, neurological deficit, pupillary size and reaction, and clinical vasospasm
presence as defined earlier. Radiologic measurements included the location of cerebral
aneurysms, intraventricular, intracerebral, or intracerebellar hemorrhage, and the
presence of angiographic vasospasm. Treatment modalities, including surgical intervention,
coiling, or clipping, were recorded.
Statistical Analysis
We evaluated predictors of symptomatic vasospasm. Descriptive and inferential statistics
were used. Descriptive results (including graphical displays) for all continuous variables
are presented as mean ± standard deviation for normally distributed data, or median
with interquartile range for data not normally distributed. Numbers and percentages
were reported for all qualitative variables. The bivariate analysis was performed
using an independent sample t-test or Mann–Whitney U test to compare all quantitative variables between patients
with and without CV. All qualitative variables between patients with and without CV
were compared using the Pearson chi-squared test or Fisher's exact test as appropriate.
Logistic regression analysis was used to measure the odds ratio (OR) and 95% confidence
interval (CI) for OR to assess each predictor's effect on patients with and without
clinical vasospasm.
Multiple logistic regression was used to identify significant independent factors
associated with patients with and without CV after adjusting for potentially confounding
factors. The Wald test was computed on each predictor to determine which were significant.
The adjusted OR and 95% CI for the adjusted OR were reported. A p-value less than 0.05 (two-tailed) was considered statistically significant.
All statistical analyses were performed using Statistical Package for Social Sciences
Version 22 (SPSS).
Results
Out of the 259 patients admitted with spontaneous aSAH, eighty-seven patients (34%)
had CV. Male patients had a trend toward a higher incidence of CV than females; however,
it was not statistically significant (34.5 vs. 31.4%, p = 0.29). There was no significant difference between the mean age of patients with
and without CV (47.98 ± 102.98 vs. 46.30 ± 11.77 years, p < 0.296). There was a statistically significant difference in the WFNS score and
the occurrence of CV (p < 0.01). Patients with a lower WFNS score and lower H&H score (p < 0.01) had a statistically significant lower incidence of CV. There was no correlation
between the Fisher grading and the occurrence of CV (p < 0.122).
There was no significant difference in the occurrence of CV with pre-existing hypertension
or diastolic pressure. A neurological deficit on admission was associated with the
development of CV (p < 0.01). Intraventricular, intracerebellar, or intracerebral hemorrhage was not associated
with an increased risk of CV ([Table 1]). EVDs were significantly associated with the absence of the CV (p < 0.05). Decompressive craniotomy was not associated with a significantly decreased
incidence of CV (p < 0.055).
Table 1a
Risk factors for clinical cerebral vasospasm
|
Factors
|
Vasoplasm
|
p-Value
|
|
Yes
87 (34%)
|
No
172 (66%)
|
|
Age in years
|
47.98 ± 12.98
|
46.30 ± 11.77
|
0.296
|
|
Gender
|
0.662
|
|
|
Male
|
61 (34.5%)
|
116 (65.5%)
|
|
Female
|
26 (31.7%)
|
56 (68.3%)
|
|
Clinical
|
|
World Federation of Neurosurgeons (WFNS) Score
|
0.005
|
|
1
|
18 (19.1%)
|
76 (80.9%)
|
|
2
|
28 (38.4%)
|
45 (61.6%)
|
|
3
|
4 (30.8%)
|
9 (69.2%)
|
|
4
|
20 (50.0%)
|
20 (50.0%)
|
|
5
|
11 (39.3%)
|
17 (60.7%)
|
|
Fischer grade
|
0.122
|
|
1
|
14 (23.0%)
|
47 (77.0%)
|
|
2
|
22 (31.0%)
|
49 (69.0%)
|
|
3
|
10 (38.5%)
|
16 (61.5%)
|
|
4
|
38 (40.9%)
|
55 (59.1%)
|
|
Hunt and Hess score
|
0.002
|
|
1
|
14 (16.9%)
|
69 (83.1%)
|
|
2
|
33 (36.7%)
|
57 (63.3%)
|
|
3
|
13 (48.1%)
|
14 (51.9%)
|
|
4
|
12 (50.0%)
|
12 (50.0%)
|
|
5
|
10 (38.5%)
|
16 (61.5%)
|
|
History of HTN
|
0.113
|
|
Yes
|
48 (38.4%)
|
77 (61.6%)
|
|
No
|
39 (29.1%)
|
95 (70.9%)
|
|
Neurological deficit
|
0.004
|
|
Yes
|
23 (52.3%)
|
21 (47.7%)
|
|
No
|
64 (29.8%)
|
(151) 70.2%
|
|
Pupillary size
|
0.908
|
|
Equal and reactive
|
(72) 32.9%
|
(147) 67.1%
|
|
Anisocoric
|
9 (34.6%)
|
17 (65.4%)
|
|
Fixed
|
5 (38.5%)
|
8 (61.5%)
|
|
Admission SBP
|
167.1 ± 33.8
|
154.4 ± 34.9
|
0.007
|
|
Admission DBP
|
92.6 ± 15.4
|
88.4 ± 17.3
|
0.063
|
Table 1b
Risk factors for clinical vasospasm
|
Factors
|
Vasospasm
|
p-Value
|
|
Yes (%)
87 (34%)
|
No (%)
172 (66%)
|
|
Intravent haemorrhage
|
0.251
|
|
Yes
|
45 (37.2%)
|
76 (62.8%)
|
|
|
No
|
42 (30.4%)
|
96 (69.6%)
|
|
Intracerebellar haemorrhage
|
0.732
|
|
Yes
|
6 (37.5%)
|
10 (62.5%)
|
|
No
|
81 (33.3%)
|
162 (66.7%)
|
|
Intracereberal haemorrhage
|
0.161
|
|
Yes
|
21 (42.0%)
|
29 (58.0%)
|
|
No
|
66 (31.6%)
|
143 (68.4%)
|
|
Insertion of EVD (external ventricular drain)
|
0.031
|
|
Yes
|
44 (41.1%)
|
63 (58.9%)
|
|
No
|
43 (28.3%)
|
109 (71.7%)
|
|
Decompressive craniectomy
|
0.055
|
|
Yes
|
8 (57.1%)
|
6 (42.9%)
|
|
No
|
79 (32.2%)
|
166 (67.8%)
|
|
Clipping
|
0.161
|
|
Yes
|
21 (42.0%)
|
29 (58.0%)
|
|
No
|
66 (31.6%)
|
143 (68.4%)
|
|
Coiling
|
0.174
|
|
Yes
|
40 (38.5%)
|
64 (61.5%)
|
|
No
|
47 (30.3%)
|
108 (69.7%)
|
Table 1c
Ethnicity and location cerebral aneurysm and vasospasm
|
Ethnicity
|
Vasospasm
|
p-Value
|
|
Yes
|
No
|
|
European
|
2 (20%)
|
8 (80%)
|
0.75
|
|
Subcontinent
|
29 (31.9%)
|
62 (68.1)
|
|
|
Arabs
|
28 (35%)
|
52 (65%)
|
|
Southeast Asian
|
24 (35.8%)
|
43 (64.2)
|
|
Africans
|
4 (44.4%)
|
5 (55.6%)
|
|
Turkey
|
0 (0%)
|
2 (100%)
|
|
Location of aneurysms
|
|
No aneurysm
|
2 (20.0%)
|
8 (80.0%)
|
|
ACOM
|
29 (38.2%)
|
62 (61.8%)
|
|
Vertebral
|
2 (50.0%)
|
2 (50.0%)
|
|
MCA
|
41 (31.8%)
|
30 (68.2%)
|
|
Basilar
|
3 (50.0%)
|
3 (50.0%)
|
|
ACA
|
2 (25.0%)
|
6 (75.0%)
|
|
ICA
|
12 (52.0)
|
13 (48.0%)
|
|
PCA
|
1 (33.0%)
|
2 (66.7%)
|
|
SCA
|
0 (0%)
|
1 (100%)
|
|
PCOM
|
12 (46.2%)
|
14 (53.8%)
|
|
CALLOSM
|
1 (100%)
|
0 (0%)
|
Abbreviations: ACA, anterior cerebral artery; ACOM, anterior communicating artery
aneurysm; CALLOSUM, callosal arteries; DSP, diastolic blood pressure; EVD, external
ventricular drain; HTN, hypertension; ICA, internal carotid artery; MCA, middle cerebral
artery; PCA, posterior cerebral artery; PCOM, posterior communicating artery; SBP,
systolic blood pressure; SCA, superior cerebral artery; WFNS, World Federation of
Neurosurgeons.
There was no association between the development of CV and the aneurysms location
(p-value > 0.075) and treatment modalities. Our patient population was multiethnic.
Clinical vasospasm was frequent in the Asian subcontinent, Arab, and southeast Asian
populations compared to the European and African populations ([Table 1]).
[Table 2] shows the multiple regression analysis of independent parameters associated with
the occurrence of clinical vasospasm. Admission systolic BP was significantly associated
with the development of clinical vasospasm (p < 0.05). The patient's age and neurological deficit were not associated with clinical
vasospasm development (p > 0.296). The endovascular coiling was associated with the development of clinical
vasospasm (p < 0.05) ([Table 2]).
Table 2
Multiple regression models to identify independent risk factors associated with vasospasm
|
Factors
|
Adjusted
odds ratio
|
95% CI for adjusted
odds ratio
|
p-Value
|
|
Admission SBP
|
1.008
|
1.000–1.017
|
0.046
|
|
Hunt & Hess score
|
0.055
|
|
1
|
2.470
|
1.176–5.188
|
0.017
|
|
2
|
3.631
|
1.308–10.079
|
0.013
|
|
3
|
3.216
|
1.096–9.441
|
0.033
|
|
4
|
3.141
|
1.008–9.791
|
0.048
|
|
Motor deficit
|
1.948
|
0.922–4.117
|
0.081
|
|
Coiling
|
1.860
|
1.021–3.389
|
0.042
|
|
Age
|
1.003
|
0.978–1.028
|
0.835
|
Abbreviations: CI, confidence interval; CT, computed tomography; OR, odds ratio; SBP,
systolic blood pressure.
Note: p-Value has been calculated using binary multiple logistic regression Wald test. Growth
rate = (Infarct volume at 2nd CT – Infarct volume at 1st CT) / (Time at 2nd CT – Time at 1st CT).
Discussion
aSAH has an annual impact of 10/100, and 25% of the patients die instantly. Improvement
in surgical and endovascular treatment of the cerebral aneurysms has decreased the
major rebleeding. In 1951, Ecker and Riemenschneider described the syndrome of CV
in patients with aSAH.[7] A significant number of cases develop clinical vasospasm manifested by increasingly
severe headaches, new focal neurological deficits, or cognitive deficits between the
4th to 14th day after aSAH.[8] A literature review revealed the use of the term “vasospasm” without identifying
the clinical or radiologic nature of the diagnosis. Also, there has been no consensus
on a unifying definition of vasospasm. A variety of terms are used in the literature
for clinical vasospasm, including clinical vasospasm or delayed ischemic neurologic
deficit, or DCI. There is a dearth of literature on risk factors for clinical vasospasm
associated with aSAH from the Arabian Gulf region.
Most studies suggest no association between patient age and the development of CV.
Magge et al suggested a higher risk of CV in younger patients.[9] Mijiti et al reported that the age more than 53 years is a risk for CV development.[10] Age was not associated with an increased risk of CV in our patients.
Nasser et al reported a higher incidence of CV in males.[11] In contrast, a lower incidence was reported by Dumont et al.[12] Our cohort had a statistically nonsignificant trend toward increased incidence in
males.
Concerning racial differences, the Japanese and the Han Chinese are at a higher risk
of developing CV, with no difference between Caucasians and African-Americans.[10]
[13]
[14] No significant ethnicity-based risk differences exist in our cohort.
Most of our patients had CV with a rupture of middle cerebral artery aneurysms. The
location of SAH is inconsistently associated with varied risk of CV.[15]
[16]
[17] In our cohort, no such association was noted.
Higher H&H grades and higher WFNS score correlated with the development of CV, which
is in line with available literature.[10]
[14]
[18]
[19]
Previous studies reported a negative relationship between hypertension and CV and
a positive correlation with the admission systolic BP.[10]
[17]
[20] It is interesting to note that hypertension was not associated with the risk for
the development of CV; however, multiple regression analysis established a positive
relationship between CV and systolic BP on admission.
A significant finding in this study is the correlation of neurological deficit on
admission with CV. To the best of our knowledge, this association is not reported.
Arguably, our cohort's most exciting finding was the insertion of an EVD associated
with a significantly lesser CV. The authors propose that earlier clearance of blood
degradation products may play a role. This finding is in line with earlier cohorts
that underwent spinal CSF drainage or EVD insertion.[21]
[22]
The multiple regression analysis demonstrated that coiling procedures had a significantly
higher incidence of CV than surgical clipping of a ruptured aneurysm. A review of
the literature on this association produced inconsistent findings.[23]
[24]
[25]
[26]
Conclusion
Our study population demonstrates region-dependent risk factors associated with CV.
SAH severity, the presence of neurological deficit or systolic hypertension on admission,
and coiling procedures were associated with an increase in CV. EVD insertion decreased
the occurrence of clinical vasospasm. A prospective cohort study is needed to delineate
the risk factors in this multiethnic population further.
