ISSN: 2469-6706  Vol. 6   2019 



Acute bilateral ischemic stroke in a young adult
without risk factors

Maisa Alafyouni a , 1 Derrick Huang b , 1 Scott Kleiman c and Shanna Jones b

a Department of Emergency Medicine, Royal Oak, MI, USA,b Oakland University, William Beaumont School of Medicine, Rochester, MI, USA, and c Department of
Emergency Medicine, Troy Beaumont Hospital, Troy, MI, USA

Emergency department (ED) management of cerebrovascular ac-
cidents (CVA) in younger patients is complicated by atypical
presentations, rarer etiologies, and greater disability costs. A
previously healthy 27-year-old woman presented to the ED for
a trauma resuscitation that was subsequently converted into a
stroke resuscitation with a last known normal of 8 hours. Com-
puted tomography perfusion scan results diagnosed the patient
with a bilateral ischemic stroke that was successfully treated
with a mechanical thrombectomy. The case highlights the need
for a high index of suspicion in younger CVA patients whose
greater potential for atypical presentations may compromise
time-sensitive treatments.

| young stroke | bilateral CVA | thrombectomy | post-partum | perfu-
sion scan |

Cerebrovascular accidents (CVA) are currently the fifth leadingcause of death in the United States (1). In the emergency de-
partment (ED), acute ischemic stroke was the primary diagnosis in
over 600,000 ED visits each year from 2010 to 2013, with over 90%
of these visits resulting in admission or transfer to another hospital
(2).

CVAs are also a major burden in the US from both a quality
of life and disability standpoint as well as an economic burden (2).
This is particularly problematic for younger CVA patients, often de-
fined as those aged 18 to 54, who may be disabled during their most
productive years of life (3). Although CVAs in this patient group
are relatively rare, making up only 16% of all CVAs in 2013, in-
cidence of this disease among ED visits continues to remain stable
(2). This is reflected in national trend data revealing that the ED
visit rate for ischemic stroke or TIA for patients aged 55 and older
has decreased, whereas no change was observed for patients aged
18 to 54, highlighting a persistent concern for care providers (1, 2,
4).

Time-sensitive decision making and the undifferentiated nature
of patients in the ED are inherent in the assessment and treatment of
CVA patients. In younger patients, this difficulty is exacerbated by
atypical presentations, such as headache and dizziness, as well as
potentially rarer etiologies, such as antiphospholipid antibody syn-
drome and hyperhomocysteinemia (5-7). Furthermore, CVAs may
be misdiagnosed as seizures and the sequelae of CVAs may them-
selves precipitate traumatic accidents, further obscuring assessment.
These difficulties complicate differential diagnoses and result in the
potential for misdiagnosis and delayed CVA treatment (5, 8). Here,
we present a case that showcases the persistent complexities of CVA
care in a young patient and involves new imaging modalities in the
ED that are essential in diagnosis and subsequent treatment.

Case report

Patient information. Age: 27 years, gender: female, ethnicity:
caucasian. Related medical problems: 4 months post-partum, obe-
sity, ischemic CVA.

Objective. Discuss complexities of CVA care in young patients
and new imaging modalities essential in diagnosis and subsequent
treatment.

Case. A previously healthy 27-year-old woman four months
post-partum presented to the ED due to a motor vehicle collision
(MVC). Per emergency medical services (EMS), the patient was a
restrained driver traveling at 35-40 mph when her vehicle experi-
enced a broadside collision with another car, resulting in damage to
the front right passenger side with air bag deployment. Witnesses
note that the patient had crossed a red light without applying the
brakes. The patient was found covered in vomit, diaphoretic, and
only responsive to pain. EMS reported that she may have had a
seizure while driving.

Her husband reported that the patient has been healthy with no
history of seizures, intravenous drug abuse, hypertension, hyper-
lipidemia, blood clots, nor bleeding disorders. He also denied any
surgical and family history in the patient as well as any current med-
ication use. The patient was last seen in her usual state of health 8
hours prior to the MVC. In the ED, the patient vomited once. Initial
vitals indicated a blood pressure of 152/86 mmHg with an oxygen
saturation of 100% on nasal cannula, and were otherwise normal.
On exam, the patient was in no apparent distress with a Glasgow
Coma Scale total of 8 (Eye = 4, Verbal = 1, and Motor = 3). Her
head and body were without obvious external signs of trauma and
a C-collar was in place by EMS. The patient had a regular rate and
rhythm, equal pulses bilaterally, no focal abdominal tenderness, and
her lungs were clear to auscultation. Skin exam was normal. On
neurological exam, she spontaneously withdrew her left upper and
left lower extremity to pain and did not move her right upper or right
lower extremity prompting a stat non-contrast computed tomogra-
phy (CT) of the head.

Initial laboratory studies showed a mild leukocytosis of 11.3
103 µl, glucose of 157 mg/dl, and were otherwise normal - includ-
ing a negative pregnancy test, urinalysis, metabolic panel, coagu-

All authors contributed to this paper. 1 To whom correspondence should be sent: Maisa
Alafyouni: maisa.alafyouni@beaumont.org or Derrick Huang: derrickhuang@oakland.edu

The authors declare no conflict of interest. Submitted: 08/09/2019, published: 10/10/2019.

Freely available online through the UTJMS open access option

utdc.utoledo.edu/Translation UTJMS 2019 Vol. 6 29–31



lation panel, and drug panel. Non-contrast CT scan of the head
showed hypodense lesions in the right temporoparietal region con-
cerning for subacute ischemia. A CT perfusion of the head was
then ordered and showed occlusion of the left middle cerebral artery
(MCA) M1 segment with a core infarct involving the basal ganglia
mid frontal lobe, insular cortex, and the anterior temporal lobe. Is-
chemic penumbra was seen more distally and superiorly at the pari-
etal lobe indicating collateralization from the anterior and posterior
cerebral artery territories (see Fig. 1 and 2). There was also a right
temporal lobe perfusion abnormality suggesting distal branch oc-
clusion with ischemia. National Institutes of Health Stroke Scale
was calculated at 23.

Given the last known normal of the patient, tissue plasminogen
activator (tPA) was not deemed an appropriate treatment option.
Thrombectomy was considered based on the CT perfusion results
and consultation with neurointerventional radiology. The patient
was given a full dose aspirin and ticagrelor, intubated for airway
protection, and admitted for emergent endovascular intervention.
She underwent an uncomplicated mechanical thrombectomy and ul-
timately returned to near baseline function with a mild impairment
in her language skills. All hematologic workup during her admis-
sion was negative and no clear cause was found.

Discussion

We report a case of a successful emergent endovascular inter-
vention for bilateral MCA CVAs in a previously healthy 27-year-
old patient. This patient initially presented as a trauma resusci-
tation that was subsequently converted into a stroke resuscitation
after clinical examination. According to the 2018 American Heart
Association (AHA) and American Stroke Association (ASA) Early
Management Acute Ischemic Stroke guidelines, IV tPA is provided
to eligible acute stroke patients ages > 18 within 3 hours of last
known normal or within 4.5 hours of last known normal based on
ECASS III exclusion criteria (9). Our patient was involved in a
traumatic accident and also arrived outside of the treatment window
with a last known normal of 8 hours prior to ED arrival, thus IV
tPA was deemed inappropriate. Potential candidates for mechani-
cal thrombectomy may receive a CT angiogram or MR (magnetic
resonance) angiogram to identify large vessel occlusion amenable
to surgical treatment. Additionally, these patients have until re-
cently required presentation within 6 hours of last known normal. In
February 2018, AHA/ASA guideline changes expanded the eligibil-
ity for mechanical thrombectomy based on the DAWN or DEFUSE
3 trials (9). In patients with clinical evidence of a large vessel oc-
clusion in the anterior cerebral circulation presenting within 6-24
hours of last known normal, perfusion imaging (CT or MR) or MRI
(magnetic resonance imaging) with DWI (diffusion weighted imag-
ing) sequence can be ordered to evaluate for evidence of large ves-
sel occlusion in the proximal anterior circulation. Incorporating our
CT perfusion scan results in conjunction with neurointerventional
radiology consultation, our patient was deemed an appropriate can-
didate for mechanical thrombectomy.

Classic risk factors for ischemic stroke in young patients mirror
those of older adult patients, including hypertension, dyslipidemia,
and cigarette smoking (10). Although both groups share identical
modifiable risk factors, heart disease such as atrial fibrillation and
diabetes mellitus is more prevalent in patents whereas dyslipidemia
and smoking are more prevalent in younger stroke patients (10).
Other more nuanced risk factors in the younger population include
hyperhomocysteinemia and a history of migraine with aura, a risk
that is significantly heightened among those who are also smokers
and those using oral contraception (10, 11). Our patient did not
possess typical risk factors for ischemic stroke and was not on oral

contraceptive pills commonly associated with increased thrombotic
risk. Although our patient was 4 months post-partum, this is out-
side the post-partum risk threshold of about 12 weeks for increased
thrombotic risk, which is also more commonly related to cerebral
venous thrombosis (12).

The most common etiologies of ischemic stroke differ in young
patients compared to older patients. Various studies exploring is-
chemic stroke etiologies in young patients have utilized the TOAST
criteria, which uses the following categories: large-vessel disease,
small-vessel disease, cardioembolic stroke, other determined cause,
and undetermined cause (10). In one review article utilizing the
TOAST criteria, cardioembolic etiology was the most common
cause of ischemic stroke in young adults, defined at under age 49,
and was determined as the general etiology in 575 (17.3%) of is-
chemic strokes in the study population of 3331 ischemic stroke pa-
tients (3, 10, 13).

 

Fig. 1. Computed tomography (CT) scan with contrast (A) and CT
perfusion parametric maps with time to peak (B), cerebral blood
flow (C), and cerebral blood volume (D), demonstrate occlusion of
the left middle cerebral artery M1 segment with a core infarct (ar-
row) involving the basal ganglia mid frontal lobe, insular cortex,
and the anterior temporal lobe. Ischemic penumbra (dashed arrow)
was seen more distally at the parietal lobe indicating collateraliza-
tion from the anterior cerebral artery and posterior cerebral artery
territories. By convention, all color maps are coded red for higher
values and blue for lower values.

Cardioembolic etiology included a range of pathologies includ-
ing atrial fibrillation, cardiomyopathy, and valve abnormalities. In
the same study population, cervicocephalic arterial dissection was
the most common single etiology of ischemic stroke, comprising
426 (12.8%) of cases (13). Carotid artery dissections may occur in
the setting of trauma, such as strangulation and in an MVC, and the
traumatic event may precede the onset of initial symptoms from sev-
eral hours to days (14). Dissections may also occur spontaneously
in the absence of identified trauma. Notably, outside of hyperhomo-

30 utdc.utoledo.edu/Translation Alafyouni et al.



cystinuria and antiphospholipid antibody syndrome, inherited co-
agulation disorders have not been shown to have a significant role
in stroke in young patients (7, 10). Unfortunately, as in our case,
undetermined etiology has been the most prevalent "diagnosis" in
most studies using the TOAST criteria. This category includes pa-
tients with two or more potential etiologies, a negative work up, and
incomplete investigation or loss to follow up (3).

 

Fig. 2. Computed tomography scan with contrast coronal image
demonstrating loss of cerebral blood flow to the left middle cerebral
artery (black arrow).

Conclusion

Incidence of young patients presenting with ischemic stroke in
the ED has been stable, despite a concomitant decrease in incidence
in older age groups. As in our case, an initial trauma resuscita-
tion may crucially convert to a stroke resuscitation based solely on
a comprehensive history and physical examination, which may be
difficult in younger CVA patients who more often present atypically.
Clinicians are advised to have a low threshold for further exploration
when the history and physical examination do not align. Expansion
of candidacy for emergent surgical intervention and use of newer
imaging modalities has been invaluable to management.

Conflict of interest

Authors declare no conflict of interest.

Authors’ contributions

MA, DH wrote the paper, SJ, SK reviewed and revised the
manuscript. All authors read and approved the final document.

1. Talwalkar A and Uddin S (2015) Trends in Emergency Department Visits for Is-
chemic Stroke and Transient Ischemic Attack: United States, 2001{2011. NCHS
Data Brief (194):1-8.

2. Stuntz M, et al. (2017) Nationwide trends of clinical characteristics and economic
burden of emergency department visits due to acute ischemic stroke. Open Ac-
cess Emerg Med 9:89-96.

3. Smajlovic D (2015) Strokes in young adults: epidemiology and prevention. Vasc
Health Risk Manag 11:157-164.

4. Marini C, Russo T, and Felzani G (2010) Incidence of Stroke in Young Adults: A
Review. Stroke Res Treat 2011.

5. Brandler E, et al. (2015) Prehospital Stroke Identification: Factors Associated
with Diagnostic Accuracy. J Stroke Cerebrovasc Dis 24(9):2161-2166.

6. Xu Y, et al. (2019) Plasma homocysteine levels may be associated with the sub-
types of ischemic stroke: a meta-analysis. Int J Clin Exp Med 12(1):117-124.

7. Brey R (2005) Antiphospholipid Antibodies in Young Adults with Stroke. J
Thromb Thrombolysis 20(2):105-112.

8. Newman-Toker D, et al. (2014) Missed diagnosis of stroke in the emergency
department: a cross-sectional analysis of a large population-based sample. Di-
agnosis 1(2):155-166.

9. Powers W, et al. (2018) 2018 Guidelines for the Early Management of Patients
with Acute Ischemic Stroke: A Guideline for Healthcare Professionals from the
American Heart Association/American Stroke Association. Stroke 49(6).

10. Tancredi L, et al. (2013) Stroke Care in Young Patients. Stroke Res Treat 2013.
11. Bousser M and Welch K (2005) Relation between migraine and stroke. Am J

Ophthalmol 140(6):1173.
12. Kamel H, et al. (2014) Risk of a Thrombotic Event After the 6-Week Postpartum

Period. Obstet Gynecol Surv 69(7):375-376.
13. Yesilot Barlas N, et al. (2013) Etiology of first-ever ischaemic stroke in European

young adults: the 15 cities young stroke study. Eur J Neurol 20:1431-1439.
14. Ben Hassen W, et al. (2014) Imaging of cervical artery dissection. Diagn Interv

Imaging 95(12):1151-61.

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