Int J Pharm Pharm Sci, Vol 11, Issue 9, 73-79Original Article

BLOOD VISCOSITY AS A DETERMINING FACTOR OF ISCHEMIC STROKE OUTCOMES EVALUATED WITH NIHSS AND MRS ON DAY 7 AND 30 POST-THROMBOLYSIS

AL RASYID^1*, SALIM HARRIS¹, MOHAMMAD KURNIAWAN¹, TAUFIK MESIANO¹, RAKHMAD HIDAYAT¹, GOGOR MEISADONA¹

¹Department of Neurology, Faculty of Medicine, University of Indonesia/Cipto Mangunkusumo Hospital, Jakarta 10430, Indonesia
Email: alrasyid50@yahoo.com

Received: 08 Jul 2019, Revised and Accepted: 10 Aug 2019

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ABSTRACT

Objective: This study aimed to analyze blood viscosity as a determining factor of ischemic stroke outcomes evaluated with National Institutes of Health Stroke Scale (NIHSS) and modified Rankin Scale (mRS) on day 7 and 30 post-thrombolysis.

Methods: This study was a 4-months cohort study taking place in Cipto Mangunkusumo General Hospital from January to April 2017. Subjects were collected at the Emergency Department or Neurology Outpatient Department. Eligible patients gave informed consent. Patients underwent numerous examinations, including blood viscosity test using digital microcapillary (DM) instrument. Outcomes of patients were identified on day 7 and day 30 post-thrombolysis using NIHSS and mRS, respectively.

Results: Most acute ischemic stroke patients (88.6%) had blood hyperviscosity. 9.1% patients had poorer neurologic deficit on day 7 evaluated with NIHSS and 18.2% patients had poor outcome on day 30 evaluated with mRS. All patients with normal blood viscosity did not have a poorer neurologic deficit on day-7-evaluation.

Conclusion: Blood viscosity determines the outcomes of acute ischemic stroke patients on day 7 and day 30 post-thrombolysis.

Keywords: Blood viscosity, Thrombolysis, Ischemic stroke, Indonesia

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© 2019 The Authors. Published by Innovare Academic Sciences Pvt Ltd. This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/)
DOI: http://dx.doi.org/10.22159/ijpps.2019v11i9.34820

INTRODUCTION

Stroke is the second leading cause of death and the third leading cause of disability [1-5]. Stroke hold accountable for 5 million deaths and 5 million permanent disabilities in the world [6]. Ischemic stroke has the highest prevalence of all types of stroke (87%) [7]. Stroke causes the highest mortality from the non-communicable disease group in Indonesia with ischemia as the main etiology [8]. In Indonesia, stroke prevalence is 10.9/1000 population (2018) [9].

Blood viscosity is the blood flow resistance due to friction caused by the difference in the speed of blood flow movement through the lamina [10]. Blood viscosity is one of the components determining the flow of the blood. Many studies have shown a correlation between the blood flow and hemostasis as well as thrombosis. Blood viscosity is associated with the prothrombic condition [11, 12]. The blood viscosity value varies between individuals and may play an important role in ischemic stroke and transient ischemic disease (TIA) as its value is increased in some of those patients, 48% and 34%, respectively [13]. Blood viscosity –as part of the blood flow, is associated with the pathophysiology of cerebral ischemia. Blood hyperviscosity is found in most patients with acute ischemic stroke [14]. Szapary et al. study found there was an increase of blood viscosity in ischemic stroke patients and Meliala et al. study stated that blood hyperviscosity contributed as one of the stroke risk factors [15, 16]. Rasyid et al. and Ott et al. study found that more than 40% of acute ischemic stroke patients had increased blood viscosity [17, 18]. Blood viscosity also tends to be higher in certain populations such as elderly, smokers, hypertensive people, diabetic people, patients with ischemic heart disease, and dyslipidemic patients [11, 12, 19, 20]. Blood hyperviscosity contributes to the severity of the ischemic stroke outcomes [14, 18]. Blood hyperviscosity in the penumbra can decrease cerebral blood flow and lead to more severe ischemia [21]. Blood viscosity can be measured by the long-waiting laboratory examination or instantly by digital microcapillary (DM) instrument created by Al Rasyid in 2014 [22].

Outcome of stroke patient can be evaluated using the National Institutes of Health Stroke Scale (NIHSS) and modified Rankin Scale (mRS). NIHSS evaluates the patient’s impairment. NIHSS can measure severity of symptoms related with brain infarction and evaluate post-stroke neurologic deficit. Higher NIHSS score represents more severe impairment [23]. mRS evaluates the patient’s disability. mRS measures patient’s independency post-stroke [24]. This study aimed to investigate the effect of blood viscosity in determining the outcomes of acute ischemic stroke using NIHSS and mRS evaluation.

MATERIALS AND METHODS

Subjects and procedures

This cohort study used consecutive sampling method of acute ischemic stroke patients admitted to the Emergency Department or Neurology Outpatient Department in Cipto Mangunkusumo General Hospital between January 2017 and April 2017. Inclusion criteria for this study were an adult (aged 19-80 y old) ischemic stroke patients with stroke symptom onset within 72 h. Patients with posterior circulation infarct (POCI) or total anterior circulation infarct (TACI) were excluded from this study. Patients included in this study were those who had the stroke for the first time. Patients with previous stroke history or/and had received intravenous/intra-arterial thrombolysis before were excluded. Patients who had chronic kidney disease, sepsis, malignancy, congestive heart failure, liver failure, or severe dehydration were also excluded; hence these factors could potentially influence the outcome of the therapy. Patients who consumed corticosteroid and diuretic were also excluded from this study.

History taking, physical examination, and National Institute of Health Stroke Scale (NIHSS) score were taken on the first day patient came to the hospital. NIHSS score ranges between 0-42. Laboratory examination including blood urea, creatinine, sodium, potassium, and glucose level were performed on the patients. Blood viscosity of the patient was also investigated using digital microcapillary (DM) instrument. Brain imaging using commuted topography (CT) scan without contrast was also performed on the patients to establish the ischemic stroke diagnosis.

NIHSS score of patients was taken again on day 7 hospitalized. Patients who had returned home before day-7-hospitalization were advised to make an outpatient visit to Neurology Outpatient Department on day 7 post first-day-visit. NIHSS day-7 score for those patients was collected at that visit. All patients were told to make an outpatient visit on day 30 post first-day-visit to collect modified Rankin Scale (mRS) score. mRS score can range from 0 (no symptoms) to 6 (dead). NIHSS day-7 and mRS day-30 score were the outcomes evaluated in this study.

Patients with NIHSS score increased ≥1 on day-7-evaluation were categorized as having a poorer neurologic deficit. Patients who had mRS day-30 score 0-2 were categorized as having good outcome while those who had score >2 were categorized as having poor outcome.

This study also evaluated the possibility of other risk factors in affecting the outcomes of ischemic stroke. Risk factors investigated consisted of age, sex, hypertension, hyperglycemia, atrial fibrillation, dehydration state, and type of stroke (partial anterior circulation infarct [PACI] or lacunar infarct [LACI]).

This study had been approved by Committee Ethics of Faculty of Medicine University of Indonesia/Cipto Mangunkusumo General Hospital with approval number 281/UN2/F1/ETIK/2017. All patients gave informed consent. Identity and data of all patients were held confidential.

Statistical analysis

Data were analyzed statistically using SPSS version 20. Most data were presented as categorical data. Chi-square test or Fisher’s exact test was performed to identify the significance of blood viscosity as a determining factor of ischemic stroke outcomes. The possibility of other risk factors in influencing outcomes of stroke was analyzed using logistic regression.

RESULTS

There were 44 ischemic stroke patients submitted to Emergency Department or Neurology Outpatient Department in Cipto Mangunkusumo General Hospital between January 2017 and April 2017 who met the eligibility criteria and were willing to participate in this study. Subjects of this study: 56.8% were male; 27.3% aged >65 y old; 77.3% were hypertensive; 40.9% were hyperglycemic; 6.8% had atrial fibrillation; and 47.7% had dehydration. Most patients (90.9%) had a lacunar infarct (LACI) type of stroke. No patient had fever and 88.6% patients admitted to the hospital on the first day of stroke symptoms onset. Fig. 1 showed that 88.6% of the patients had blood hyperviscosity.

Fig. 1: Pie chart showing the percentage of blood hyperviscosity and nonhyperviscosity in the patients

There were 39 patients with blood hyperviscosity while there were only 5 patients with normal blood viscosity. There was no significant proportional difference among other variables such as age, sex, hydration state, blood pressure level, blood glucose level, atrial fibrillation, stroke subtype, and stroke onset towards blood viscosity as described in table 1.

Table 1: Baseline demographic and clinical characteristics of hyperviscosity and nonhyperviscosity group

	Hyperviscosity, n (%)	Non-hyperviscosity n (%)	p score*	Relative risk (RR) (95% CI)
Age, y
≤65	27 (84.4)	5 (15.6)	0.301	1.185 (1.021-1.376)
>65	12 (100.0)	0 (0.0)
Sex
Male	23 (92.0)	2 (8.0)	0.638	1.093 (0.871-1.370)
Female	16 (84.2)	3 (15.8)
Fever
Yes	0 (0.0)	0 (0.0)	-	-
No	39 (88.6)	5 (11.4)
Dehydration
Yes	20 (95.2)	1 (4.8)	0.348	1.153 (0.934-1.423)
No	19 (82.6)	4 (17.4)
Hypertension
Yes	30 (88.2)	4 (11.8)	1.000	0.980 (0.771-1.247)
No	9 (90.0)	1 (10.0)
Hyperglycemia
Yes	14 (77.8)	4 (22.2)	0.142	0.809 (0.625-1.048)
No	25 (96.2)	1 (3.8)
Atrial fibrillation
Yes	3 (100.0)	0 (0.0)	1.000	1.139 (1.016-1.277)
No	36 (87.8)	5 (12.2)
Stroke subtype
PACI	3 (75.0)	1 (25.0)	0.394	0.833 (0.469-1.481)
LACI	36 (90.0)	4 (10.0)
Stroke onset
Day 1	34 (87.2)	5 (12.8)	1.000	0.872 (0.773-0.983)
Day 2-3	5 (100.0)	0 (0.0)

*Fisher’s exact test. PACI: partial anterior circulation infarct, LACI: lacunar circulation infarct

Outcomes of patients

On day-7-evaluation, only 4 patients had a poorer neurologic deficit than the first-day-evaluation –having increased National Institute of Health Stroke Scale (NIHSS) score ≥1. NIHSS score on 90.9% patients did not increase. Most patients (81.8%) in this study also had good outcome on day-30-evaluation with modified Rankin Scale (mRS) score 0-2 as described in fig. 2.

Fig. 2: Column chart showing outcomes of the patients on day-7 and day-30 evaluation

Factors affecting outcomes of patients

Based on the bivariate analysis performed, partial anterior circulation infarct (PACI) gave a significant contribution to the poorer neurologic deficit (RR=10.000; 95% CI: 1.885-53.061; p=0.036, table 2). Proportion of poorer neurologic deficit in PACI subtype was higher than in lacunar infarct (LACI), 50.0% and 5.0%, respectively. Normal hydration state contributed to non-poorer neurologic deficit (RR=0.810; 95% CI: 0.658-0.996; p=0.044, table 2). There were no patients with normal hydration state experienced poorer neurologic deficit on day-7-evaluation.

Table 2: Factors affecting NIHSS score on day-7-evaluation

	Poorer neurologic deficit n (%)	Non-poorer neurologic deficit n (%)	p score*	Relative risk (RR) (95% CI)
Age, y
≤65	1 (3.1)	31 (96.9)	0.056	8.000 (0.919-69.629)
>65	3 (25.0)	9 (75.0)
Sex
Male	2 (8.0)	23 (92.0)	1.000	0.760 (0.117-4.916)
Female	2 (10.5)	17 (89.5)
Fever
Yes	0 (0.0)	0 (0.0)	-	-
No	4 (9.1)	40 (90.9)
Dehydration
Yes	4 (19.0)	17 (81.0)	0.044	0.810 (0.658-0.996)
No	0 (0.0)	23 (100.0)
Hypertension
Yes	3 (8.8)	31 (91.2)	1.000	0.882 (0.103-7.579)
No	1 (10.0)	9 (90.0)
Hyperglycemia
Yes	2 (11.1)	16 (88.9)	1.000	1.444 (0.224-9.330)
No	2 (7.7)	24 (92.3)
Atrial fibrillation
Yes	1 (33.3)	2 (66.7)	0.254	4.556 (0.657-31.572)
No	3 (7.3)	38 (92.7)
Stroke subtype
PACI	2 (50.0)	2 (50.0)	0.036	10.000 (1.885-53.061)
LACI	2 (5.0)	38 (95.0)
Stroke onset
Day 1	3 (7.7)	36 (92.3)	0.394	1.154 (0.738-1.805)
Day 2-3	1 (20.0)	4 (80.0)

*Fisher’s exact test. PACI: partial anterior circulation infarct, LACI: lacunar circulation infarct

Multivariate analysis was performed to identify adjusted relative risk (adjusted RR) of variables fulfilling chi-square test’s conditions with p score <0.250 (i.e. age and stroke subtype). Logistic regression analysis was used. Result of the analysis showed that patients with PACI had a likelihood of 18.089 times to have a poorer neurologic deficit on day-7-evaluation than patients with LACI (adjusted RR=18.089; 95% CI: 1.121-291.970; p=0.041, table 3). Half of the patients (50.0%) with PACI had poorer neurologic deficit while only 5.0% patients with LACI had poorer neurologic deficit. Elderly patients (aged >65 y old) had a likelihood of 9.908 times to have poorer neurologic deficit than those that younger.

Table 3: Determining factors of poorer neurologic deficit

	Poorer neurologic deficit n (%)	Non-poorer neurologic deficit n (%)	p score	Adjusted RR* (95% CI)
Stroke subtype
PACI	2 (50.0)	2 (50.0)	0.041	18.089 (1.121-291.970)
LACI	2 (5.0)	38 (95.0)
Age, y
>65	3 (25.0)	9 (75.0)	0.090	9.908 (0.698-291.702)
≤65	1 (3.1)	31 (96.9)

*Logistic regression analysis. PACI: partial anterior circulation infarct, LACI: lacunar circulation infarct

PACI also significantly contributed to poor outcome on day-30-evaluation (RR=10.000; 95% CI: 3.947-25.337; p=0.001, table 4). All patients with PACI had poor outcome while only 10.0% of patients with LACI had poor outcome.

Table 4: Factors affecting mRS score on day-30-evaluation

	Poor outcome, n (%)	Good outcome, n (%)	p score*	Relative risk (RR) (95% CI)
Age, y
≤65	5 (15.6)	27 (84.4)	0.663	1.600 (0.450-5.688)
>65	3 (25.0)	9 (75.0)
Sex
Male	4 (16.0)	21 (84.0)	0.710	0.760 (0.218-2.655)
Female	4 (21.1)	15 (78.9)
Fever
Yes	0 (0.0)	0 (0.0)	-	-
No	8 (18.2)	36 (81.8)
Dehydration
Yes	4 (19.0)	17 (81.0)	1.000	1.095 (0.313-3.835)
No	4 (17.4)	19 (82.6)
Hypertension
Yes	5 (14.7)	29 (85.3)	0.355	0.490 (0.141-1.704)
No	3 (30.0)	7 (70.0)
Hyperglycemia
Yes	2 (11.1)	16 (88.9)	0.439	0.481 (0.109-2.122)
No	6 (23.1)	20 (76.9)
Atrial fibrillation
Yes	1 (33.3)	2 (66.7)	0.461	1.952 (0.344-11.087)
No	7 (17.1)	34 (82.9)
Stroke subtype
PACI	4 (100.0)	0 (0.0)	0.001	10.000 (3.947-25.337)
LACI	4 (10.0)	36 (90.0)
Stroke onset
Day 1	7 (17.9)	32 (82.1)	1.000	1.026 (0.646-1.628)
Day 2-3	1 (20.0)	4 (80.0)

*Fisher’s exact test. PACI: partial anterior circulation infarct, LACI: lacunar circulation infarct

Table 5: Outcomes of patients with blood hyperviscosity

	Hyperviscosity, n (%)	Non-hyperviscosity, n (%)	p score*	Relative risk (RR) (95% CI)
NIHSS day-7
Poorer neurologic deficit	4 (10.3)	0 (0.0)	1.000	0.897 (0.807-0.998)
Non-poorer neurologic deficit	35 (89.7)	5 (100.0)
mRS day-30
Poor outcome	7 (17.9)	1 (20.0)	1.000	0.897 (0.137-5.864)
Good outcome	32 (82.1)	4 (80.0)

*Fisher’s exact test. NIHSS: National Institute of Health Stroke Scale, mRS: modified Rankin Scale

Impact of blood hyperviscosity on ischemic stroke outcomes

Blood hyperviscosity significantly did not give contribution neither to the poorer neurologic deficit on day-7-evalution nor poor outcome on day-30-evaluation as described in table 5.

DISCUSSION

There were 44 ischemic stroke patients participated in this study. The patients were gathered consecutively on the outpatient visit or emergency department admission. 72.7% of patients aged ≤65 y old while 27.3% aged >65 y old. These findings do not really correspond with RISKESDAS 2018 stated that 45.3% people aged 65-74 y old had stroke and 50.2% people aged ≥75 y old had stroke [9]. These result probably caused by sampling method of this study. This study used consecutive sampling method which gathered subjects met eligibility criteria in the period of January 1^st to April 31^st 2017.

It was found that all patients aged >65 y old had blood hyperviscosity. This finding corresponds with Emril et al. study stated that old age was associated with an increase of blood viscosity. This may be due to the decrease of blood plasma volume in elderly which causes increased hematocrit [25].

Most patients (56.8%) were male. This finding corresponds with Harris et al. and Rasyid et al. study which found the percentage of male ischemic stroke patients were higher than female, 59.1% vs 40.9%, and 63% vs 36%, respectively [26, 27]. Harris et al. and Rasyid et al. study both took place in Cipto Mangunkusumo General Hospital/Rumah Sakit Cipto Mangunkusumo (RSCM), similar with this study. In this study, proportion of blood hyperviscosity in male was higher than in female, 92.0% and 84.2%, respectively. These findings may be caused by higher frequency of stroke risks in male population such as smoking, hypertension, dyslipidemia, coronary artery disease (CAD), and atrial fibrillation [28, 29]. Smoking can increase blood viscosity by causing decrease of erythrocyte deformability and increase of erythrocyte aggregation [30].

Approximately half of the patients (47.7%) had dehydration. This finding corresponds with Fadhly et al. study on ischemic stroke patients treated in RSCM during 2014 stated that 51% of the patients had dehydration [31]. Schrock et al. found that 36% patients with acute ischemic stroke had dehydration [32]. Rowat et al. reported that 29% of acute ischemic stroke patients had dehydration on the first-day hospitalized [33]. Most patients with dehydration in this study had blood hyperviscosity (95.2%). This finding corresponds with studies stated that dehydration could increase blood viscosity [34-36].

Percentage of stroke risk factors i.e. hypertension, hyperglycemia, and atrial fibrillation was 77.3%, 40.9%, and 6.8%, consecutively. This finding is consistent with RISKESDAS 2013 stated that hypertension was the principal risk factor for stroke [8]. Percentages of those with blood hyperviscosity in hypertensive patients, hyperglycemic patients, and patients with atrial fibrillation in this study were high: 88.2%, 77.8%, and 100.0%, consecutively. These findings correspond with Kuriakose et al. study stated that blood hyperviscosity was present in most patients with stroke risk factors such as smoking, diabetes mellitus, dyslipidemia, and heart disease [37]. Rasyid stated that hypertension and diabetes mellitus can lead to blood hyperviscosity [30]. Blood viscosity increases on hypertensive patients [17]. In patients with diabetes mellitus, an increase of blood viscosity is caused by microangiopathy and/or macroangiopathy. A study showed that there was a significant correlation between increase of HbA1C level and fibrinogen level, erythrocyte aggregation, and blood viscosity (p<0.001) [11].

Stroke subtype was based on Bamford’s ischemic stroke classification: total anterior circulation infarct (TACI); partial anterior circulation infarct (PACI); lacunar circulation infarct (LACI); and posterior circulation infarct (POCI) [38]. Ischemic stroke patients with TACI and POCI subtype were excluded in this study leaving only patients with PACI and LACI stroke subtype. Most patients (90.9%) had LACI. This result is consistent with Harris et al. study on 3627 ischemic stroke patients in Indonesia uncovered that 45.07% of those patients had LACI stroke subtype [39]. Both patients with PACI and patients with LACI had high percentage of blood hyperviscosity, 75.0% and 90.0%, respectively. These results can be explained by Rasyid stated that blood hyperviscosity was present in most ischemic stroke cases [12, 22].

Stroke patients selected in this study were those with symptoms onset within 72 h, based on study by Rasyid [22]. Onset of stroke then categorized as: on the first day (day 1); and on the second or the third day (day 2-3). Most patients (88.6%) came to the hospital on the first day of onset. This finding corresponds with Harris et al. study in which 91% patients came to the hospital within 24 h of symptoms onset [40]. All patients who came to the hospital on day 2-3 had blood hyperviscosity in this study. This may be due to small number of patients who came to the hospital on day 2 or 3 of stroke onset (n=5).

Most patients had favorable outcomes evaluated both on day 7 and day 30. On day-7-evaluation, 90.9% patients did not have poorer neurologic deficit. On day-30-evaluation, 81.8% had a good outcome with the modified Rankin Scale (mRS) score 0-2. This study followed an acute ischemic stroke outcome evaluation method by Rasyid and Smith et al. [22, 41]. Also following Rasyid study, mRS score 0-2 were classified as good outcome while score>2 were classified as poor outcome [22].

Fisher’s exact test was performed to compare percentage between variables. Based on test performed, there was a significant proportional difference between PACI and LACI towards towards poorer neurologic deficit on day-7-evaluation. Logistic regression analysis then performed. The analysis result showed that patients with PACI had likelihood of 18.089 times to have poorer neurologic deficit than patients with LACI. PACI also significantly correlated with poor outcome on day-30-evaluation. Patients with PACI had likelihood of 10 times to have poor outcome on day-30-evaluation than patients with LACI. These findings were consistent with Mohr et al. study stated that survival rate on patients with LACI was significantly better than another subtypes of stroke [42]. Sprigg study on 1484 acute ischemic stroke patients found that patients with LACI tend to have faster clinical improvement than patients with other stroke subtypes. Patients who have fast clinical improvement will go through early mobilization thus prevent them from having complications such as pneumonia and thrombosis [43].

Nondehydration significantly contributed to non-poorer neurologic deficit on day-7-evaluation (RR=0.810; 95% CI: 0.658-0.996; p=0.044). All patients with normal hydration state had a non-poorer neurologic deficit. Although, both dehydration and nondehydration patients mostly had good outcome on day-30-evaluation, 81.0% and 82.6%, respectively. This finding is different with Wu et al. study found that good mRS outcome was significantly lower in dehydration group of acute ischemic stroke patients (p=0.012). Multivariate analysis Wu et al. performed then showed that dehydration patients had a smaller likelihood of achieving good mRS outcome (score ≤2) than nondehydration patients (RR=0.46; p=0.004) [44]. Rowat et al. study found that dehydration was significantly related with poor outcomes such as death and physical independency (p=0.0001) [33]. Dehydration can reduce cerebral blood flow (CBF) and cerebral perfusion pressure (CPP) thus worsen ongoing ischemia and eventually lead to worse outcomes [34-36].

Quarter of patients (25.0%) aged >65 y old had poorer neurologic deficit on day-7-evaluation while only 3.1% patients aged ≤65 y old had poorer neurologic deficit. Elderly patients (aged >65 y old) had likelihood of eight times to have poorer neurologic deficit than younger patients (RR= 8.000; 95% CI: 0.919-69.629; p=0.056). Multivariate analysis performed then showed that patients aged >65 y old had tendency to have poorer neurologic deficit on day-7-evaluation 9.908 times than patients aged ≤65 y old. Thrift et al. study stated that crude death rate and crude incidence rate of stroke were both positively correlated with the proportion of aged ≥ 65 y population [45]. This is most likely due to the prognosis of cerebrovascular disease relies on blood viscosity [46, 47]. Blood viscosity is increased in elderly population [30, 48]. Blood hyperviscosity can reduce cerebral blood flow thus causes more severe brain tissue hypoperfusion [46, 47].

Blood viscosity is a major risk factor for ischemic heart disease and stroke [17, 49]. Autonomic activity, blood viscosity, and endothelial dysfunction determine the peripheral resistance. Peripheral resistance affects systemic blood pressure. Blood flow of the brain is determined by CPP that results from reduction of systemic blood pressure and intracranial pressure. Decrease in CBF will result in brain cells death. Hyperviscosity may lead to more brain cells death thus resulting in poorer outcome of ischemic stroke [50]. In this study, it was found that all patients with normal blood viscosity did not have poorer neurologic deficit on day-7-evaluation. Despite blood viscosity had been stated taking a part in determining outcomes of ischemic stroke in previous studies before, there was no significant difference of either day-7-outcome or day-30-outcome on patients with hyperviscosity and patients with nonhyperviscosity in this study. This is probably caused by small number of subjects in this study and there was unbalanced number of the subject between hyperviscosity and nonhyperviscosity group. Another limitation of this study is that outcome of patients on day 90 post-thrombolysis could not be evaluated even though it is the standard measurement of acute ischemic stroke patients’ functional outcome [51].

CONCLUSION

Results of this study suggest that blood viscosity plays a role in determining the outcomes of ischemic stroke. Most acute ischemic stroke patients had blood hyperviscosity. All patients with normal blood viscosity did not have a poorer neurologic deficit on day-7-evaluation. In conclusion, blood viscosity is a determining factor of ischemic stroke outcomes evaluated with NIHSS and mRS on day 7 and day 30 post-thrombolysis.

ACKNOWLEDGMENT

The authors thank all the party involved in this study.

AUTHORS CONTRIBUTIONS

All the authors have contributed equally

CONFLICT OF INTERESTS

The authors declare that there is no conflict of interest

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