1Department of Research Section, Royal Hospital, Muscat, Oman; 2Department of Emergency, Khoula Hospital, Muscat, Oman; 3Department of Primary 
Health Care, Ministry of Health, Muscat, Oman
*Corresponding Author’s e-mail: ammar.alkashmiri@moh.gov.om

Clinical Profile of Stroke Patients Presenting to the 
Emergency Department of a Major Stroke Centre 

in Oman

Hasina A. Al Harthi,1 *Ammar Al Kashmiri,2 Lubna M. Zakaryia,2 Jawad A. Al-Lawati,3 Omar M. Najem,1
Isra Al-Lawati,1 Ghulam R. Memon,1 Amr A. Elfaham1

Sultan Qaboos University Med J, February 2022, Vol. 22, Iss. 1, pp. 91–97, Epub. 28 Feb 22
Submitted 14 Aug 20
Revisions Req. 14 Oct & 9 Dec 20; Revisions Recd. 20 Nov & 15 Dec 20
Accepted 29 Dec 20

This work is licensed under a Creative Commons Attribution-NoDerivatives 4.0 International License.

https://doi.org/10.18295/squmj.4.2021.062

CLINICAL & BASIC RESEARCH

abstract: Objectives: Stroke is a significant public health problem and one of the most important preventable 
non-communicable diseases. Preventive stroke programmes with a better focus on increasing awareness among 
those who are currently at risk are yet to be properly established in Oman. This study was conducted to describe 
the characteristics of stroke patients presenting to a tertiary care hospital in Oman. Methods: This cross-
sectional hospital-based study included 193 stroke cases which were prospectively recruited from the Emergency 
Department of Khoula Hospital, Muscat, Oman. Data were collected from November 2017 to April 2018. Results: 
The total number of patients was 193 with 82.9% of strokes being ischaemic strokes. Of this, 58% were male. The 
mean age of stroke patients was 61.05 years. Risk factors included hypertension (72.5%) and diabetes mellitus 
(54.4%). Dyslipidaemia, atrial fibrillation and ischaemic heart diseases were not particularly prevalent in the studied 
population and 24.4% of ischaemic strokes had large artery atherosclerosis while 21.9% had small vessel occlusion. 
Significantly more patients had lower Glasgow Coma Scale scores, required intensive care unit admission and 
experienced in-hospital deaths due to haemorrhagic stroke compared to ischaemic stroke. Conclusion: This study 
provides essential data regarding stroke characteristics specific to Oman’s population. Most of the information 
obtained appears to be in-line with what has been described internationally and, hence, preventive strategies 
similar to those indicated in extant literature can be implemented. This information can be utilised by health 
administrators in planning resource allocation. Further research is needed to explore rehabilitation aspects and 
long-term outcomes.

Keywords: Stroke; Ischemic Stroke; Haemorrhagic Stroke; Risk Factors; Thrombolytic Therapy; Epidemiology; 
Oman.

Advances in Knowledge
- This study provides information on the characteristics of stroke patients specific to the local population of Oman and compares them to 

benchmark international trends. 
- Information on the different risk factors associated with stroke in this population can help guide the development of specific preventive 

and possibly rehabilitative strategies for stroke. 

Application to Patient Care 
- This study highlights various stroke-related aspects among patients sustaining a stroke, one of the main causes of morbidity and mortality 

in Oman. 
- Identifying the main risk factors is important in targeting the patient population at risk and providing them with the necessary means of 

prevention through better control of their disease.

Stroke is a prevalent illness worldwide withassociated morbidity, mortality and financial costs to health systems. It is the second most 
common cause of death and the third most common 
cause of disability-adjusted life-years (DALYs) lost 
globally.1 Stroke is more prevalent in the Middle East 
compared to the Western world with an annual incidence 
of 180 per 100,000 individuals, with ischaemic stroke 
being the most common subtype.2 One study revealed 
that it was the leading cause of death in several 
middle-income Arab countries.3 Although the overall 
percentage of the average stroke-related DALYs lost is 
thought to have declined in some Arab countries, the 

global burden of stroke continues to rise.4 The financial 
costs of strokes are multitudinous due to its effects on 
the health system as well as the economy from loss of 
labour, among other costs related to the survivors and 
their caregivers. 

Strokes constitute a significant public health 
problem, being one of the important preventable non- 
communicable diseases.5 The majority of risk factors for 
stroke are modifiable; therefore, preventive strategies 
would be effective in reducing the incidence of new 
and recurrent stroke. Preventive stroke programmes 
with a better focus on increasing awareness among 
those who are currently at risk are yet to be properly 

https://creativecommons.org/licenses/by-nd/4.0/


Clinical Profile of Stroke Patients Presenting to the Emergency Department of a Major Stroke Centre in Oman

92 | SQU Medical Journal, Februay 2022, Volume 21, Issue 1

established in many countries, including Oman. 
Patientsat risk of developing stroke have poor aware- 
ness of their risks, according to one study from a 
primary healthcare setting in Oman.6 Furthermore, it 
appears that many other neighbouring countries of the 
Gulf Cooperation Council (GCC) seem no different, 
with less than a third of the at-risk patients in these 
countries being barely familiar with the meaning of 
stroke.7  

To the best of the authors’ knowledge, there has 
been only a single abstract of a study on ischaemic 
stroke patients in Oman that has been published thus 
far.8 No detailed studies have been conducted in Oman 
on stroke patients and hence, this study will be the first 
to provide the aforementioned information. This study 
aimed to describe the features of stroke presented by 
patients to a stroke centre in a tertiary care hospital in 
Oman. The findings could aid health system planners 
in decisions for more efficient resource allocation, 
including necessary clinical services and development 
of preventive strategies. 

Methods

This cross-sectional hospital-based study included 
193 stroke patients prospectively recruited from the 
Emergency Department (ED) of Khoula Hospital 
(KH) from November 2017 to April 2018. KH is one 
of the main governmental tertiary hospitals with a 
functioning stroke unit in the capital city of Muscat in 
Oman. In addition, it is the only tertiary stroke centre 
under the Ministry of Health with a stroke unit in 
Muscat. This unit also receives referrals from private 
and remotely located hospitals.

Patients were included in the study if they had 
experienced an acute or a sub-acute stroke confirmed 
by computed tomography (CT) scans and/or magnetic 
resonance imaging (MRI). They had to have also 
fulfilled the criteria of the American Heart Association/ 
American Stroke Association according to which an 
ischaemic stroke is defined as “an episode of neuro- 
logical dysfunction caused by focal cerebral, spinal, or 
retinal infarction”, and a haemorrhagic stroke is defined 
as “rapidly developing clinical signs of neurological 
dysfunction attributable to a focal collection of blood 
within the brain parenchyma or ventricular system 
that is not caused by trauma”.9 In the aforementioned 
regard, Omani and non-Omani patients aged 18 
years or above with a confirmed diagnosis of either 
intra-cerebral haemorrhage or ischaemic stroke were 
included in the study. Patients with stroke caused by 
complications arising from trauma were excluded. 
Subarachnoid haemorrhage was not included in the 

analysis as there were no cases encountered during the 
study period.

Data was collected from the patients’ computerised 
records as well as from interviews with the patient 
or a close relative to obtain missing variables in the 
history. The data on functional assessment obtained 
by the Neurology Unit upon discharge was gathered 
from the patient’s medical record. The tools used for 
data collection purposes included standard, pretested 
forms extracting information regarding demographic 
characteristics, type of acute stroke, ischaemic stroke 
subtypes, severity, risk factors, acute management, 
medical comorbidities, duration of hospital admission, 
functional assessment and outcomes.

Information regarding the following parameters 
were evaluated as part of the risk factors for 
stroke (based on previous or current diagnosis): 
1) hypertension, defined as systolic pressure ≥130 
mmHg or diastolic pressure ≥80 mmHg or the 
use of antihypertensive medication; 2) diabetes 
mellitus (DM), defined as use of insulin or an oral 
hypoglycaemic agent or a fasting glucose value ≥126 
mg/dL; 3) dyslipidaemia, defined as elevated total 
or low-density lipoprotein cholesterol levels or low 
levels of high-density lipoprotein cholesterol; and 4) 
cardiac diseases (atrial fibrillation [AF] and myocardial 
infarction). Additionally, information regarding a 
history of current or past tobacco and alcohol use 
was also obtained. Furthermore, a history of previous 
stroke and transient ischaemic attacks was also 
considered.

Ischaemic stroke subtypes were defined according 
to the Trial of Org 10172 in Acute Stroke Treatment 
(TOAST) criteria.10 This is a widely-used classification 
with good reliability and high sensitivity and specificity, 
based on its aetiology of large-artery atherosclerosis 
(LAA), small-vessel disease or lacunar stroke, cardio-
embolic stroke, stroke of other defined aetiologies 
(OD) or stroke of other undetermined aetiology.

The severity of cases was assessed using the 
National Institutes of Health Stroke Scale (NIHSS).11 
The total neurological impairment score was 
interpreted as being very severe (>25), severe (15–24), 
moderately severe (5–14) or mild (<5). The Glasgow 
Coma Scale, in which cases are categorised as being 
mild (>12), moderate (8–12) and severe (<8), was also 
used.12 Functional assessment was assessed using the 
Modified Rankin Scale (MRS).13 The time taken for 
care provision at each stage of stroke management at 
the ED including triaging, doctor’s evaluation, imaging 
and time when management began were also recorded 
to evaluate and account for time delay as a potential 
reason for non-thrombolysis.



Hasina A. Al Harthi, Ammar Al Kashmiri, Lubna M. Zakaryia, Jawad A. Al-Lawati, Omar M. Najem, Isra Al-Lawati, 
Ghulam R. Memon and Amr A. Elfaham

Clinical and Basic Research | 93

All the data were analysed using the Statistical 
Package for Social Science (SPSS), Version 20 (IBM 
Corp., Chicago, Illinois, USA). Statistical inferences 
were drawn based on two-tailed tests and a P value <0.05 
was considered statistically significant. For descriptive 
analysis, the means, medians, standard deviations 
and 95% confidence intervals were calculated. The 
prevalence and frequencies were expressed in terms of 
percentages and the appropriate tables were designed 

to describe the study population. Further analysis of 
ischaemic stroke cases (n = 160) was also performed.

The study was approved by the ethics and 
research committee under the administration unit of 
the Directorate General of Muscat. Informed consent 
was obtained from each participant or his/her relative 
before any interview or neurologic examination was 
conducted.

Results 

A total of 193 confirmed cases of stroke with a mean 
age of 61.05 ± 13.81 years were included in this study. 
The majority of cases were categorised as ischaemic 
strokes (n = 160, 82.90%) and predominantly male 
(58%) among both Omanis and non-Omanis, with a 
male-female ratio of 1.38:1. There was no significant 
difference between the types of strokes in terms of 
gender distribution (P = 0.25) [Table 1]. More than half 
(63%) of the total cases were below 65 years of age with 
haemorrhagic stroke found mostly among the younger 
patients. Eight out of 10 stroke patients were Omanis, 
which could be reflective of the free medical care 
offered to Omani nationals compared to non-Omanis. 

Hypertension was the most prevalent risk factor 
(72.5%) followed by DM (54.4%), which was more 
common among ischaemic stroke cases. Approximately 
a quarter of the ischaemic stroke patients reported 
hypertension, diabetes and dyslipidaemia and 51.3% 
of them were in the 40–60-year age group. Among 
the ischaemic stroke cases, 16.9% (n = 27) and 6.9% 

Table 1: Characteristics of stroke patients presenting to the 
National Stroke Center in Muscat, Oman (N = 193)

Characteristics n (%) P 
value

HS IS

Total 33 (17.1) 160 (82.9)

Age 0.016

Age range in 
years

27–100 27–96

Mean Age ± SD 55.79 ± 16.73 62.13 ± 12.93

Nationality 0.14

Omani 24 (72.7) 134 (83.8)

Non-Omani 9 (27.3) 26 (16.3)

Gender 0.25

Male 16 (48.5) 96 (60.0)

Female 17 (51.5) 64 (40.0)

Educational status 0.752

Illiterate 9 (27.3) 38 (23.8)

Read/write 7 (21.2) 40 (25.0)

Elementary 
education

5 (15.2) 27 (16.9)

Secondary 
education

6 (18.2) 38 (23.8)

Higher 
education

6 (18.2) 17 (10.6)

Marital status 0.934

Single 2 (6.1) 7 (4.4)

Married 24 (72.7) 121 (75.6)

Divorced 1 (3.0) 7 (4.4)

Widowed 6 (18.2) 25 (15.6)

Smoking status (current) 0.99

Yes 2 (6.1) 13 (8.1)

No 31 (93.9) 147 (91.2)

Alcohol consumption (current) 0.69

Yes 1 (3.0) 11 (6.9)

No 32 (97.0) 149 (93.1)

HS = haemorrhagic Stroke; IS = ischaemic stroke; SD = standard deviation.

Table 2: Stroke-related risk factors of stroke patients pre- 
senting to the National Stroke Center in Muscat, Oman 
(N = 193)

Variable n (%) P 
value

HS IS

Total 33 (17.1) 160 (82.9)

Hypertension 21 (63.6) 119 (74.4) 0.21

Diabetes mellitus 13 (39.4) 92 (57.5) 0.06

Dyslipidaemia 7 (21.2) 51 (31.9) 0.29

Ischemic heart 
disease

3 (9.1) 34 (21.3) 0.16

Atrial fibrillation 4 (12.1) 11 (6.9) 0.30

Hypertension 
+ diabetes + 
dyslipidaemia

6 (18.2) 39 (24.4) 0.44

Past history of 
stroke

4 (12.1) 27 (16.9) 0.40

Family history of 
stroke

1 (3.0) 3 (1.9) 0.53

HS = haemorrhagic Stroke; IS = ischaemic stroke.



Clinical Profile of Stroke Patients Presenting to the Emergency Department of a Major Stroke Centre in Oman

94 | SQU Medical Journal, Februay 2022, Volume 21, Issue 1

(n = 11) reported history of previous stroke and 
transient ischaemic attack, respectively [Table 2]. 
The distribution of cases according to severity are 
demonstrated in Table 3.

According to the NIHSS score ranking, haemo- 
rrhagic stroke cases were more severe compared to 
ischaemic stroke cases (P = 0.005). The severity of 
stroke incidents correlated with the age group among 
the ischaemic stroke cases, with 69.2% of severe 
cases presenting among patients aged above 60 years 

(P = 0.004) but not among the haemorrhagic stroke 
cases (P = 0.816). The age group also correlated with 
outcomes among the haemorrhagic stroke cases (P 
= 0.002) with five deaths being reported among the 
haemorrhagic stroke cases; all of these patients were 
below 40 years of age and had an NIHSS score ranging 
from severe to very severe. There was no significant 
difference between the two genders in relation to the 
NIHSS score (P = 0.488) or outcome (P = 0.319).

The average time (in minutes) spent on different 
steps of providing care in the ED for patients being 
attended to on the day of symptom presentation (n 
= 106) can be found in Table 4. Among these cases, 
25.6% presented directly to the ED while the rest were 
escorted by ambulance. Among those escorted by 
ambulance, 96.9% were diagnosed with a query stroke. 

Around half of the cases (n = 82) were classified 
utilising the TOAST classification system, of which 
45% were diagnosed with large artery atherosclerosis, 
40% with small vessel occlusion, 9% with stroke of other 
undetermined aetiology and 6% were cardioembolic. 
The rest of the cases, however, did not receive any 
classification. The majority of the cases that were 
classified were diagnosed with LAA followed by small 
vessel occlusion.

Around 53.7% of the ischaemic stroke cases 
presented on the day the symptoms of stroke 
developed. Approximately 5.8% of early presenting 
cases had a contraindication for thrombolysis. Only 
19 (11.9%) of all ischaemic stroke cases (n = 160) had 
intravenous thrombolysis, five of whom died. 

Discussion 

To the best of the authors’ knowledge, this is the 
first detailed account of the characteristics of stroke 
patients presenting to the main National Stroke Center 
in Oman. In this study, several aspects related to stroke 
among patients presenting acutely to a tertiary care 
hospital were looked at. These included demographics, 
associated risk factors, clinical presentation and their 
sequelae. The mean age for stroke in the current 

Table 3: Severity of stroke and various other stroke-related 
outcomes of stroke patients presenting to the National 
Stroke Center in Muscat, Oman (N = 193)

Variable n (%) P 
value

HS IS

Total 33 (17.1) 160 (82.9)

National Institute of Health Scale Score 0.005

Mild 13 (39.4) 109 (68.1)

Moderate 11 (33.3) 38 (23.8)

Severe/very severe 9 (27.3) 13 (8.1)

Glasgow coma scale 0.001

Mild 23 (69.7) 150 (93.8)

Moderate 4 (12.1) 7 (4.4)

Severe 6 (18.2) 3 (1.9)

Complications* 9 (28.1) 22 (14.2) 0.07

Intensive care unit 
admission*

16 (50.0) 35 (22.6) 0.004

Hospital stay ± SD 10.58 ± 
11.89

7.94 ± 
7.31

0.09

Outcome 0.35

Died 5 (15.2) 11 (6.9)

Survived 27 (81.8) 144 (90.0)

Signed LAMA 1 (3.0) 5 (3.1)

Modified ranking score upon discharge* 0.26

No symptoms 1 (3.1) 12 (7.7)

No significant 
disability

3 (9.4) 30 (19.4)

Slight disability 4 (12.5) 32 (20.6)

Moderate disability 10 (31.3) 43 (27.7)

Moderately sever 
disability

6 (18.8) 21 (13.5)

Severe disability 3 (9.4) 5 (3.2)

Died 5 (15.6) 12 (7.7)

HS = haemorrhagic Stroke; IS = ischaemic stroke; CI = confidence 
interval; SD = standard deviation; LAMA = left against medical advice.
*Patients who left against medical advice were excluded and percentages 
have been calculated based on the total number of remaining patients.

Table 4: Average time spent during different stages of care 
provision at the Emergency Department for stroke patients 
presenting on the day of stroke symptom development 
to the National Stroke Center in Muscat, Oman (n = 106)

Variable Mean in minutes ± SD

Time from arrival until triage 6.77 ± 4.5

Time from arrival until doctor 
evaluation

7.58 ± 0.82

Time from arrival until imaging 28.53 ± 3.08

SD = standard deviation.



Hasina A. Al Harthi, Ammar Al Kashmiri, Lubna M. Zakaryia, Jawad A. Al-Lawati, Omar M. Najem, Isra Al-Lawati, 
Ghulam R. Memon and Amr A. Elfaham

Clinical and Basic Research | 95

population was similar to the mean age reported by 
many South Asian countries. For example, the mean 
age was 59 years in Pakistan and 63 years in India.14 In 
the Western world, however, the mean age of incident 
stroke was higher, (68 years in the USA and 71 years 
in Italy).15 This finding may be a source of concern 
considering the relatively young age of stroke onset 
for both its types in Oman. However, it is known from 
experience that the documentation of age in Oman has 
been inaccurate in the past, especially for generations 
born prior to the 1970s. During those times, Oman 
had an underdeveloped system for civil registration of 
vital statistics, including recording birth dates. Most 
of the current cohort afflicted by stroke were born at 
home with no birth certificates. Furthermore, patients 
from this generation tended to underestimate their age 
when asked for the same as part of the medical records 
at admission. Therefore, the average age of incident 
stroke cases at onset may actually be closer to that of 
the Western world than it appears now.

Since stroke is potentially preventable through 
control of its risk factors, it is important to identify 
these risk factors and determine their relative 
prevalence in order to manage them through primary 
prevention. Hypertension can lead to ischaemic 
stroke through acceleration of the development of 
atherosclerosis which results in atherothrombotic 
events. The relationship between hypertension and 
haemorrhagic stroke is also well documented with 
global consistency.16 Uncontrolled hypertension is the 
main cause for primary intracerebral haemorrhage. 
This can be prevented through good blood pressure 
control and regular medical check-ups to diagnose 
hypertension early. Patients are often diagnosed with 
hypertension only after the development of a target 
organ issue such as a haemorrhagic stroke.17

Approximately half of the patient population in 
the present study had DM with a significantly higher 
prevalence in the ischaemic stroke group. Ischaemic 
stroke is known to be independently associated with 
DM which increases its risk two to six times. However, 
with regards to haemorrhagic stroke, the link with 
diabetes has not been consistent. AF is another risk 
factor associated with ischaemic stroke. AF is also 
associated with a higher risk of stroke recurrence, 
whether it is diagnosed after or known before the 
stroke incident.18 It is interesting to note that the 
prevalence of AF in the present ischaemic stroke 
group was approximately 8%, significantly lower than 
the internationally reported rate which can reach as 
high as one third of the stroke cases.19 Whether this 
represents a generally lower incidence of AF in the 
current sample or more efficient management of 
existing AF with anticoagulation leading to a lower 

incidence of thrombotic complications remains 
unclear. However, it is important to note that AF can 
get picked-up later during the patient’s hospital course 
or later during follow-up with a cardiologist using 
Holter monitoring; hence, it is possible that some 
cases were not identified during the patients’ course of 
admission at the ED. 

Other risk factors known to have an association 
with stroke were analysed. These included past 
history of transient ischaemic attacks, dyslipidaemia, 
ischaemic heart disease and a family history of stroke. 
These factors were more commonly absent than 
present in the current population.

The majority of strokes were of the ischaemic 
type constituting more than 80% of cases with the rest 
being haemorrhagic. This is consistent with reports 
from Western countries where ischaemic stroke 
is significantly more common than haemorrhagic 
stroke.20 Studies from other Arab countries, including 
the GCC, reported variable proportions for ischaemic 
stroke ranging from approximately 58% to 87%, with 
the highest being reported in Saudi Arabia and the 
lowest in Bahrain and Sudan, where haemorrhagic 
stroke comprised a larger percentage.21–23 The latter is 
more consistent with the pattern of strokes observed 
in the Eastern part of the globe, where the incidence 
of haemorrhagic stroke is reported to be twice that 
seen in the West.24 This higher incidence is even seen 
in East Asians who have immigrated to the West.25 
These differences may partly be related to ethnicity, a 
factor which was not explored in this study.26 The fact 
that the current findings mirror the Western patterns 
of this disease may be a reflection of the change in 
lifestyle in Oman that has accompanied the rapid 
modernisation and development that the country 
has witnessed over the past four decades, including 
changes in the healthcare system. Furthermore, the 
lower rate of haemorrhagic stroke is likely due to 
implementation of treatment screening programmes 
for the hypertension, a significant factor known to be 
related to haemorrhagic strokes.27,28 

When comparing the severity of the two subtypes 
of stroke, haemorrhagic stroke had significantly worse 
outcomes compared to ischaemic stroke with a higher 
incidence of requiring admission to the intensive care 
unit and a longer hospital stay. The incidence of death 
was twice as common in haemorrhagic strokes. This 
is consistent with findings from many international 
studies.29 Intracranial haemorrhage causes more 
severe strokes and is known to be an independent 
predictor of poor neurological outcomes with higher 
odds of long-term disability. This is a direct result of 
haemorrhage causing larger anatomic lesions when 
compared to ischaemia-induced strokes.30 The in-



Clinical Profile of Stroke Patients Presenting to the Emergency Department of a Major Stroke Centre in Oman

96 | SQU Medical Journal, Februay 2022, Volume 21, Issue 1

hospital mortality rate of haemorrhagic stroke was 
relatively low compared to other reports.31 

This study has certain strengths and limitations. 
This is the first study from Oman to prospectively 
collect data from patients during their ED visits. It 
systematically reviewed the burden of stroke admitted 
to the National Stroke Center. The findings from this 
study can be utilised to inform future research in the 
country and to guide appropriate preventive strategies 
as well as resource allocation. 

One limitation of this study is that it is a single-
centre study; therefore, the findings may not be 
considered to be generalisable to the entire population. 
Furthermore, the sample size was relatively small, 
which may affect the reliability of the obtained 
statistical results. Another limitation is that patients 
were only interviewed during their ED visits, which 
limited the collection of other variables that may have 
been relevant and could have been collected if the 
study had included following the patients’ in-hospital 
course. In addition, patients were not followed-up 
with throughout their rehabilitation course, limiting 
the information obtained on their pattern of recovery. 
For future studies, it will be important to expand the 
research to include all stroke patients admitted to 
hospitals in Oman. The adequacy of long-term and 
rehabilitation facilities for stroke patients is still to be 
assessed in Oman. 

Conclusion

This study provides essential data on stroke charact- 
eristics which is important in developing effective 
prevention, management and rehabilitation strategies 
specific to Oman’s population. Most of the information 
obtained conforms with that described internationally 
and, therefore, similar preventive strategies can be 
implemented. Furthermore, the information can be 
utilised by health administrators in planning resource 
allocation. Further research is needed to explore 
rehabilitation aspects and long-term outcomes.

c o n f l i c t o f i n t e r e s t
The authors declare no conflicts of interest. 

f u n d i n g

No funding was received for this study.

a u t h o r s’ c o n t r i b u t i o n
HH, AK, JL conceptualised and designed the study. 
LZ, ON, IL, GM, AE AB collected the data. HH, 
AK, JL analysed and interpreted the results. HH, 
AK, JL drafted the manuscript. All authors reviewed 

the results and approved the final version of the 
manuscript. 

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