key: cord-0890295-0r6hxk5d
authors: Arandela, Kristine; Samudrala, Shilpa; Abdalkader, Mohamad; Anand, Pria; Daneshmand, Ali; Dasenbrock, Hormuzdiyar; Nguyen, Thanh; Ong, Charlene; Takahashi, Courtney; Shulman, Julie; Babi, Marc Alain; Sivakumar, Sanjeev; Shah, Neel; Jain, Sandip; Anand, Samyuktha; Nobleza, Christa O'Hana S.; Shekhar, Shashank; Venkatasubramanian, Chitra; Salahuddin, Hisham; Taqi, Muhammad A.; Nour, Hassan Aboul; Nofar, Justin B.; Cervantes-Arslanian, Anna M.
title: Reversible Cerebral Vasoconstriction Syndrome in Patients with Coronavirus Disease: A Multicenter Case Series
date: 2021-09-17
journal: J Stroke Cerebrovasc Dis
DOI: 10.1016/j.jstrokecerebrovasdis.2021.106118
sha: 0e216c9147deecb93275900fe768df84d5acefe0
doc_id: 890295
cord_uid: 0r6hxk5d

BACKGROUND/PURPOSE: : RCVS (Reversible Cerebral Vasoconstrictive Syndrome) is a condition associated with vasoactive agents that alter endothelial function. There is growing evidence that endothelial inflammation contributes to cerebrovascular disease in patients with coronavirus disease 2019 (COVID-19). In our study, we describe the clinical features, risk factors, and outcomes of RCVS in a multicenter case series of patients with COVID-19. METHODS: : Multicenter retrospective case series. We collected clinical characteristics, imaging, and outcomes of patients with RCVS and COVID-19 identified at each participating site. RESULTS: : Ten patients were identified, 7 women, ages 21 – 62 years. Risk factors included use of vasoconstrictive agents in 7 and history of migraine in 2. Presenting symptoms included thunderclap headache in 5 patients with recurrent headaches in 4. Eight were hypertensive on arrival to the hospital. Symptoms of COVID-19 included fever in 2, respiratory symptoms in 8, and gastrointestinal symptoms in 1. One patient did not have systemic COVID-19 symptoms. MRI showed subarachnoid hemorrhage in 3 cases, intraparenchymal hemorrhage in 2, acute ischemic stroke in 4, FLAIR hyperintensities in 2, and no abnormalities in 1 case. Neurovascular imaging showed focal segment irregularity and narrowing concerning for vasospasm of the left MCA in 4 cases and diffuse, multifocal narrowing of the intracranial vasculature in 6 cases. Outcomes varied, with 2 deaths, 2 remaining in the ICU, and 6 surviving to discharge with modified Rankin scale (mRS) scores of 0 (n=3), 2 (n=2), and 3 (n=1). CONCLUSION: : Our series suggests that patients with COVID-19 may be at risk for RCVS, particularly in the setting of additional risk factors such as exposure to vasoactive agents. There was variability in the symptoms and severity of COVID-19, clinical characteristics, abnormalities on imaging, and mRS scores. However, a larger study is needed to validate a causal relationship between RCVS and COVID-19.

Multicenter retrospective case series. We collected clinical characteristics, imaging, and outcomes of patients with RCVS and COVID-19 identified at each participating site.

Results:

Ten patients were identified, 7 women, ages 21 -62 years. Risk factors included use of vasoconstrictive agents in 7 and history of migraine in 2. Presenting symptoms included thunderclap headache in 5 patients with recurrent headaches in 4. Eight were hypertensive on arrival to the hospital. Symptoms of COVID-19 included fever in 2, respiratory symptoms in 8, and gastrointestinal symptoms in 1. One patient did not have systemic COVID-19 symptoms. MRI showed subarachnoid hemorrhage in 3 cases, intraparenchymal hemorrhage in 2, acute ischemic stroke in 4, FLAIR hyperintensities in 2, and no abnormalities in 1 case. Neurovascular imaging showed focal segment irregularity and narrowing concerning for vasospasm of the left MCA in 4 cases and diffuse, multifocal narrowing of the intracranial vasculature in 6 cases. Outcomes varied, with 2 deaths, 2 remaining in the ICU, and 6 surviving to discharge with modified Rankin scale (mRS) scores of 0 (n=3), 2 (n=2), and 3 (n=1).

Our series suggests that patients with COVID-19 may be at risk for RCVS, particularly in the setting of additional risk factors such as exposure to vasoactive agents. There was variability in the symptoms and severity of COVID-19, clinical characteristics, abnormalities on imaging, and mRS scores. However, a larger study is needed to validate a causal relationship between RCVS and COVID-19.

Search terms RCVS, COVID-19, SARS-CoV-2, stroke Introduction:

The reversible cerebral vasoconstriction syndrome (RCVS) is characterized by severe thunderclap headache with angiography showing diffuse, multifocal, segmental constriction of cerebral arteries which typically resolves within 3 months. The headache may or may not be accompanied by focal deficits that result from ischemic stroke, convexal subarachnoid hemorrhage, intraparenchymal hemorrhage, or reversible cerebral edema. It is typically provoked by vasoconstrictive agents, triggered by sexual activity or valsalva maneuvers, and associated with conditions such as pregnancy or postpartum state, catecholamine-secreting tumors, and intracranial vascular lesions [1] . Cerebrovascular complications occur in 0.5 to 5% of acute COVID-19 infections [2] [3] [4] [5] . Acute ischemic stroke comprises the majority of cases, but intracerebral hemorrhage [6] , cerebral venous sinus thrombosis [7, 8] , and posterior reversible encephalopathy syndrome (PRES) [9] have also been reported. There are several mechanisms by which COVID-19 infection may lead to stroke, including exacerbation of pre-existing underlying vascular risk factors, viral mediated hypercoagulability, hyperinflammatory state, general critical illness, hypoxia, hypotension, direct cardiac effects, but also via activation of the renin-angiotensin system, and direct endothelial invasion leading to endotheliitis [10] [11] [12] [13] . In the latter two mechanisms, cellular invasion by the SARS-CoV-2 virus occurs via binding of the viral spike protein to the ACE2 receptor which leads to the downstream effects of vasoconstriction, hypercoagulability, a pro-inflammatory state, sympathetic hyperactivity and subsequent blood pressure elevation and cerebral autoregulation failure [10, 11] . The pathophysiology of RCVS remains unknown but could be plausibly related to SARS-CoV-2 infection given its proposed mechanisms of endothelial dysfunction, dysregulation of cerebral arterial tone, and sympathetic hyperactivity that are thought to provoke cerebral vasoconstriction [1, 16] . This is based on its natural history, lack of histological findings on brain biopsy, significant overlap with PRES, and its association with sympathomimetic vasoactive substances and catecholamine secreting tumors [17] . To investigate the relationship further, we present a multicenter case series of ten patients with concomitant RCVS and acute COVID-19 infection.

This study was approved or exempted by the institutional review boards of Boston Medical Center, PrismaHealth, University of Mississippi, University of Florida, University of Toledo, Stanford University, and Henry Ford Hospital.

The patients ranged from 21 to 62 years in age. Seven of ten of the patients were female. 6 patients were Caucasian, 3 were African American, and 1 was Haitian Creole. Common comorbidities included hypertension in five patients, diabetes mellitus in three patients, hyperlipidemia in four patients, obesity in four patients, and obstructive sleep apnea in one patient. Further details of the patient characteristics are described in Table 1 .

Nine patients were diagnosed with COVID-19 within 30 days prior to the RCVS diagnosis, one patient was diagnosed more than 30 days prior to the RCVS diagnosis, and one patient was diagnosed in the 30 days following RCVS diagnosis. Nine patients experienced systemic symptoms of COVID within 30 days prior to RCVS diagnosis and one patient was asymptomatic. The patient who was diagnosed with COVID-19 more than 30 days prior to RCVS diagnosis was first admitted less than 45 days prior for COVID Pneumonia, had improved respiratory status for discharge, then worsened and required readmission during which RCVS was diagnosed. The last patient was admitted with RCVS and then had a positive COVID PCR test two weeks later. Her symptoms were mild cough and sore throat which became noticeable to her within 48 hours after her RCVS presentation. Because her symptoms were so mild, the temporal course was unclear and she eventually reported her symptoms as an outpatient two weeks later when the cough and sore throat were persistent. Further details of the temporal relationship of COVID symptoms to RCVS diagnosis are detailed in Table 1 . COVID-19 was identified from nasopharyngeal or respiratory specimens with positive polymerase chain reaction testing in eight of ten patients. The remaining two testing methods could not be confirmed.

Typical systemic symptoms of COVID-19 included fever in two, cough/respiratory symptoms in eight, GI symptoms in one, headache with anosmia in one, and one was asymptomatic. With regards to severity, four patients required ICU admission for COVID-19 related respiratory complications while the remaining patients were managed on the medical floor. COVID-related hypercoagulability labs ( Table 2) showed D-dimer values elevated in seven patients (0.23 to 73,225 ng/mL). CRP values were obtained and elevated in six patients (14. 70 to 133 mg/L).

Five patients experienced at least one thunderclap headache with 4 patients experiencing recurrent thunderclap headaches. Triggering factors for headache identified were orgasm, Valsalva maneuver while straining, and a root canal. Associated neurologic deficits included encephalopathy in four, hemiparesis in two, aphasia in two, and visual deficits in two. Eight patients were hypertensive on arrival with blood pressure ranging from 140/65 to greater than 270 systolic. One patient was normotensive upon hospital arrival and the remaining patient was in septic shock requiring vasopressor support.

Five out of ten patients were regularly using medications previously associated with RCVS; 5 were taking Selective Serotonin Reuptake Inhibitors and 1 was taking nasal decongestants. One patient took red rice yeast, milk thistle, fish oil, and turmeric. The last three patients did not take any medications. Eight out of ten patients had negative urine drug screens. Two cases were associated with illicit drugs with one patient using barbiturates and opiates, and another patient with daily marijuana use. Of seven female patients, five had negative hCG pregnancy tests and none were within the post-partum period. Only two out of ten patients had a condition associated with RCVS (migraine).

MRI Brain identified acute ischemic strokes in 4 cases, FLAIR hyperintensities in 2, subarachnoid hemorrhage in 3, and intraparenchymal hemorrhage in 2. One patient did not have acute findings on an MRI Brain with contrast. One patient had a CT without subarachnoid hemorrhage or stroke. Only two patients had delayed interval imaging and in one case the repeat MRI Brain at 3 months showed resolution of the FLAIR hyperintensities involving the bilateral parietal and occipital lobes while an MRA showed resolution of previously seen multivessel narrowing and irregularity. In the other case, the repeat CTA Head/Neck at 3 months showed significant improvement in the previously seen multivessel stenosis.

Ten patients underwent neurovascular imaging with most patients receiving a combination of CTA (n=9), MRA (n=5), and conventional angiogram (n=6). Four patients had focal segment irregularity and narrowing concerning for vasospasm. All four patients had focal involvement of the left middle cerebral artery. Six patients had diffuse, multifocal narrowing of the intracranial vasculature. One patient had only distal branch involvement while two patients had both proximal and distal focal involvement of the left middle cerebral artery. Further details of the brain and neurovascular imaging are described in Table 3 and depicted in Figures 1-3 .

Only two patients were administered IA calcium channel blockers. One patient was administered verapamil and milrinone during her cerebral angiogram with moderate improvement of her diffuse, intracranial vasospasm. One patient was administered daily intra-arterial nicardipine. Five patients were administered corticosteroids, three were given IV dexamethasone, one was given IV methylprednisolone, and one was given PO prednisone.

Two patients remain hospitalized in the ICU. Two patients died during hospitalization. The remaining patients were discharged: two to an acute rehabilitation center and four were discharged home. The patients who were discharged from the hospital had modified Rankin scale (mRS) scores of 0 (n=3), 2 (n=2), and 3 (n=1).

In our case series, we identified 10 patients who developed RCVS in the setting of COVID-19 infection. Of these cases, 3 patients did not have a provoking condition or medication, suggesting there may be an independent association between RCVS and COVID-19 infection. Although RCVS has not been historically associated with infections, there are several reasons to suspect that COVID-19 infection may specifically contribute to increased risk for development of RCVS.

Cellular invasion by the SARS-CoV-2 virus occurs via binding of the viral spike protein to the ACE2 receptor with downstream effects on the renin-angiotensin system leading to vasoconstriction, a hypercoagulable, pro-inflammatory state, sympathetic hyperactivity leading to elevations in blood pressure, and cerebral autoregulation failure [10, 11] . In many ways this mirrors the proposed pathophysiology in RCVS, where endothelial dysfunction, dysregulation of cerebral arterial tone, and sympathetic hyperactivity are thought to provoke cerebral vasoconstriction [1, 16] . In our series, 7 patients were hypertensive on arrival; five had mild hypertension and two had hypertensive crises. This observation suggests that dysfunction of cerebral autoregulation from COVID-19 may manifest with hypertension as one of the clinical characteristics in RCVS.

Tissue expression of ACE2 receptors determines viral tropism. The ACE2 receptors are expressed on a myriad of tissues outside of the respiratory tract including endothelial cells within the cerebrovasculature which may contribute to pathogenesis of stroke [18] . Indeed SARS-CoV-2 endotheliitis has been described radiographically and via pathology causing strokes [12, 13] . This same mechanism could putatively lead to other conditions of endothelial dysfunction within the cerebrovasculature leading to PRES or RCVS.

It is possible that systemic critical illness, and a hyperinflammatory state in COVID-19 may directly contribute to the development of RCVS. The SARS-CoV-2 virus has been implicated in cytokine and interleukin-6 mediated inflammation of the intracranial vasculature [18] . Interleukin-6 has been detected in higher levels in those patients meeting WHO criteria for severe COVID-19 Pneumonia [20] . For this reason, tocilizumab (an IL-6 inhibitor) has been utilized as a treatment in COVID. Yet the use of tocilizumab itself has also been associated with development of PRES in COVID [9] . In our series, two patients were diagnosed with COVID-19 ARDS and three additional patients required ICU level of care. Neurovascular imaging was obtained in these patients and showed multifocal paucity of opacified intracranial vessels concerning for vasospasm. This observation suggests that there may be an association between the severity of the hyperinflammatory state and respiratory symptoms of COVID-19 with RCVS-related diffuse, intracranial vasospasm. It is also quite possible that RCVS is occurring in many other patients with severe COVID-19 but is not detected due to critical illness or poor prognosis limiting neurologic evaluation and diagnostics including angiography.

Brain parenchymal imaging in RCVS has been reported as normal in 21-55% of patients at symptom onset, but this varies from study to study. Common findings on imaging include: convexity non-aneurysmal subarachnoid hemorrhage in 22-34%, intracerebral hemorrhage in 6-20%, watershed ischemic stroke in 29%, and reversible vasogenic edema in 38% [21, 22] . Of our cohort of 10 patients, two patients had brain parenchymal imaging without acute findings. MRI identified subarachnoid hemorrhage in 3 cases, intraparenchymal hemorrhage in 2, acute ischemic strokes in 4, and FLAIR hyperintensities in 2. The distribution of lesions in our cohort are similar to that reported in other studies. However it is notable that while ischemic strokes in RCVS have been mainly reported in arterial watershed regions, in our cohort, 4 had strokes which were far more extensive. This suggests ischemia in COVID-related RCVS may be more profound. Whether this is due to more severe vasospasm or perhaps due to host factors in the setting of critical illness with COVID-19 infection such as hypotension, hypoxemia, hypercapnia, which exacerbate the effects of cerebral vasoconstriction is unknown.

Outcomes were poorer in our series than previously described [23] . Of our cohort of 10 patients, two patients died, five required the ICU for respiratory support, and one remained on a ventilator at the time of publication. Both patients who died had diffuse multifocal intracranial vasospasm with ischemic strokes on initial imaging, one of whom died despite resolving vasospasm on repeat imaging. Poorer course cannot be attributed solely to the systemic complications of COVID-19 as one of the deaths occurred in a patient without respiratory complications.

An important confounder to the clinical outcome of our patient cohort is glucocorticoid exposure which is associated with clinical, radiographic, and angiographic worsening as well as poor outcome [24] . Three patients were administered IV dexamethasone for severe COVID Pneumonia/ARDS with one still intubated in the ICU, one just recently extubated and with improving clinical course, and the last was discharged home with an mRS of 0. One patient was taking PO prednisone for COVID Pneumonia as an outpatient before her hospitalization for RCVS and ultimately died in the ICU. The last patient was administered IV methylprednisolone for empiric treatment of inflammatory vasculopathy with worsening clinical status, interval strokes and vasogenic edema, worsening vasoconstriction on interval angiographic imaging, and death.

Poorer course and outcome of RCVS cannot be attributed solely to glucocorticoid exposure as four out of five patients also were critically ill with COVID-19 infection.

There are several limitations of our study, most notably the small number of cases, uncertainty of diagnosis in some, and the lack of interval follow-up imaging and functional outcomes in most patients. Diagnosing RCVS has a high specificity of 99% and a high sensitivity of 90% when the RCVS2 score is greater than 5 [25] ; however, only five of the ten patients met this criteria. The remaining five patients with RCVS2 scores <5 did not experience a thunderclap headache. While uncommon, a literature review identified 87 patients with RCVS who did not have a thunderclap headache and instead experienced an atypical, new headache, focal neurological deficits, seizures, or encephalopathy [26] . Furthermore, four of the five patients in our study with RCVS2 scores <5 were either obtunded or aphasic and all required intubation with ICU level care; thus, a clinical history could not be obtained. The remaining patient had an equivocal RCVS2 score because her new, intractable headache on admission was attributed to the severity of her COVID Pneumonia and the temporal course of her headache was not clarified. With this said, it is important to consider alternative inflammatory vasculopathies when the diagnosis is unclear, for which CSF studies could be helpful. We noted in our group of ten patients that only two patients underwent a lumbar puncture with resulting CSF studies that were non-inflammatory.

Despite these limitations, we believe it is important to report these cases given the plausibility of a pathophysiologic basis for viral provocation of RCVS. Our limited study has shown that COVID patients with RCVS have worse outcomes than previously reported cohorts of patients with RCVS, thus making it an important diagnosis to pursue and aggressively manage.

This multicenter case series may suggest a possible association between RCVS and COVID-19 however the exact relationship remains unclear. A larger cohort study is needed in order to validate a causal relationship, establish risk factors, assess disease severity and neurologic involvement, and ultimately aid in prognostication and in treatment.

None. 

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There is a large volume subarachnoid hemorrhage that emanates from this position and is likely a direct extension from the parenchymal hemorrhage. It is also present in the interpeduncular cistern, ambient cistern, and extends to the left sylvian fissure. There is additional subarachnoid hemorrhage present in the left frontoparietal convexity and right temporal sulci.

Left MCA M2 distribution multivessel long segment high-grade stenosis affecting essentially all of the M2 segment branches. Highgrade stenosis extends into the M3 segment and M4 segment of multiple of these branches as well. This is in the region of the large subarachnoid hemorrhage. Low-attenuation in the left thalamus and medial left basal ganglia is nonspecific but suspicious for acute ischemic change.