Abstract

Background

Coronavirus disease 2019 (COVID-19) has emerged as a public health emergency worldwide, predominantly affecting the respiratory tract. However, evidence supports the involvement of extrapulmonary sites, including reports of intracranial hemorrhages.

Objective

To describe six original cases and review the literature on intracranial hemorrhages in patients diagnosed with COVID-19 by molecular methods.

Methods

A systematic literature review was performed on MEDLINE, PubMed, and NCBI electronic databases to identify eligible studies. Of the total 1,624 articles retrieved, only 53 articles met the inclusion criteria.

Results

The overall incidence of intracranial hemorrhage in patients hospitalized for COVID-19 was 0.26%. In this patient group, the mean age was 60 years, and the majority were male (68%) with initial respiratory symptoms (73%) and some comorbidity. Before the diagnosis of hemorrhage, 43% of patients were using anticoagulants, 47.3% at therapeutic doses. The intraparenchymal (50%) was the most affected compartment, followed by the subarachnoid (34%), intraventricular (11%), and subdural (7%). There was a predominance of lobar over non-lobar topographies. Multifocal or multicompartmental hemorrhages were described in 25% of cases. Overall mortality in the cohort studies was 44%, while around 55% of patients were discharged from hospital.

Conclusion

Despite the unusual association, the combination of these two diseases is associated with high rates of mortality and morbidity, as well as more severe clinicoradiological presentations. Further studies are needed to provide robust evidence on the exact pathophysiology behind the occurrence of intracranial hemorrhages after COVID-19 infection.

Keywords
COVID-19; Intracranial Hemorrhages; Cerebral Hemorrhage; Hemorrhagic Stroke

Resumo

Antecedentes

A COVID-19 emergiu como uma emergência de saúde pública em todo o mundo, proporcionando lesão principalmente do trato respiratório. No entanto, várias evidências apontam para acometimento de sítios extrapulmonares, incluindo relatos de hemorragias intracranianas.

Objetivo

Descrever seis casos originais e revisar a literatura sobre hemorragias intracranianas em pacientes com diagnostico de COVID-19 por métodos moleculares.

Métodos

A revisão sistemática da literatura foi feita nas bases de dados eletrônicas da MEDLINE, PubMed e NCBI para identificar os estudos elegíveis. Do total de 1.624 artigos recuperados, apenas 53 artigos preencheram os critérios de inclusão.

Resultados

A incidência geral de hemorragia intracraniana nos pacientes internados por COVID-19 foi de 0,26%. A média de idade foi de 60 anos, e a maioria dos pacientes era do sexo masculino (68%) com sintomas respiratórios iniciais (73%) e alguma comorbidade. Antes do diagnóstico de hemorragia, 43% estavam em uso de anticoagulantes, 47,3% destes em doses terapêuticas. O compartimento mais acometido foi o intraparenquimatoso (50%), seguido do subaracnoideo (34%), intraventricular (11%) e subdural (7%). Houve predomínio de topografias lobares sobre as não-lobares. Hemorragias multifocais ou multicompartimentais foram descritas em 25% dos casos. A mortalidade geral nos estudos de coorte foi de 44%, enquanto houve alta hospitalar em cerca de 55% dos pacientes.

Conclusão

Apesar da associação incomum, a combinação dessas doenças está relacionada com altas taxas de mortalidade e morbidade, bem como apresentações clínico-radiológicas mais graves. Mais estudos são necessários para oferecer evidências robustas sobre a fisiopatologia exata por trás da ocorrência de hemorragias intracranianas após infecção por COVID-19.

Palavras-chave
COVID-19; Hemorragias Intracranianas; Hemorragia Cerebral; Acidente Vascular Cerebral Hemorrágico

INTRODUCTION

A few months after the outbreak of the novel coronavirus disease 2019 (COVID-19), in March 2020, the World Health Organization (WHO) declared a pandemic. Within just 2 years, cumulative COVID-19 cases had reached 455 million, with a death toll of around 6 million worldwide.¹1 World Health Organization. Coronavirus disease (COVID-19) outbreak [Internet]. 2021 [cited 2021 Mar 24]. Available from: https://www.who.int/emergencies/diseases/novel-coronavirus-2019
https://www.who.int/emergencies/diseases... The β-coronavirus, whose full name is severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), causes an infection predominantly of the lower and upper respiratory tract, but there is evidence of involvement of extrapulmonary sites: cardiovascular, central nervous system, gastrointestinal, renal, hepatic, hematologic, and cutaneous.²2 Thakur V, Ratho RK, Kumar P, et al. Multi-Organ Involvement in COVID-19: Beyond Pulmonary Manifestations. J Clin Med 2021;10 (03):446,³3 Sun BW, Zhang M, Wang PC, Song JT. A Clinical Analysis of Extrapulmonary Complications in Novel Coronavirus Pneumonia Patients. Int J Gen Med 2021;14:381–385

Neurological manifestations of COVID-19 include headache, dizziness, altered level of consciousness, hyposmia, hypogeusia, cerebrovascular diseases (CVDs), polyneuropathies, ataxia, and epileptic seizures. Although CVD events are among the least common manifestations, they are one of the most serious and fatal.⁴4 Mao L, Jin H, Wang M, et al. Neurologic Manifestations of Hospitalized Patients With Coronavirus Disease 2019 in Wuhan, China. JAMA Neurol 2020;77(06):683–690,⁵5 Tawakul AA, Alharbi AH, Basahal AM, et al. Neurological Symptoms and Complications of COVID-19 Among Patients in a Tertiary Hospital in Saudi Arabia. Cureus 2021;13(11):e19200

Imaging findings in the patients with neurological symptoms include numerous disorders, with stroke being the most prevalent and dangerous. Hemorrhagic stroke has even higher mortality and symptom severity than ischemic stroke.⁶6 Chowdhary A, Subedi R, Tandon M, et al. Relevance and clinical significance of magnetic resonance imaging of neurological manifestations in covid-19: A systematic review of case reports and case series. Vol. 10, Brain Sciences MDPI AG; 2020:1–15

7 Mogensen MA, Wangaryattawanich P, Hartman J, Filippi CG, Hippe DS, Cross NMRSNA COVID-19 task force. Special report of the RSNA COVID-19 task force: systematic review of outcomes associated with COVID-19 neuroimaging findings in hospitalized patients. Br J Radiol 2021;94(1127):20210149-⁸8 Mahammedi A, Ramos A, Bargalló N, et al. Brain and lung imaging correlation in patients with COVID-19: Could the severity of lung disease reflect the prevalence of acute abnormalities on neuroimaging? A global multicenter observational study. AJNR Am J Neuroradiol 2021;42(06):1008–1016 Intracranial hemorrhages (ICHs) can be classified into five broad categories: intraparenchymal hemorrhage (IPH); intraventricular hemorrhage (IVH); epidural hematoma (EDH); subdural hematoma (SDH); and subarachnoid hemorrhage (SAH).⁹9 Kuo W, Hӓne C, Mukherjee P, Malik J, Yuh EL. Expert-level detection of acute intracranial hemorrhage on head computed tomography using deep learning. Proc Natl Acad Sci U S A 2019; 116(45):22737–22745,¹⁰10 Naidech AM. Intracranial hemorrhage. Am J Respir Crit Care Med 2011;184(09):998–1006

The mechanisms behind neurological involvement, although not yet fully clear, include direct and indirect damage caused by the virus upon invasion of the central nervous system (CNS), involving both hematogenous and retrograde neuronal pathways in the invasion of olfactory neurons.¹¹11 Baig AM, Khaleeq A, Ali U, Syeda H. Evidence of the COVID-19 Virus Targeting the CNS: Tissue Distribution, Host-Virus Interaction, and Proposed Neurotropic Mechanisms. ACS Chem Neurosci 2020;11(07):995–998 The angiotensin II-converting enzyme (ACE2) receptor plays a key role in the mechanism of cell invasion and breakdown of the blood-brain barrier (BBB). Respiratory epithelial cells, neurons and glial cells express ACE2 receptors in abundance.¹²12 Klingenstein M, Klingenstein S, Neckel PH, et al. Evidence of SARSCoV2 Entry Protein ACE2 in the Human Nose and Olfactory Bulb. Cells Tissues Organs 2020;209(4-6):155–164 Nevertheless, there are also mechanisms of indirect injury mediated by the systemic inflammatory syndrome promoted by the storm of proinflammatory cytokines and chemokines, also implicated in the breakdown of the BBB.¹³13 Pedersen SF, Ho YC. SARS-CoV-2: a storm is raging. J Clin Invest 2020;130(05):2202–2205

In general, endothelial dysfunction leads to a systemic prothrombotic state related to high levels of proinflammatory cytokines and also angiotensin II.¹⁴14 Wang Z, Yang Y, Liang X, et al. COVID-19 Associated Ischemic Stroke and Hemorrhagic Stroke: Incidence, Potential Pathological Mechanism, and Management. Front Neurol 2020;11:571996 Findings of abnormalities on coagulation tests and high serum levels of D-dimer, ferritin, and LDH corroborate this hypothesis.¹⁵15 Tang N, Li D,Wang X, Sun Z. Abnormal coagulation parameters are associated with poor prognosis in patients with novel coronavirus pneumonia. J Thromb Haemost 2020;18(04):844–847,¹⁶16 Valderrama EV, Humbert K, Lord A, Frontera J, Yaghi S. Severe Acute Respiratory Syndrome Coronavirus 2 Infection and Ischemic Stroke. Stroke 2020;51(07):e124–e127 Thus, there is a greater tendency for ischemic than hemorrhagic events, and the somewhat paradoxical occurrence of these intracranial hemorrhages might be attributed to blood pressure dysregulation and BBB breakdown.¹⁴14 Wang Z, Yang Y, Liang X, et al. COVID-19 Associated Ischemic Stroke and Hemorrhagic Stroke: Incidence, Potential Pathological Mechanism, and Management. Front Neurol 2020;11:571996

Thus, the aim of this study was to report six original cases of COVID19-related cerebral hemorrhages in patients who presented at a health care facility. Furthermore, the current study, as part of a systematic review, aimed to assess the existing evidence within the literature concerning cases of COVID-19 (confirmed through the real-time polymerase chain reaction [RT-PCR] method) and their potential correlation with intracranial hemorrhage. Additionally, the study aimed to delineate the demographic, clinical, and radiologic characteristics associated with these cases.

METHODS

Case series

Six patients with cerebral hemorrhages related to COVID-19 infection were selected. These cases were observed between 1st May 2020 and December 28th, 2020 at the Air Force Hospital of Belém. The patients had a confirmed diagnosis of COVID-19 through RT-PCR testing, and a diagnosis of ICH was established based on clinical-radiological aspects. Neuroimaging was done in all patients. After reviewing the neuroimaging reports for these patients, they were found to have documented radiographic evidence of hemorrhage. Neuroimaging for these patients was reviewed by a fellowship-trained neuroradiologist to verify the presence and type of hemorrhage. This diagnosis was further corroborated by neuroimaging tests, which included computed tomography (CT) or magnetic resonance imaging (MRI).

The six patients in this case series were not encompassed within the scope of the systematic review conducted in this study.

Literature search strategy

A comprehensive, systematic search of the literature published between December 19, 2021, and May 7, 2022, held on the MEDLINE, PubMed, and NCBI electronic databases was conducted using the following search terms: (hemorrhagic encephalopathy) OR (intracranial bleeding) OR (subarachnoid hemorrhage) OR (subdural hemorrhage) OR (intracranial hemorrhage) OR (hemorrhagic stroke) OR (cerebral hemorrhagic complication) OR (cerebral hemorrhage) AND (SARS-CoV-2 virus) OR (SARS CoV 2 virus) OR (2019-nCoV) OR (COVID-19) OR (2019 novel coronavirus).

Eligibility criteria

The search was limited to articles written in English. Articles identified by the initial search strategy were independently evaluated by two authors (WL and MP) according to the inclusion criteria: involving patients with COVID diagnosed by RT-PCR, a confirmed diagnosis of ICH, description of the cases with individual demographic characteristics, clinical-radiological aspects, interventions, and outcomes. Articles which were duplicates, those that had only the abstract available or were editorial letter articles, as well as those whose full-text was not in English, and those that involved pediatric patients (age < 18) and patients with predominantly non-spontaneous hemorrhages were excluded.

Study selection and quality control

The Covidence systematic review software (Veritas Health Innovation, Melbourne, Australia) was used to import all titles and abstracts of the articles identified and remove duplicate records. Potentially eligible articles were identified by screening the titles and abstracts. The full texts of the studies selected were then thoroughly reviewed for quality control by two authors (WL and MP) using the Newcastle-Ottawa scale, and the eligibility of each study was determined. Any disagreements between the investigators were resolved by consulting with the corresponding author (FP) (Supplementary Material 1 https://www.arquivosdeneuropsiquiatria.org/wp-content/uploads/2023/10/ANP-2022.0230-Supplementary-Material-1.docx).

Data extraction

The following information was collected from each study reviewed: surname of the first author and year of publication, study design, sample size, demographic characteristics, comorbidities, number of patients with hemorrhagic events in COVID-19 hospital admissions, time interval from admission/initial symptoms to radiological diagnosis, initial laboratory findings, antithrombotic therapy prior to onset of hemorrhagic event, type of ICH, clinicoradiological scales applied on admission and/or discharge, mortality rates, and discharge outcomes. Neuroimaging findings were divided into three major types: intraparenchymal hemorrhage (IPH), subdural hematoma (SDH), and subarachnoid hemorrhage (SAH). Additionally, regarding the hemorrhage distribution, we also classified three subtypes: focal intracerebral hemorrhage (FICH), multifocal intracerebral hemorrhage (MFIH), and multicompartmental hemorrhage (MCH).⁹9 Kuo W, Hӓne C, Mukherjee P, Malik J, Yuh EL. Expert-level detection of acute intracranial hemorrhage on head computed tomography using deep learning. Proc Natl Acad Sci U S A 2019; 116(45):22737–22745,¹⁰10 Naidech AM. Intracranial hemorrhage. Am J Respir Crit Care Med 2011;184(09):998–1006,¹⁷17 Altschul DJ, Unda SR, de La Garza Ramos R, et al. Hemorrhagic presentations of COVID-19: Risk factors for mortality. Clin Neurol Neurosurg 2020;198:106112

Synthesis of results

The synthesis of the data was performed with the aid of the Covidence and Excel (Microsoft Corp., Redmond, WA, USA) programs, where data extracted were compiled into tables with their respective categories. Primarily, the relevant findings on eligible cohort and case series studies reporting ICH in COVID-19 hospitalizations were presented in the form of a summary table (Supplementary Material 2, Table 1) accompanied by a narrative description. A concise overview of the attributes of the six patients featured in this case series has been incorporated into Supplementary Material 2, Table 1. The remaining case reports identified by the search were subsequently compared against our original case reports and stratified into additional tables by similar hemorrhagic events (Supplementary Material 2, Tables 2–4).

RESULTS

Case series

The cerebral hemorrhage causes identified in the six selected patients were as follows: IPV/IVH in two cases, both accompanied by indications of intracranial hypertension and uncus herniation; one case with SDH featuring mass effect on the right frontal, temporal, and parietal lobes, alongside indications of intracranial hypertension; two cases with CVT/IPH; and one case with IS/IPH. Detailed clinical and demographic attributes of the patients within this case series can be found in Supplementary Material 2.

Study identification and eligibility

Of a total of 1,624 articles retrieved in the literature search up to March 2022, 6 duplicate studies were removed, and 1,618 articles retained for screening of title and abstract. After exclusion of 1,421 non-relevant studies, 197 studies were retrieved, of which an additional 144 were subsequently excluded for the reasons presented in Figure 1. The selection process resulted in a final total of 53 articles for inclusion in the review.

Characteristics of studies reviewed

Considering 22 cohort selected articles, the prevalence of hemorrhagic cerebrovascular events among patients with COVID-19 was described in Supplementary Material 2, along with epidemiological data. A total of 31 case reports and case series articles were included to report the sex, age, comorbidities, initial symptoms, diagnostic methods, radiological findings, treatment, and outcome. (Supplementary Material 2)

Data synthesis

Incidence of ICH in COVID-19 patients with positive RT-PCR

For the cohort studies, the overall incidence of ICH was ∼ 0.26% among 168,703 patients from the 22 studies evaluated. Regarding range, the studies with the lowest and highest incidence reported 0.06% in 1,661 cases⁵5 Tawakul AA, Alharbi AH, Basahal AM, et al. Neurological Symptoms and Complications of COVID-19 Among Patients in a Tertiary Hospital in Saudi Arabia. Cureus 2021;13(11):e19200 and 23.7% in 80 patients¹⁸18 Lersy F, Willaume T, Brisset JC, et al. Critical illness-associated cerebral microbleeds for patientswith severe COVID-19: etiologic hypotheses. J Neurol 2021;268(08):2676–2684 assessed, respectively.

Demographic aspects of patients with COVID-19 and ICH

Age and sex

For the overall 41 articles involving a total 414 cases, patients had a mean age of 60 years and were predominantly male (67%). Among the cohort studies only, patients were 73% male and had a mean age of 62 years, while the cohorts of only 4 articles¹⁹19 Rothstein A, Oldridge O, Schwennesen H, Do D, Cucchiara BL. Acute Cerebrovascular Events in Hospitalized COVID-19 Patients. Stroke 2020;51(09):e219–e222

20 John S, Hussain SI, Piechowski-Jozwiak B, et al. Clinical characteristics and admission patterns of stroke patients during the COVID 19 pandemic: A single center retrospective, observational study from the Abu Dhabi, United Arab Emirates. Clin Neurol Neurosurg 2020;199:106227

21 Al-Mufti F, Becker C, Kamal H, et al. Acute Cerebrovascular Disorders and Vasculopathies Associated with Significant Mortality in SARS-CoV-2 Patients Admitted toThe Intensive Care Unit in The New York Epicenter. J Stroke Cerebrovasc Dis 2021;30(02): 105429-²²22 Migdady I, Shoskes A, Hasan LZ, et al. Timing of Acute Stroke in COVID-19-A Health System Registry Study. Neurohospitalist 2021;11(04):285–294 had a mean age of < 60 years (Supplementary Material 2, Table 1). However, for the reports and case series, patients had a mean age of 54 years and 60% were male.

Comorbidities

Only half of the cohort studies reported information on comorbidities¹⁷17 Altschul DJ, Unda SR, de La Garza Ramos R, et al. Hemorrhagic presentations of COVID-19: Risk factors for mortality. Clin Neurol Neurosurg 2020;198:106112

18 Lersy F, Willaume T, Brisset JC, et al. Critical illness-associated cerebral microbleeds for patientswith severe COVID-19: etiologic hypotheses. J Neurol 2021;268(08):2676–2684

19 Rothstein A, Oldridge O, Schwennesen H, Do D, Cucchiara BL. Acute Cerebrovascular Events in Hospitalized COVID-19 Patients. Stroke 2020;51(09):e219–e222-²⁰20 John S, Hussain SI, Piechowski-Jozwiak B, et al. Clinical characteristics and admission patterns of stroke patients during the COVID 19 pandemic: A single center retrospective, observational study from the Abu Dhabi, United Arab Emirates. Clin Neurol Neurosurg 2020;199:106227,²²22 Migdady I, Shoskes A, Hasan LZ, et al. Timing of Acute Stroke in COVID-19-A Health System Registry Study. Neurohospitalist 2021;11(04):285–294

23 Siegler JE, Cardona P, Arenillas JF, et al. Cerebrovascular events and outcomes in hospitalized patients with COVID-19: The SVIN COVID-19 Multinational Registry. Int J Stroke 2021;16(04): 437–447

24 Pavlov V, Beylerli O, Gareev I, Torres Solis LF, Solís Herrera A, Aliev G. COVID-19-Related Intracerebral Hemorrhage. Front Aging Neurosci 2020;12:600172

25 Qureshi AI, BaskettWI, Huang W, et al. Intracerebral Hemorrhage and Coronavirus Disease 2019 in a Cohort of 282,718Hospitalized Patients. Neurocrit Care 2022;36(01):259–265

26 Hernández-Fernández F, Sandoval Valencia H, Barbella-Aponte RA, et al. Cerebrovascular disease in patients with COVID-19: neuroimaging, histological and clinical description. Brain 2020; 143(10):3089–3103

27 Kvernland A, Kumar A, Yaghi S, et al. Anticoagulation use and Hemorrhagic Stroke in SARS-CoV-2 Patients Treated at a New York Healthcare System. Neurocrit Care 2021;34(03):748–759-²⁸28 Melmed KR, Cao M, Dogra S, et al. Risk factors for intracerebral hemorrhage in patients with COVID-19. J Thromb Thrombolysis 2021;51(04):953–960 (Supplementary Material 2, Table 1). Hypertension and type 2 diabetes mellitus (DM2) were cited in all such articles, with prevalence ranges of hypertension of 37 to 100%, DM2 11 to 49.4%, and dyslipidemia 8.3 to 67%. The rates of atrial fibrillation²³23 Siegler JE, Cardona P, Arenillas JF, et al. Cerebrovascular events and outcomes in hospitalized patients with COVID-19: The SVIN COVID-19 Multinational Registry. Int J Stroke 2021;16(04): 437–447,²⁵25 Qureshi AI, BaskettWI, Huang W, et al. Intracerebral Hemorrhage and Coronavirus Disease 2019 in a Cohort of 282,718Hospitalized Patients. Neurocrit Care 2022;36(01):259–265,²⁷27 Kvernland A, Kumar A, Yaghi S, et al. Anticoagulation use and Hemorrhagic Stroke in SARS-CoV-2 Patients Treated at a New York Healthcare System. Neurocrit Care 2021;34(03):748–759,²⁸28 Melmed KR, Cao M, Dogra S, et al. Risk factors for intracerebral hemorrhage in patients with COVID-19. J Thromb Thrombolysis 2021;51(04):953–960 were 5.2 to 31.8%, tobacco use¹⁸18 Lersy F, Willaume T, Brisset JC, et al. Critical illness-associated cerebral microbleeds for patientswith severe COVID-19: etiologic hypotheses. J Neurol 2021;268(08):2676–2684,²⁰20 John S, Hussain SI, Piechowski-Jozwiak B, et al. Clinical characteristics and admission patterns of stroke patients during the COVID 19 pandemic: A single center retrospective, observational study from the Abu Dhabi, United Arab Emirates. Clin Neurol Neurosurg 2020;199:106227,²⁴24 Pavlov V, Beylerli O, Gareev I, Torres Solis LF, Solís Herrera A, Aliev G. COVID-19-Related Intracerebral Hemorrhage. Front Aging Neurosci 2020;12:600172

25 Qureshi AI, BaskettWI, Huang W, et al. Intracerebral Hemorrhage and Coronavirus Disease 2019 in a Cohort of 282,718Hospitalized Patients. Neurocrit Care 2022;36(01):259–265-²⁶26 Hernández-Fernández F, Sandoval Valencia H, Barbella-Aponte RA, et al. Cerebrovascular disease in patients with COVID-19: neuroimaging, histological and clinical description. Brain 2020; 143(10):3089–3103 5.3 to 66.6%, coronary disease¹⁹19 Rothstein A, Oldridge O, Schwennesen H, Do D, Cucchiara BL. Acute Cerebrovascular Events in Hospitalized COVID-19 Patients. Stroke 2020;51(09):e219–e222,²⁸28 Melmed KR, Cao M, Dogra S, et al. Risk factors for intracerebral hemorrhage in patients with COVID-19. J Thromb Thrombolysis 2021;51(04):953–960 12.1 to 38%, and congestive heart failure²³23 Siegler JE, Cardona P, Arenillas JF, et al. Cerebrovascular events and outcomes in hospitalized patients with COVID-19: The SVIN COVID-19 Multinational Registry. Int J Stroke 2021;16(04): 437–447,²⁵25 Qureshi AI, BaskettWI, Huang W, et al. Intracerebral Hemorrhage and Coronavirus Disease 2019 in a Cohort of 282,718Hospitalized Patients. Neurocrit Care 2022;36(01):259–265 17.1 to 24.7%.

Previous bleeding events¹⁸18 Lersy F, Willaume T, Brisset JC, et al. Critical illness-associated cerebral microbleeds for patientswith severe COVID-19: etiologic hypotheses. J Neurol 2021;268(08):2676–2684,¹⁹19 Rothstein A, Oldridge O, Schwennesen H, Do D, Cucchiara BL. Acute Cerebrovascular Events in Hospitalized COVID-19 Patients. Stroke 2020;51(09):e219–e222,²³23 Siegler JE, Cardona P, Arenillas JF, et al. Cerebrovascular events and outcomes in hospitalized patients with COVID-19: The SVIN COVID-19 Multinational Registry. Int J Stroke 2021;16(04): 437–447,²⁵25 Qureshi AI, BaskettWI, Huang W, et al. Intracerebral Hemorrhage and Coronavirus Disease 2019 in a Cohort of 282,718Hospitalized Patients. Neurocrit Care 2022;36(01):259–265 ranged from 12.5% to 18%. Cancer was cited in only 2 articles,¹⁷17 Altschul DJ, Unda SR, de La Garza Ramos R, et al. Hemorrhagic presentations of COVID-19: Risk factors for mortality. Clin Neurol Neurosurg 2020;198:106112,²²22 Migdady I, Shoskes A, Hasan LZ, et al. Timing of Acute Stroke in COVID-19-A Health System Registry Study. Neurohospitalist 2021;11(04):285–294 affecting 14 to 33% of the samples investigated. Other comorbidities, such as chronic kidney disease,²³23 Siegler JE, Cardona P, Arenillas JF, et al. Cerebrovascular events and outcomes in hospitalized patients with COVID-19: The SVIN COVID-19 Multinational Registry. Int J Stroke 2021;16(04): 437–447 obesity,¹⁹19 Rothstein A, Oldridge O, Schwennesen H, Do D, Cucchiara BL. Acute Cerebrovascular Events in Hospitalized COVID-19 Patients. Stroke 2020;51(09):e219–e222 alcoholism,²⁵25 Qureshi AI, BaskettWI, Huang W, et al. Intracerebral Hemorrhage and Coronavirus Disease 2019 in a Cohort of 282,718Hospitalized Patients. Neurocrit Care 2022;36(01):259–265 and previous myocardial infarction,¹⁷17 Altschul DJ, Unda SR, de La Garza Ramos R, et al. Hemorrhagic presentations of COVID-19: Risk factors for mortality. Clin Neurol Neurosurg 2020;198:106112 were present in only one cohort each.

Anticoagulation prior to ICH onset

Twenty-five articles, including cohort studies, case series, and case reports, reported administration of some form of anticoagulation in 43% of the 385 patients before the diagnosis of cerebral hemorrhage. Of these, 167 patients (47.3%) used therapeutic doses of anticoagulants, and antiplatelet agents were used in 4% of the 385 cases.

Initial clinical presentations

Out of the 125 COVID-19 cases, 73% initially had respiratory symptoms before the cerebrovascular event, while the remainder had early neurological symptoms. Reported symptoms included sudden severe headache, aphasia, hemiparesis, seizures, altered level of consciousness, and coma.

The time elapsed between the initial symptoms and diagnosis of the event was reported for 131 cases, revealing an average period of 10 days. However, some studies,²⁶26 Hernández-Fernández F, Sandoval Valencia H, Barbella-Aponte RA, et al. Cerebrovascular disease in patients with COVID-19: neuroimaging, histological and clinical description. Brain 2020; 143(10):3089–3103,²⁸28 Melmed KR, Cao M, Dogra S, et al. Risk factors for intracerebral hemorrhage in patients with COVID-19. J Thromb Thrombolysis 2021;51(04):953–960

29 Abbas R, El Naamani K, Sweid A, et al. Intracranial Hemorrhage in Patients with Coronavirus Disease 2019 (COVID-19): A Case Series. World Neurosurg 2021;154:e473–e480-³⁰30 Fayed I, Pivazyan G, Conte AG, Chang J, Mai JC. Intracranial hemorrhage in critically ill patients hospitalized for COVID-19. J Clin Neurosci 2020;81:192–195 involving a total of 61 cases, described the time between patient admission and diagnosis of the event, revealing a mean interval of 13 days. The National Institutes of Health Stroke Scale (NIHSS) was used in 74 of the cases reviewed, with a mean score of 19.7 while the Glasgow Coma Scale (GCS) was used in 90 patients, with scores averaging 7.7.

In-hospital events during hospitalization

Six articles reported other events during the hospital stay in 211 patients.¹⁸18 Lersy F, Willaume T, Brisset JC, et al. Critical illness-associated cerebral microbleeds for patientswith severe COVID-19: etiologic hypotheses. J Neurol 2021;268(08):2676–2684,¹⁹19 Rothstein A, Oldridge O, Schwennesen H, Do D, Cucchiara BL. Acute Cerebrovascular Events in Hospitalized COVID-19 Patients. Stroke 2020;51(09):e219–e222,²⁵25 Qureshi AI, BaskettWI, Huang W, et al. Intracerebral Hemorrhage and Coronavirus Disease 2019 in a Cohort of 282,718Hospitalized Patients. Neurocrit Care 2022;36(01):259–265,²⁹29 Abbas R, El Naamani K, Sweid A, et al. Intracranial Hemorrhage in Patients with Coronavirus Disease 2019 (COVID-19): A Case Series. World Neurosurg 2021;154:e473–e480,³¹31 Keller E, Brandi G, Winklhofer S, et al. Large and Small Cerebral Vessel Involvement in Severe COVID-19:Detailed Clinical Workup of a Case Series. Stroke 2020;51(12):3719–3722,³²32 Mousa-Ibrahim F, Berg S, Od TPDetola O, Teitcher M, Ruland S. Intracranial Hemorrhage in Hospitalized SARS-CoV-2 Patients: A Case Series. J Stroke Cerebrovasc Dis 2021;30(01):105428 The complications presented were acute kidney injury (44%), sepsis (30%), myocardial injury (14%), urinary tract infection (12%), deep vein thrombosis (7%), hepatic failure (5%), and venous thromboembolism (3%).¹⁸18 Lersy F, Willaume T, Brisset JC, et al. Critical illness-associated cerebral microbleeds for patientswith severe COVID-19: etiologic hypotheses. J Neurol 2021;268(08):2676–2684,¹⁹19 Rothstein A, Oldridge O, Schwennesen H, Do D, Cucchiara BL. Acute Cerebrovascular Events in Hospitalized COVID-19 Patients. Stroke 2020;51(09):e219–e222,²⁵25 Qureshi AI, BaskettWI, Huang W, et al. Intracerebral Hemorrhage and Coronavirus Disease 2019 in a Cohort of 282,718Hospitalized Patients. Neurocrit Care 2022;36(01):259–265,²⁹29 Abbas R, El Naamani K, Sweid A, et al. Intracranial Hemorrhage in Patients with Coronavirus Disease 2019 (COVID-19): A Case Series. World Neurosurg 2021;154:e473–e480,³¹31 Keller E, Brandi G, Winklhofer S, et al. Large and Small Cerebral Vessel Involvement in Severe COVID-19:Detailed Clinical Workup of a Case Series. Stroke 2020;51(12):3719–3722,³²32 Mousa-Ibrahim F, Berg S, Od TPDetola O, Teitcher M, Ruland S. Intracranial Hemorrhage in Hospitalized SARS-CoV-2 Patients: A Case Series. J Stroke Cerebrovasc Dis 2021;30(01):105428

Characteristics of ICH

Of the 561 cases included in the review, descriptions of ICH neuroradiological features were provided for 342 (61%). The most frequent presentations were IPH (50%) and SAH (34%), followed by FICH (17%), MFH (15%), microhemorrhages (12%), IVH (11%), MCH (10%), hemorrhagic conversion (9%), and SDH (7%). Analyzing the cohort studies only, the distribution of hemorrhage types differed: IPH (45%), SAH (27%), microhemorrhages (16%), MFH (15%), hemorrhagic conversion (10%), FICH (9%), SDH (9%), MCH (8%), and IVH (7%) (Supplementary Material 2).

Intraparenchymal hemorrhage

IPH was reported in 36 articles, representing 170 patients. The location of the IPH was supratentorial in 66% of cases and infratentorial in 14%, while the remainder had a non-specified location. Additionally, lobar locations accounted for 32% and non-lobar for 24% of cases. Supratentorial hemorrhages were described in 99 cases with the following site distribution: lobar (51%), cortical (28%), basal ganglia (12%), and thalamic (5%) (Supplementary Material 2) (Figure 2).

Some cohorts specified IPH case characteristics in which, in this patient group, up to 75% used anticoagulants, the majority were male (81%), initial symptoms were respiratory (81%), and mean age was 61 years.¹⁸18 Lersy F, Willaume T, Brisset JC, et al. Critical illness-associated cerebral microbleeds for patientswith severe COVID-19: etiologic hypotheses. J Neurol 2021;268(08):2676–2684,¹⁹19 Rothstein A, Oldridge O, Schwennesen H, Do D, Cucchiara BL. Acute Cerebrovascular Events in Hospitalized COVID-19 Patients. Stroke 2020;51(09):e219–e222,²²22 Migdady I, Shoskes A, Hasan LZ, et al. Timing of Acute Stroke in COVID-19-A Health System Registry Study. Neurohospitalist 2021;11(04):285–294,²⁴24 Pavlov V, Beylerli O, Gareev I, Torres Solis LF, Solís Herrera A, Aliev G. COVID-19-Related Intracerebral Hemorrhage. Front Aging Neurosci 2020;12:600172,²⁶26 Hernández-Fernández F, Sandoval Valencia H, Barbella-Aponte RA, et al. Cerebrovascular disease in patients with COVID-19: neuroimaging, histological and clinical description. Brain 2020; 143(10):3089–3103,²⁷27 Kvernland A, Kumar A, Yaghi S, et al. Anticoagulation use and Hemorrhagic Stroke in SARS-CoV-2 Patients Treated at a New York Healthcare System. Neurocrit Care 2021;34(03):748–759 The volume of the IPH was measured in 54 patients, with a mean value of 37.1 cm³ (0.4–125 cm³). Moreover, the mean ICH score for 106 patients was 2.46. (0–5).²³23 Siegler JE, Cardona P, Arenillas JF, et al. Cerebrovascular events and outcomes in hospitalized patients with COVID-19: The SVIN COVID-19 Multinational Registry. Int J Stroke 2021;16(04): 437–447,²⁶26 Hernández-Fernández F, Sandoval Valencia H, Barbella-Aponte RA, et al. Cerebrovascular disease in patients with COVID-19: neuroimaging, histological and clinical description. Brain 2020; 143(10):3089–3103,²⁷27 Kvernland A, Kumar A, Yaghi S, et al. Anticoagulation use and Hemorrhagic Stroke in SARS-CoV-2 Patients Treated at a New York Healthcare System. Neurocrit Care 2021;34(03):748–759,²⁹29 Abbas R, El Naamani K, Sweid A, et al. Intracranial Hemorrhage in Patients with Coronavirus Disease 2019 (COVID-19): A Case Series. World Neurosurg 2021;154:e473–e480

Multicompartmental hemorrhages

A total of 16 studies including a total of 35 patients with MCH were identified. The combinations of hemorrhage locations included IPH/SAH/IVH (n = 11), IPH/SAH (n = 10), IPH/SAH/SDH (n = 10), SDH/SAH (n = 2), and IPH/SDH (n = 1). Some cohorts specified MCH case characteristics, revealing that patients had the same profile of IPH group, and more than half (53%) of these patients were on anticoagulation agents (Supplementary Material 2).

Subarachnoid and subdural hemorrhages

Of a total of 118 cases reported in 34 articles, secondary or undetermined SAH was the most prevalent cause, representing ∼ 75% of cases, while aneurysm and arterial dissection represented 18% and 7% of patients, respectively. Six cohort studies described SAH features, according to which up to 86% of patients were on anticoagulation agents, most had initial respiratory symptoms (62%), and the mean age was 62 years.¹⁷17 Altschul DJ, Unda SR, de La Garza Ramos R, et al. Hemorrhagic presentations of COVID-19: Risk factors for mortality. Clin Neurol Neurosurg 2020;198:106112

18 Lersy F, Willaume T, Brisset JC, et al. Critical illness-associated cerebral microbleeds for patientswith severe COVID-19: etiologic hypotheses. J Neurol 2021;268(08):2676–2684-¹⁹19 Rothstein A, Oldridge O, Schwennesen H, Do D, Cucchiara BL. Acute Cerebrovascular Events in Hospitalized COVID-19 Patients. Stroke 2020;51(09):e219–e222,²¹21 Al-Mufti F, Becker C, Kamal H, et al. Acute Cerebrovascular Disorders and Vasculopathies Associated with Significant Mortality in SARS-CoV-2 Patients Admitted toThe Intensive Care Unit in The New York Epicenter. J Stroke Cerebrovasc Dis 2021;30(02): 105429,²⁶26 Hernández-Fernández F, Sandoval Valencia H, Barbella-Aponte RA, et al. Cerebrovascular disease in patients with COVID-19: neuroimaging, histological and clinical description. Brain 2020; 143(10):3089–3103,²⁷27 Kvernland A, Kumar A, Yaghi S, et al. Anticoagulation use and Hemorrhagic Stroke in SARS-CoV-2 Patients Treated at a New York Healthcare System. Neurocrit Care 2021;34(03):748–759 When including case series and reports, the mean age was 54 years, 81% had respiratory onset, and 68% used anticoagulants.

Only 25 patients in 8 studies reported SDH; these cases were either isolated (n = 20) or associated with multicompartmental hemorrhage (n = 5). Up to 70% of these patients were male and the mean age was 74 years, while 30% used anticoagulants (n = 20). (Supplementary Material 2)

The aneurysmal arteries reported were the posterior inferior cerebellar artery (10%), posterior cerebral artery (10%), anterior choroidal artery (10%), anterior communicating artery (10%), middle cerebral artery (5%), and ophthalmic artery (5%). Moreover, the dissecting arteries were vertebral artery (33%), posterior inferior cerebellar artery (22%), anterior communicating artery (11%), middle cerebral artery (11%), posterior cerebral artery (11%), and internal carotid artery (11%).

Hemorrhagic conversion

Thirty-two patients were identified, in 10 separate articles, who suffered a hemorrhagic conversion of some kind during a COVID-19 infection. Ischemic stroke (IS) was the main cause of these hemorrhages (n = 29) (Figure 3), followed by cerebral venous thrombosis (CVT) (n = 3).

Furthermore, among the case reports, 6 out of the 8 patients had respiratory symptoms, with time from onset to diagnosis of 0 to 21 days, while the remaining 2 cases had a typical acute stroke presentation. Only one patient was managed surgically, and three patients had a poor prognosis with death or multiple organ failure, but none had CVT (Supplementary Material 2, Tables 1 and 4).

Interventions for ICH

Interventions targeting ICH were reported in 10 cohort studies involving a total of 269 cases¹⁷17 Altschul DJ, Unda SR, de La Garza Ramos R, et al. Hemorrhagic presentations of COVID-19: Risk factors for mortality. Clin Neurol Neurosurg 2020;198:106112

18 Lersy F, Willaume T, Brisset JC, et al. Critical illness-associated cerebral microbleeds for patientswith severe COVID-19: etiologic hypotheses. J Neurol 2021;268(08):2676–2684

19 Rothstein A, Oldridge O, Schwennesen H, Do D, Cucchiara BL. Acute Cerebrovascular Events in Hospitalized COVID-19 Patients. Stroke 2020;51(09):e219–e222-²⁰20 John S, Hussain SI, Piechowski-Jozwiak B, et al. Clinical characteristics and admission patterns of stroke patients during the COVID 19 pandemic: A single center retrospective, observational study from the Abu Dhabi, United Arab Emirates. Clin Neurol Neurosurg 2020;199:106227,²²22 Migdady I, Shoskes A, Hasan LZ, et al. Timing of Acute Stroke in COVID-19-A Health System Registry Study. Neurohospitalist 2021;11(04):285–294,²⁴24 Pavlov V, Beylerli O, Gareev I, Torres Solis LF, Solís Herrera A, Aliev G. COVID-19-Related Intracerebral Hemorrhage. Front Aging Neurosci 2020;12:600172

25 Qureshi AI, BaskettWI, Huang W, et al. Intracerebral Hemorrhage and Coronavirus Disease 2019 in a Cohort of 282,718Hospitalized Patients. Neurocrit Care 2022;36(01):259–265

26 Hernández-Fernández F, Sandoval Valencia H, Barbella-Aponte RA, et al. Cerebrovascular disease in patients with COVID-19: neuroimaging, histological and clinical description. Brain 2020; 143(10):3089–3103-²⁷27 Kvernland A, Kumar A, Yaghi S, et al. Anticoagulation use and Hemorrhagic Stroke in SARS-CoV-2 Patients Treated at a New York Healthcare System. Neurocrit Care 2021;34(03):748–759,³³33 Ramos AD, Koyfman F, Byrns K, et al. Characterization of Hemorrhagic and Ischemic Stroke in a Diverse Cohort of COVID-19 Patients. Neurohospitalist 2021;11(04):295–302 (Supplementary Material 1, Table 1). Surgical management was performed in 29 patients (10.7%), 16 of whom had external ventricular shunt (EVD), 5 hematoma drainage with decompressive craniectomy, 2 aneurysm embolization by coiling or flow deviation, 2 had invasive monitoring of intracranial pressure (ICP), and the remaining reports were unclear on the type of surgical approach employed. Management solely by intensive care measures occurred in 45 patients (16.7%). However, the use of specific measures to control ICP or hemorrhage was not specified.

Mortality in COVID-19 patients with ICH

Among the cohort studies, 11 articles described the mortality rate, which ranged from 0 to 84.6%¹⁷17 Altschul DJ, Unda SR, de La Garza Ramos R, et al. Hemorrhagic presentations of COVID-19: Risk factors for mortality. Clin Neurol Neurosurg 2020;198:106112

18 Lersy F, Willaume T, Brisset JC, et al. Critical illness-associated cerebral microbleeds for patientswith severe COVID-19: etiologic hypotheses. J Neurol 2021;268(08):2676–2684

19 Rothstein A, Oldridge O, Schwennesen H, Do D, Cucchiara BL. Acute Cerebrovascular Events in Hospitalized COVID-19 Patients. Stroke 2020;51(09):e219–e222-²⁰20 John S, Hussain SI, Piechowski-Jozwiak B, et al. Clinical characteristics and admission patterns of stroke patients during the COVID 19 pandemic: A single center retrospective, observational study from the Abu Dhabi, United Arab Emirates. Clin Neurol Neurosurg 2020;199:106227,²²22 Migdady I, Shoskes A, Hasan LZ, et al. Timing of Acute Stroke in COVID-19-A Health System Registry Study. Neurohospitalist 2021;11(04):285–294

23 Siegler JE, Cardona P, Arenillas JF, et al. Cerebrovascular events and outcomes in hospitalized patients with COVID-19: The SVIN COVID-19 Multinational Registry. Int J Stroke 2021;16(04): 437–447

24 Pavlov V, Beylerli O, Gareev I, Torres Solis LF, Solís Herrera A, Aliev G. COVID-19-Related Intracerebral Hemorrhage. Front Aging Neurosci 2020;12:600172

25 Qureshi AI, BaskettWI, Huang W, et al. Intracerebral Hemorrhage and Coronavirus Disease 2019 in a Cohort of 282,718Hospitalized Patients. Neurocrit Care 2022;36(01):259–265

26 Hernández-Fernández F, Sandoval Valencia H, Barbella-Aponte RA, et al. Cerebrovascular disease in patients with COVID-19: neuroimaging, histological and clinical description. Brain 2020; 143(10):3089–3103

27 Kvernland A, Kumar A, Yaghi S, et al. Anticoagulation use and Hemorrhagic Stroke in SARS-CoV-2 Patients Treated at a New York Healthcare System. Neurocrit Care 2021;34(03):748–759-²⁸28 Melmed KR, Cao M, Dogra S, et al. Risk factors for intracerebral hemorrhage in patients with COVID-19. J Thromb Thrombolysis 2021;51(04):953–960 (Supplementary Material 2). The overall mortality rate in these studies was 44%, for a total of 313 patients out of 114,706 cases hospitalized with COVID-19. The mortality rate from cerebrovascular hemorrhagic events in hospitalized patients with a confirmed diagnosis of COVID-19 by the RT-PCR method was 0.12%. When case series studies and case reports were included, a total of 427 patients were obtained with an overall mortality rate of 46.3%.

Outcomes reported

Other outcomes were reported in 7 cohort studies,¹⁷17 Altschul DJ, Unda SR, de La Garza Ramos R, et al. Hemorrhagic presentations of COVID-19: Risk factors for mortality. Clin Neurol Neurosurg 2020;198:106112,¹⁸18 Lersy F, Willaume T, Brisset JC, et al. Critical illness-associated cerebral microbleeds for patientswith severe COVID-19: etiologic hypotheses. J Neurol 2021;268(08):2676–2684,²⁰20 John S, Hussain SI, Piechowski-Jozwiak B, et al. Clinical characteristics and admission patterns of stroke patients during the COVID 19 pandemic: A single center retrospective, observational study from the Abu Dhabi, United Arab Emirates. Clin Neurol Neurosurg 2020;199:106227,²²22 Migdady I, Shoskes A, Hasan LZ, et al. Timing of Acute Stroke in COVID-19-A Health System Registry Study. Neurohospitalist 2021;11(04):285–294,²⁴24 Pavlov V, Beylerli O, Gareev I, Torres Solis LF, Solís Herrera A, Aliev G. COVID-19-Related Intracerebral Hemorrhage. Front Aging Neurosci 2020;12:600172,²⁵25 Qureshi AI, BaskettWI, Huang W, et al. Intracerebral Hemorrhage and Coronavirus Disease 2019 in a Cohort of 282,718Hospitalized Patients. Neurocrit Care 2022;36(01):259–265,²⁷27 Kvernland A, Kumar A, Yaghi S, et al. Anticoagulation use and Hemorrhagic Stroke in SARS-CoV-2 Patients Treated at a New York Healthcare System. Neurocrit Care 2021;34(03):748–759 with descriptions of hospital discharge (non-routine, to home or to rehabilitation) in 57.5% of a total of 245 patients. In addition, modified Rankin Scale (mRS) scores at discharge were variably reported and incomplete for the majority of the studies reviewed. Only 4 articles²⁰20 John S, Hussain SI, Piechowski-Jozwiak B, et al. Clinical characteristics and admission patterns of stroke patients during the COVID 19 pandemic: A single center retrospective, observational study from the Abu Dhabi, United Arab Emirates. Clin Neurol Neurosurg 2020;199:106227,²²22 Migdady I, Shoskes A, Hasan LZ, et al. Timing of Acute Stroke in COVID-19-A Health System Registry Study. Neurohospitalist 2021;11(04):285–294,²⁴24 Pavlov V, Beylerli O, Gareev I, Torres Solis LF, Solís Herrera A, Aliev G. COVID-19-Related Intracerebral Hemorrhage. Front Aging Neurosci 2020;12:600172,²⁶26 Hernández-Fernández F, Sandoval Valencia H, Barbella-Aponte RA, et al. Cerebrovascular disease in patients with COVID-19: neuroimaging, histological and clinical description. Brain 2020; 143(10):3089–3103 mentioned a poor prognosis at discharge (mRS > 3), in 69.5% of a total of 23 patients who were evaluated at discharge with this scale (Supplementary Material 2). Including case series and case report studies, hospital discharge was reported in 53.5% out of a total of 327 patients, while there was a poor prognosis (mRS > 3) in 73% of a total of 110 patients (Supplementary Material 2).

DISCUSSION

Several epidemiological studies have reported a significant reduction in hospital admissions involving stroke cases of all types during the first wave period. The decrease in admissions reported by these studies ranged from 12 to 45.6%.³⁴34 Sedova P, Brown RD Jr, Bryndziar T, et al. Treat covid-19, but not only covid-19: Stroke matters as well. Cerebrovasc Dis 2022;51 (01):52–59

35 Douiri A, Muruet W, Bhalla A, et al; SSNAP Collaboration. Stroke Care in the United Kingdom During the COVID-19 Pandemic. Stroke 2021;52(06):2125–2133

36 Wu Y, Chen F, Wang Z, et al. Reductions in Hospital Admissions and Delays in Acute Stroke Care During the Pandemic of COVID-19. Front Neurol 2020;11:584734-³⁷37 Libruder C, RamA, Hershkovitz Y, et al. Reduction in Acute Stroke Admissions during the COVID-19 Pandemic: Data froma National Stroke Registry. Neuroepidemiology 2021;55(05):354–360

There was a more significant reduction for transient ischemic attack (TIA) and IS admissions, although no significant decrease for hemorrhagic stroke cases, possibly explained by the low incidence of this type of event.³⁵35 Douiri A, Muruet W, Bhalla A, et al; SSNAP Collaboration. Stroke Care in the United Kingdom During the COVID-19 Pandemic. Stroke 2021;52(06):2125–2133,³⁷37 Libruder C, RamA, Hershkovitz Y, et al. Reduction in Acute Stroke Admissions during the COVID-19 Pandemic: Data froma National Stroke Registry. Neuroepidemiology 2021;55(05):354–360

38 Balestrino M, Coccia A, Boffa AS, et al. Request of hospital care dropped for TIA but remained stable for stroke during COVID-19 pandemic at a large Italian university hospital. Intern Emerg Med 2021;16(03):735–739-³⁹39 Diegoli H, Magalhães PSC, Martins SCO, et al. Decrease in Hospital Admissions for Transient Ischemic Attack, Mild, and Moderate Stroke During the COVID-19 Era. Stroke 2020;51(08):2315–2321 Other authors found similar results, but reported a significant decrease in hemorrhagic stroke cases.³⁶36 Wu Y, Chen F, Wang Z, et al. Reductions in Hospital Admissions and Delays in Acute Stroke Care During the Pandemic of COVID-19. Front Neurol 2020;11:584734,³⁷37 Libruder C, RamA, Hershkovitz Y, et al. Reduction in Acute Stroke Admissions during the COVID-19 Pandemic: Data froma National Stroke Registry. Neuroepidemiology 2021;55(05):354–360,⁴⁰40 Abdulazim A, Ebert A, Etminan N, Szabo K, Alonso A. Negative Impact of the COVID-19 Pandemic on Admissions for Intracranial Hemorrhage. Front Neurol 2020;11:584522

To investigate this impact, a large observational study involving 187 major stroke centers in 40 countries assessed the impact of the COVID-19 pandemic on hospital admissions for ischemic and hemorrhagic stroke, as well as for the volume of mechanical thrombectomy. A significant global decline was reported in all stroke care indicators during the early COVID-19 pandemic, including a drop in the volume of mechanical thrombectomy procedures (12.7%), overall stroke admissions (19.2%), IS/TIA admissions (15.1%), and of ICH hospitalization cases (11.5%).⁴¹41 Nogueira RG, Abdalkader M, Qureshi MM, et al. Global impact of COVID-19 on stroke care. Int J Stroke 2021;16(05):573–584

Possible explanations for this phenomenon include the cancellation of elective surgeries due to the pandemic, leading to a decrease in perioperative stroke. The lockdown situation may have been a factor improving medication adherence, which can lead to a decrease in cerebrovascular diseases.⁴¹41 Nogueira RG, Abdalkader M, Qureshi MM, et al. Global impact of COVID-19 on stroke care. Int J Stroke 2021;16(05):573–584

These findings are consistent with the reported increase of in-hospital mortality for stroke in some studies,³⁵35 Douiri A, Muruet W, Bhalla A, et al; SSNAP Collaboration. Stroke Care in the United Kingdom During the COVID-19 Pandemic. Stroke 2021;52(06):2125–2133,³⁷37 Libruder C, RamA, Hershkovitz Y, et al. Reduction in Acute Stroke Admissions during the COVID-19 Pandemic: Data froma National Stroke Registry. Neuroepidemiology 2021;55(05):354–360,⁴²42 Tong X, King SMC, Asaithambi G, et al. COVID-19 Pandemic and Quality of Care and Outcomes of Acute Stroke Hospitalizations: the Paul Coverdell National Acute Stroke Program. Prev Chronic Dis 2021;18:E82

43 Katz JM, Libman RB, Wang JJ, et al. Cerebrovascular Complications of COVID-19. Stroke 2020;51(09):e227–e231-⁴⁴44 Jain R, Young M, Dogra S, et al. COVID-19 related neuroimaging findings: A signal of thromboembolic complications and a strong prognostic marker of poor patient outcome. J Neurol Sci 2020; 414:116923 while other studies also found a more marked increase for ICH.¹⁷17 Altschul DJ, Unda SR, de La Garza Ramos R, et al. Hemorrhagic presentations of COVID-19: Risk factors for mortality. Clin Neurol Neurosurg 2020;198:106112,²³23 Siegler JE, Cardona P, Arenillas JF, et al. Cerebrovascular events and outcomes in hospitalized patients with COVID-19: The SVIN COVID-19 Multinational Registry. Int J Stroke 2021;16(04): 437–447,²⁷27 Kvernland A, Kumar A, Yaghi S, et al. Anticoagulation use and Hemorrhagic Stroke in SARS-CoV-2 Patients Treated at a New York Healthcare System. Neurocrit Care 2021;34(03):748–759,²⁸28 Melmed KR, Cao M, Dogra S, et al. Risk factors for intracerebral hemorrhage in patients with COVID-19. J Thromb Thrombolysis 2021;51(04):953–960,³³33 Ramos AD, Koyfman F, Byrns K, et al. Characterization of Hemorrhagic and Ischemic Stroke in a Diverse Cohort of COVID-19 Patients. Neurohospitalist 2021;11(04):295–302 In addition, there is a contradiction if the pandemics caused a change in the proportion of moderate/severe stroke (NIHSS scale > 5), with some studies reporting an increase,³⁶36 Wu Y, Chen F, Wang Z, et al. Reductions in Hospital Admissions and Delays in Acute Stroke Care During the Pandemic of COVID-19. Front Neurol 2020;11:584734,⁴²42 Tong X, King SMC, Asaithambi G, et al. COVID-19 Pandemic and Quality of Care and Outcomes of Acute Stroke Hospitalizations: the Paul Coverdell National Acute Stroke Program. Prev Chronic Dis 2021;18:E82 while others found no significant change.³⁴34 Sedova P, Brown RD Jr, Bryndziar T, et al. Treat covid-19, but not only covid-19: Stroke matters as well. Cerebrovasc Dis 2022;51 (01):52–59,³⁷37 Libruder C, RamA, Hershkovitz Y, et al. Reduction in Acute Stroke Admissions during the COVID-19 Pandemic: Data froma National Stroke Registry. Neuroepidemiology 2021;55(05):354–360,³⁹39 Diegoli H, Magalhães PSC, Martins SCO, et al. Decrease in Hospital Admissions for Transient Ischemic Attack, Mild, and Moderate Stroke During the COVID-19 Era. Stroke 2020;51(08):2315–2321

However, in an observational study of patients aged > 80 years, it was noted that the onset of stroke did not increase the risk of death, and those who survived COVID-19 and an acute stroke had similar outcomes to those without this complication. Active smoking, previous history of stroke, along with a low BMI were identified as significant risk factors for cerebrovascular complications in this age group.⁴⁵45 Mendes A, Herrmann FR, Genton L, et al. Incidence, characteristics and clinical relevance of acute stroke in old patients hospitalized with COVID-19. BMC Geriatr 2021;21(01):52 Among our original cases reported, the 2 patients aged > 70 years had a good prognosis, including complete functional recovery after the stroke event.

Some large meta-analyses involving more than 60,000 patients reported the incidence of CVDs among the group of SARS Cov2-positive admissions, where rates ranged from 1.2 to 1.4% for general CVDs⁴⁶46 Katsanos AH, Palaiodimou L, Zand R, et al. The Impact of SARSCoV-2 on Stroke Epidemiology and Care: A Meta-Analysis. Ann Neurol 2021;89(02):380–388

47 Syahrul S, Maliga HA, Ilmawan M, et al. Hemorrhagic and ischemic stroke in patients with coronavirus disease 2019: incidence, risk factors, and pathogenesis - a systematic review and meta-analysis. F1000 Res 2021;10:34-⁴⁸48 Nannoni S, de Groot R, Bell S, Markus HS. Stroke in COVID-19: A systematic review and meta-analysis. Int J Stroke 2021;16(02): 137–149 and from 0.2 to 0.3% for ICH.⁴⁶46 Katsanos AH, Palaiodimou L, Zand R, et al. The Impact of SARSCoV-2 on Stroke Epidemiology and Care: A Meta-Analysis. Ann Neurol 2021;89(02):380–388,⁴⁷47 Syahrul S, Maliga HA, Ilmawan M, et al. Hemorrhagic and ischemic stroke in patients with coronavirus disease 2019: incidence, risk factors, and pathogenesis - a systematic review and meta-analysis. F1000 Res 2021;10:34 Additionally, CVD in these patients was associated with more severe infectious disease and an ∼ 5-fold increased mortality,⁴⁶46 Katsanos AH, Palaiodimou L, Zand R, et al. The Impact of SARSCoV-2 on Stroke Epidemiology and Care: A Meta-Analysis. Ann Neurol 2021;89(02):380–388,⁴⁸48 Nannoni S, de Groot R, Bell S, Markus HS. Stroke in COVID-19: A systematic review and meta-analysis. Int J Stroke 2021;16(02): 137–149 while a severe infection increased the risk of CVD and ICH by ∼ 3-fold and 7-fold, respectively. The reported mortality rates for ICH and IS were 44.7% and 36.2 to 38%, respectively.⁴⁷47 Syahrul S, Maliga HA, Ilmawan M, et al. Hemorrhagic and ischemic stroke in patients with coronavirus disease 2019: incidence, risk factors, and pathogenesis - a systematic review and meta-analysis. F1000 Res 2021;10:34,⁴⁹49 Tan YK, Goh C, Leow AST, et al. COVID-19 and ischemic stroke: a systematic review and meta-summary of the literature. J Thromb Thrombolysis 2020;50(03):587–595

Although these meta-analyses did not include solely RT-PCR confirmed cases, slightly different results were found in two other meta-analyses which selected only patients confirmed by this method. Slightly higher incidence rates were found for CVD (1.5%) and ICH (0.15–0.7%),⁵⁰50 Cheruiyot I, Sehmi P, Ominde B, et al. Intracranial hemorrhage in coronavirus disease 2019 (COVID-19) patients. Neurol Sci 2021; 42(01):25–33,⁵¹51 Cagnazzo F, Arquizan C, Derraz I, et al. Neurological manifestations of patients infected with the SARS-CoV-2: a systematic review of the literature. J Neurol 2021;268(08):2656–2665 with higher mortality rates for ICH (48.6%).⁵⁰50 Cheruiyot I, Sehmi P, Ominde B, et al. Intracranial hemorrhage in coronavirus disease 2019 (COVID-19) patients. Neurol Sci 2021; 42(01):25–33 However, a lower mortality rate was reported for IS (22.8%).⁵¹51 Cagnazzo F, Arquizan C, Derraz I, et al. Neurological manifestations of patients infected with the SARS-CoV-2: a systematic review of the literature. J Neurol 2021;268(08):2656–2665 In the present review, based on data from 22 cohorts and a total of 168,703 cases, the ICH incidence was 0.26%, a rate consistent with the studies cited. The mortality rate was 44%, calculated using data from 11 cohorts including a total of 114,706 cases. When compared these with our six cases of positive RT-PCR, an even higher mortality rate of 50% was found.

Clinical-radiological aspects

In general, the most common neurological symptoms described in COVID-19 patients are headache, altered level of consciousness (ALC), dizziness, ageusia and anosmia, while other less common symptoms reported include visual impairment, CVD, seizures, occipital neuralgia, ataxia, tremor, and tics.⁴4 Mao L, Jin H, Wang M, et al. Neurologic Manifestations of Hospitalized Patients With Coronavirus Disease 2019 in Wuhan, China. JAMA Neurol 2020;77(06):683–690,⁵5 Tawakul AA, Alharbi AH, Basahal AM, et al. Neurological Symptoms and Complications of COVID-19 Among Patients in a Tertiary Hospital in Saudi Arabia. Cureus 2021;13(11):e19200,²⁷27 Kvernland A, Kumar A, Yaghi S, et al. Anticoagulation use and Hemorrhagic Stroke in SARS-CoV-2 Patients Treated at a New York Healthcare System. Neurocrit Care 2021;34(03):748–759 Severe infections were more likely in the presence of CVD and ALC²⁷27 Kvernland A, Kumar A, Yaghi S, et al. Anticoagulation use and Hemorrhagic Stroke in SARS-CoV-2 Patients Treated at a New York Healthcare System. Neurocrit Care 2021;34(03):748–759 and to be reported in hypertensive patients, who were older, had fewer typical symptoms, and were more likely to develop neurological manifestations, especially acute CVD.⁴4 Mao L, Jin H, Wang M, et al. Neurologic Manifestations of Hospitalized Patients With Coronavirus Disease 2019 in Wuhan, China. JAMA Neurol 2020;77(06):683–690

Several of the articles reported the time between admission and neuroimaging, with mean values ranging from 11 to 29 days.²²22 Migdady I, Shoskes A, Hasan LZ, et al. Timing of Acute Stroke in COVID-19-A Health System Registry Study. Neurohospitalist 2021;11(04):285–294,²⁶26 Hernández-Fernández F, Sandoval Valencia H, Barbella-Aponte RA, et al. Cerebrovascular disease in patients with COVID-19: neuroimaging, histological and clinical description. Brain 2020; 143(10):3089–3103,²⁸28 Melmed KR, Cao M, Dogra S, et al. Risk factors for intracerebral hemorrhage in patients with COVID-19. J Thromb Thrombolysis 2021;51(04):953–960,⁵²52 Nawabi J, Morotti A, Wildgruber M, et al. Clinical and imaging characteristics in patients with SARS-CoV-2 infection and acute intracranial hemorrhage. J Clin Med 2020;9(08):1–15 The interval between the onset of symptoms and diagnosis was similar, lying within the range 2 to 29 days.¹⁹19 Rothstein A, Oldridge O, Schwennesen H, Do D, Cucchiara BL. Acute Cerebrovascular Events in Hospitalized COVID-19 Patients. Stroke 2020;51(09):e219–e222,²⁴24 Pavlov V, Beylerli O, Gareev I, Torres Solis LF, Solís Herrera A, Aliev G. COVID-19-Related Intracerebral Hemorrhage. Front Aging Neurosci 2020;12:600172,²⁷27 Kvernland A, Kumar A, Yaghi S, et al. Anticoagulation use and Hemorrhagic Stroke in SARS-CoV-2 Patients Treated at a New York Healthcare System. Neurocrit Care 2021;34(03):748–759,²⁹29 Abbas R, El Naamani K, Sweid A, et al. Intracranial Hemorrhage in Patients with Coronavirus Disease 2019 (COVID-19): A Case Series. World Neurosurg 2021;154:e473–e480,⁵²52 Nawabi J, Morotti A, Wildgruber M, et al. Clinical and imaging characteristics in patients with SARS-CoV-2 infection and acute intracranial hemorrhage. J Clin Med 2020;9(08):1–15

53 Büttner L, Bauknecht HC, Fleckenstein FN, et al. Neuroimaging Findings in Conjunction with Severe COVID-19. Röfo Fortschr Geb Röntgenstr Neuen Bildgeb Verfahr 2021;193(07):822–829

54 Shahjouei S, Naderi S, Li J, et al. Risk of stroke in hospitalized SARSCoV-2 infected patients: A multinational study. EBioMedicine 2020;59:102939-⁵⁵55 Cezar-Junior AB, Faquini IV, Silva JLJ, et al. Subarachnoid hemorrhage and COVID-19: Association or coincidence? Medicine (Baltimore) 2020;99(51):e23862 Acute stroke signs were the initial manifestation of COVID-19 in only 11 to 44% of admissions.²⁶26 Hernández-Fernández F, Sandoval Valencia H, Barbella-Aponte RA, et al. Cerebrovascular disease in patients with COVID-19: neuroimaging, histological and clinical description. Brain 2020; 143(10):3089–3103,²⁹29 Abbas R, El Naamani K, Sweid A, et al. Intracranial Hemorrhage in Patients with Coronavirus Disease 2019 (COVID-19): A Case Series. World Neurosurg 2021;154:e473–e480,³²32 Mousa-Ibrahim F, Berg S, Od TPDetola O, Teitcher M, Ruland S. Intracranial Hemorrhage in Hospitalized SARS-CoV-2 Patients: A Case Series. J Stroke Cerebrovasc Dis 2021;30(01):105428,⁴⁴44 Jain R, Young M, Dogra S, et al. COVID-19 related neuroimaging findings: A signal of thromboembolic complications and a strong prognostic marker of poor patient outcome. J Neurol Sci 2020; 414:116923,⁵⁰50 Cheruiyot I, Sehmi P, Ominde B, et al. Intracranial hemorrhage in coronavirus disease 2019 (COVID-19) patients. Neurol Sci 2021; 42(01):25–33,⁵²52 Nawabi J, Morotti A, Wildgruber M, et al. Clinical and imaging characteristics in patients with SARS-CoV-2 infection and acute intracranial hemorrhage. J Clin Med 2020;9(08):1–15,⁵⁴54 Shahjouei S, Naderi S, Li J, et al. Risk of stroke in hospitalized SARSCoV-2 infected patients: A multinational study. EBioMedicine 2020;59:102939,⁵⁶56 Mishra S, Choueka M, Wang Q, et al. Intracranial Hemorrhage in COVID-19 Patients. J Stroke Cerebrovasc Dis 2021;30(04):105603 Our 6 cases are in agreement with the literature as presenting a 10 days median time and 33% of neurologic symptoms onset. At admission, the main neurologic sign was the depressed level of conscience, and the NIHSS ranged from 4 to 12 points.

Despite a wide variety of radiological findings in hospitalized cases (19), it is uncommon for patients to be diagnosed with COVID-19 using brain magnetic resonance imaging (MRI). Microhemorrhages, IS and ICHs are the most prevalent presentations. Other less common findings include hypoxic anoxic brain injury, encephalitis, acute disseminated encephalomyelitis (ADEM), leukoencephalopathy, transient perivascular inflammation of the carotid artery syndrome (TIPIC), and posterior reversible encephalopathy syndrome (PRES).⁶6 Chowdhary A, Subedi R, Tandon M, et al. Relevance and clinical significance of magnetic resonance imaging of neurological manifestations in covid-19: A systematic review of case reports and case series. Vol. 10, Brain Sciences MDPI AG; 2020:1–15

7 Mogensen MA, Wangaryattawanich P, Hartman J, Filippi CG, Hippe DS, Cross NMRSNA COVID-19 task force. Special report of the RSNA COVID-19 task force: systematic review of outcomes associated with COVID-19 neuroimaging findings in hospitalized patients. Br J Radiol 2021;94(1127):20210149-⁸8 Mahammedi A, Ramos A, Bargalló N, et al. Brain and lung imaging correlation in patients with COVID-19: Could the severity of lung disease reflect the prevalence of acute abnormalities on neuroimaging? A global multicenter observational study. AJNR Am J Neuroradiol 2021;42(06):1008–1016,⁴⁴44 Jain R, Young M, Dogra S, et al. COVID-19 related neuroimaging findings: A signal of thromboembolic complications and a strong prognostic marker of poor patient outcome. J Neurol Sci 2020; 414:116923,⁵³53 Büttner L, Bauknecht HC, Fleckenstein FN, et al. Neuroimaging Findings in Conjunction with Severe COVID-19. Röfo Fortschr Geb Röntgenstr Neuen Bildgeb Verfahr 2021;193(07):822–829,⁵⁷57 Sawlani V, Scotton S, Nader K, et al. COVID-19-related intracranial imaging findings: a large single-centre experience. Clin Radiol 2021;76(02):108–116,⁵⁸58 Choi Y, Lee MK. Neuroimaging findings of brain MRI and CT in patients with COVID-19: A systematic review and meta-analysis. Eur J Radiol 2020;133:109393

The ICH group had the highest mortality rate,⁷7 Mogensen MA, Wangaryattawanich P, Hartman J, Filippi CG, Hippe DS, Cross NMRSNA COVID-19 task force. Special report of the RSNA COVID-19 task force: systematic review of outcomes associated with COVID-19 neuroimaging findings in hospitalized patients. Br J Radiol 2021;94(1127):20210149,⁴⁴44 Jain R, Young M, Dogra S, et al. COVID-19 related neuroimaging findings: A signal of thromboembolic complications and a strong prognostic marker of poor patient outcome. J Neurol Sci 2020; 414:116923 followed by patients with leukoencephalopathy and IS, whereas patients with microhemorrhages or encephalitis as sole neuroimaging findings had the lowest mortality rates.⁷7 Mogensen MA, Wangaryattawanich P, Hartman J, Filippi CG, Hippe DS, Cross NMRSNA COVID-19 task force. Special report of the RSNA COVID-19 task force: systematic review of outcomes associated with COVID-19 neuroimaging findings in hospitalized patients. Br J Radiol 2021;94(1127):20210149 Patients in intensive care unit (ICU) had significantly higher incidences of cerebral microhemorrhages and encephalitis/encephalopathy.⁵⁸58 Choi Y, Lee MK. Neuroimaging findings of brain MRI and CT in patients with COVID-19: A systematic review and meta-analysis. Eur J Radiol 2020;133:109393

COVID-19 patients are also at a higher risk for hemorrhagic conversion of their stroke, accompanied by an increased mortality rate.²³23 Siegler JE, Cardona P, Arenillas JF, et al. Cerebrovascular events and outcomes in hospitalized patients with COVID-19: The SVIN COVID-19 Multinational Registry. Int J Stroke 2021;16(04): 437–447,³³33 Ramos AD, Koyfman F, Byrns K, et al. Characterization of Hemorrhagic and Ischemic Stroke in a Diverse Cohort of COVID-19 Patients. Neurohospitalist 2021;11(04):295–302 Nonetheless, multicompartmental hemorrhage is the ICH subtype with the highest mortality rate, followed by MFH presentations, while SDH had the lowest mortality rate.¹⁷17 Altschul DJ, Unda SR, de La Garza Ramos R, et al. Hemorrhagic presentations of COVID-19: Risk factors for mortality. Clin Neurol Neurosurg 2020;198:106112

Considering patients without COVID-19, lobar hemorrhages are often associated with structural changes such as cerebral amyloid angiopathy, arteriovenous malformations or brain tumors.⁵⁹59 de Oliveira Manoel AL, Goffi A, Zampieri FG, et al. The critical care management of spontaneous intracranial hemorrhage: a contemporary review. Crit Care 2016;20(01):272 Independent associated risk factors were anticoagulation, a prior history of IS and APOE e2 or e4 genotype, which had a specific association with lobar ICH.⁶⁰60 Martini SR, Flaherty ML, Brown WM, et al. Risk factors for intracerebral hemorrhage differ according to hemorrhage location. Neurology 2012;79(23):2275–2282

Hypertension is the leading attributable risk of non-lobar ICH, followed by prior history of IS and anticoagulation. Interestingly, hypercholesterolemia was less frequent in non-lobar ICH cases.⁶⁰60 Martini SR, Flaherty ML, Brown WM, et al. Risk factors for intracerebral hemorrhage differ according to hemorrhage location. Neurology 2012;79(23):2275–2282 The most common locations of hypertensive ICH are the basal ganglia (caudate nucleus and putamen), thalamus, cerebellum, midbrain, and pons.⁵⁹59 de Oliveira Manoel AL, Goffi A, Zampieri FG, et al. The critical care management of spontaneous intracranial hemorrhage: a contemporary review. Crit Care 2016;20(01):272,⁶⁰60 Martini SR, Flaherty ML, Brown WM, et al. Risk factors for intracerebral hemorrhage differ according to hemorrhage location. Neurology 2012;79(23):2275–2282

The results of the present review revealed a predominance of hypertension over DM2, dyslipidemia, and other comorbidities. Nevertheless, a distinct proportion of IPH was found, whereas patients had predominantly lobar locations (32%) as opposed to non-lobar (24%). In addition to the association with lobar ICH and ApoE e4e4 allele, recent findings suggest an increased risk of severe COVID-19 infection in this population, independent of preexisting dementia, hypertension, and DM2.⁶¹61 Kuo CL, Pilling LC, Atkins JL, et al. APOE e4 genotype predicts severe COVID-19 in the UK biobank community cohort. Vol. 75, Journals of Gerontology - Series A Biological Sciences and Medical Sciences Oxford University Press; 2020:2231–2232,⁶²62 Kurki SN, Kantonen J, Kaivola K, et al; FinnGen. APOE ε4 associates with increased risk of severe COVID-19, cerebral microhaemorrhages and post-COVID mental fatigue: a Finnish biobank, autopsy and clinical study. Acta Neuropathol Commun 2021;9(01):199 APOE ε4 carriers also present an increased susceptibility to SARS-CoV-2 infection with higher serum indicators of inflammation.⁶³63 Zhang H, Shao L, Lin Z, et al. APOE interacts with ACE2 inhibiting SARS-CoV-2 cellular entry and inflammation in COVID-19 patients. Signal Transduct Target Ther 2022;7(01):261https://www.nature.com/articles/s41392-022-01118-4 [Internet]
https://www.nature.com/articles/s41392-0...

Our case series had an expected predominance of hypertension as comorbidity, considering that all the intraparenchymal hemorrhages were in lobar locations and 40% in non-lobar. Therefore, these findings are consistent with the literature evidence found in this review.

Severe acute respiratory syndrome coronavirus 2-infected stroke patients exhibited particular clinical aspects compared with non-infected patients. The infection was associated with a higher prevalence of younger patients, hemorrhagic conversion of IS,³³33 Ramos AD, Koyfman F, Byrns K, et al. Characterization of Hemorrhagic and Ischemic Stroke in a Diverse Cohort of COVID-19 Patients. Neurohospitalist 2021;11(04):295–302 severe NIHSS scores, elevated D-dimer levels,²⁶26 Hernández-Fernández F, Sandoval Valencia H, Barbella-Aponte RA, et al. Cerebrovascular disease in patients with COVID-19: neuroimaging, histological and clinical description. Brain 2020; 143(10):3089–3103,³³33 Ramos AD, Koyfman F, Byrns K, et al. Characterization of Hemorrhagic and Ischemic Stroke in a Diverse Cohort of COVID-19 Patients. Neurohospitalist 2021;11(04):295–302,⁶⁴64 Dhamoon MS, Thaler A, Gururangan K, et al; Mount Sinai Stroke Investigators Acute Cerebrovascular Events With COVID-19 Infection. Stroke 2021;52(01):48–56 thrombocytopenia,³³33 Ramos AD, Koyfman F, Byrns K, et al. Characterization of Hemorrhagic and Ischemic Stroke in a Diverse Cohort of COVID-19 Patients. Neurohospitalist 2021;11(04):295–302,⁴³43 Katz JM, Libman RB, Wang JJ, et al. Cerebrovascular Complications of COVID-19. Stroke 2020;51(09):e227–e231,⁶⁴64 Dhamoon MS, Thaler A, Gururangan K, et al; Mount Sinai Stroke Investigators Acute Cerebrovascular Events With COVID-19 Infection. Stroke 2021;52(01):48–56 elevated PTT,⁶⁴64 Dhamoon MS, Thaler A, Gururangan K, et al; Mount Sinai Stroke Investigators Acute Cerebrovascular Events With COVID-19 Infection. Stroke 2021;52(01):48–56 elevated INR, and in-hospital stroke.⁴³43 Katz JM, Libman RB, Wang JJ, et al. Cerebrovascular Complications of COVID-19. Stroke 2020;51(09):e227–e231

Considering only ICH, COVID-19 patients were younger with higher rates of malignancies,²⁵25 Qureshi AI, BaskettWI, Huang W, et al. Intracerebral Hemorrhage and Coronavirus Disease 2019 in a Cohort of 282,718Hospitalized Patients. Neurocrit Care 2022;36(01):259–265 elevated INR, PTT, and fibrinogen levels, yet decreased frequency of hypertension.²⁷27 Kvernland A, Kumar A, Yaghi S, et al. Anticoagulation use and Hemorrhagic Stroke in SARS-CoV-2 Patients Treated at a New York Healthcare System. Neurocrit Care 2021;34(03):748–759 No significant changes were reported for other risk factors, such as DM2, dyslipidemia, smoking, ischemic heart disease, or atrial fibrillation.²⁰20 John S, Hussain SI, Piechowski-Jozwiak B, et al. Clinical characteristics and admission patterns of stroke patients during the COVID 19 pandemic: A single center retrospective, observational study from the Abu Dhabi, United Arab Emirates. Clin Neurol Neurosurg 2020;199:106227,²⁵25 Qureshi AI, BaskettWI, Huang W, et al. Intracerebral Hemorrhage and Coronavirus Disease 2019 in a Cohort of 282,718Hospitalized Patients. Neurocrit Care 2022;36(01):259–265

26 Hernández-Fernández F, Sandoval Valencia H, Barbella-Aponte RA, et al. Cerebrovascular disease in patients with COVID-19: neuroimaging, histological and clinical description. Brain 2020; 143(10):3089–3103-²⁷27 Kvernland A, Kumar A, Yaghi S, et al. Anticoagulation use and Hemorrhagic Stroke in SARS-CoV-2 Patients Treated at a New York Healthcare System. Neurocrit Care 2021;34(03):748–759 These patients also had more severe NIHSS and ICH scores at admission.²⁶26 Hernández-Fernández F, Sandoval Valencia H, Barbella-Aponte RA, et al. Cerebrovascular disease in patients with COVID-19: neuroimaging, histological and clinical description. Brain 2020; 143(10):3089–3103,²⁷27 Kvernland A, Kumar A, Yaghi S, et al. Anticoagulation use and Hemorrhagic Stroke in SARS-CoV-2 Patients Treated at a New York Healthcare System. Neurocrit Care 2021;34(03):748–759

Although these cases present with higher median neutrophil-to-lymphocyte ratios, there was no significant difference when compared with control groups.²⁷27 Kvernland A, Kumar A, Yaghi S, et al. Anticoagulation use and Hemorrhagic Stroke in SARS-CoV-2 Patients Treated at a New York Healthcare System. Neurocrit Care 2021;34(03):748–759

The comparison between COVID-19 cases with and without ICH yielded more discrepant results. Those with hemorrhagic events were older and had higher rates of prior stroke, hypertension, DM2, dyslipidemia, congestive heart failure, ischemic heart disease, and smoking,²⁵25 Qureshi AI, BaskettWI, Huang W, et al. Intracerebral Hemorrhage and Coronavirus Disease 2019 in a Cohort of 282,718Hospitalized Patients. Neurocrit Care 2022;36(01):259–265,⁵⁴54 Shahjouei S, Naderi S, Li J, et al. Risk of stroke in hospitalized SARSCoV-2 infected patients: A multinational study. EBioMedicine 2020;59:102939 but a lower rate of atrial fibrillation²⁸28 Melmed KR, Cao M, Dogra S, et al. Risk factors for intracerebral hemorrhage in patients with COVID-19. J Thromb Thrombolysis 2021;51(04):953–960 and thrombocytopenia.⁵⁴54 Shahjouei S, Naderi S, Li J, et al. Risk of stroke in hospitalized SARSCoV-2 infected patients: A multinational study. EBioMedicine 2020;59:102939 When considering microbleeds alone, the only significant increase was in the rate of disturbance of consciousness prior to MRI, severity of lung computed tomography (CT), days of intubation, and duration of hospital or ICU stay.¹⁸18 Lersy F, Willaume T, Brisset JC, et al. Critical illness-associated cerebral microbleeds for patientswith severe COVID-19: etiologic hypotheses. J Neurol 2021;268(08):2676–2684

Anticoagulant use

Cohort studies have shown conflicting data on the risk of ICH while in use of therapeutic anticoagulation among patients with and without COVID-19. Some studies report no increased risk of bleeding or mortality,²⁵25 Qureshi AI, BaskettWI, Huang W, et al. Intracerebral Hemorrhage and Coronavirus Disease 2019 in a Cohort of 282,718Hospitalized Patients. Neurocrit Care 2022;36(01):259–265,²⁶26 Hernández-Fernández F, Sandoval Valencia H, Barbella-Aponte RA, et al. Cerebrovascular disease in patients with COVID-19: neuroimaging, histological and clinical description. Brain 2020; 143(10):3089–3103,³³33 Ramos AD, Koyfman F, Byrns K, et al. Characterization of Hemorrhagic and Ischemic Stroke in a Diverse Cohort of COVID-19 Patients. Neurohospitalist 2021;11(04):295–302 while others showed a 2 to 7-fold increase in risk of hemorrhagic events²⁷27 Kvernland A, Kumar A, Yaghi S, et al. Anticoagulation use and Hemorrhagic Stroke in SARS-CoV-2 Patients Treated at a New York Healthcare System. Neurocrit Care 2021;34(03):748–759,²⁸28 Melmed KR, Cao M, Dogra S, et al. Risk factors for intracerebral hemorrhage in patients with COVID-19. J Thromb Thrombolysis 2021;51(04):953–960 and a 13-fold higher mortality risk.²⁷27 Kvernland A, Kumar A, Yaghi S, et al. Anticoagulation use and Hemorrhagic Stroke in SARS-CoV-2 Patients Treated at a New York Healthcare System. Neurocrit Care 2021;34(03):748–759

In the current review, the use of anticoagulation was reported in 43.3% of the 385 patients before diagnosis of ICH, of which 161 patients (47.3%) used therapeutic doses. The prevalence of anticoagulation in cohorts was higher in patients with SAH (86%), followed by MFH (82%), and lower in those with SDH (29%). Some cohort studies reported the use of anticoagulants in 16 to 100% of patients.¹⁷17 Altschul DJ, Unda SR, de La Garza Ramos R, et al. Hemorrhagic presentations of COVID-19: Risk factors for mortality. Clin Neurol Neurosurg 2020;198:106112

18 Lersy F, Willaume T, Brisset JC, et al. Critical illness-associated cerebral microbleeds for patientswith severe COVID-19: etiologic hypotheses. J Neurol 2021;268(08):2676–2684

19 Rothstein A, Oldridge O, Schwennesen H, Do D, Cucchiara BL. Acute Cerebrovascular Events in Hospitalized COVID-19 Patients. Stroke 2020;51(09):e219–e222-²⁰20 John S, Hussain SI, Piechowski-Jozwiak B, et al. Clinical characteristics and admission patterns of stroke patients during the COVID 19 pandemic: A single center retrospective, observational study from the Abu Dhabi, United Arab Emirates. Clin Neurol Neurosurg 2020;199:106227,²²22 Migdady I, Shoskes A, Hasan LZ, et al. Timing of Acute Stroke in COVID-19-A Health System Registry Study. Neurohospitalist 2021;11(04):285–294,²⁴24 Pavlov V, Beylerli O, Gareev I, Torres Solis LF, Solís Herrera A, Aliev G. COVID-19-Related Intracerebral Hemorrhage. Front Aging Neurosci 2020;12:600172

25 Qureshi AI, BaskettWI, Huang W, et al. Intracerebral Hemorrhage and Coronavirus Disease 2019 in a Cohort of 282,718Hospitalized Patients. Neurocrit Care 2022;36(01):259–265

26 Hernández-Fernández F, Sandoval Valencia H, Barbella-Aponte RA, et al. Cerebrovascular disease in patients with COVID-19: neuroimaging, histological and clinical description. Brain 2020; 143(10):3089–3103

27 Kvernland A, Kumar A, Yaghi S, et al. Anticoagulation use and Hemorrhagic Stroke in SARS-CoV-2 Patients Treated at a New York Healthcare System. Neurocrit Care 2021;34(03):748–759-²⁸28 Melmed KR, Cao M, Dogra S, et al. Risk factors for intracerebral hemorrhage in patients with COVID-19. J Thromb Thrombolysis 2021;51(04):953–960,³³33 Ramos AD, Koyfman F, Byrns K, et al. Characterization of Hemorrhagic and Ischemic Stroke in a Diverse Cohort of COVID-19 Patients. Neurohospitalist 2021;11(04):295–302 The main indication was for the hypercoagulability of patients with COVID-19, expressed by high levels of D-dimer.¹⁷17 Altschul DJ, Unda SR, de La Garza Ramos R, et al. Hemorrhagic presentations of COVID-19: Risk factors for mortality. Clin Neurol Neurosurg 2020;198:106112,²⁷27 Kvernland A, Kumar A, Yaghi S, et al. Anticoagulation use and Hemorrhagic Stroke in SARS-CoV-2 Patients Treated at a New York Healthcare System. Neurocrit Care 2021;34(03):748–759,⁶⁵65 Dogra S, Jain R, Cao M, et al. Hemorrhagic stroke and anticoagulation in COVID-19. J Stroke Cerebrovasc Dis 2020;29(08): 104984 Of all the cohort and case series studies reviewed, alterations in D-dimer were observed in 13 studies, with values ranging from 231 ng/ml to 117,608 ng/mL. The mean value of 10 studies was ∼ 2,912 ng/ml.

Pathophysiology of ICH in COVID-19 infection

The coronavirus, akin to other respiratory viruses, has neurotropism and the ability to invade the CNS in two ways: hematogenous and retrograde neuronal pathways. This ability to infect neurons from the olfactory bulb can also explain complaints of hyposmia and anosmia. The hematogenous route is identified as the main form of CNS infection, since the virus can infect endothelial capillary cells in the brain or infect leukocytes. Additionally, similarly to SARS-CoV, SARS-CoV-2 exploits the ACE2 receptor for cell entry.¹⁴14 Wang Z, Yang Y, Liang X, et al. COVID-19 Associated Ischemic Stroke and Hemorrhagic Stroke: Incidence, Potential Pathological Mechanism, and Management. Front Neurol 2020;11:571996,⁶⁶66 Paniz-Mondolfi A, Bryce C, Grimes Z, et al. Central nervous system involvement by severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2). J Med Virol 2020;92(07):699–702

ACE2 (is a critical enzyme in the renin-angiotensin-aldosterone (RAAS) system that regulates blood pressure, fluid and electrolyte balance, and vascular resistance. This enzyme is extensively expressed in alveolar epithelial cells (type 2 pneumocytes), oral and esophageal mucosa, as well as in vascular endothelial cells, smooth muscle, glial cells, and in some neurons, including those in the cardiorespiratory center of the brainstem.¹¹11 Baig AM, Khaleeq A, Ali U, Syeda H. Evidence of the COVID-19 Virus Targeting the CNS: Tissue Distribution, Host-Virus Interaction, and Proposed Neurotropic Mechanisms. ACS Chem Neurosci 2020;11(07):995–998,¹⁴14 Wang Z, Yang Y, Liang X, et al. COVID-19 Associated Ischemic Stroke and Hemorrhagic Stroke: Incidence, Potential Pathological Mechanism, and Management. Front Neurol 2020;11:571996,⁶⁷67 Wang H, Tang X, Fan H, et al. Potential mechanisms of hemorrhagic stroke in elderly COVID-19 patients. Aging (Albany NY) 2020;12(11):10022–10034

Severe acute respiratory syndrome coronavirus 2 infection in humans is mediated by S (spike) glycoprotein binding, by the receptor-binding domain (RBD) to ACE2 receptors in host cells, which leads to downregulation of ACE2 expression. This negative regulation during SARS-CoV-2 infection can increase serum levels of angiotensin II, causing endothelial function impairment and blood pressure dysregulation. Therefore, blood pressure fluctuations with an increased risk of hemorrhagic cerebrovascular events can occur.¹¹11 Baig AM, Khaleeq A, Ali U, Syeda H. Evidence of the COVID-19 Virus Targeting the CNS: Tissue Distribution, Host-Virus Interaction, and Proposed Neurotropic Mechanisms. ACS Chem Neurosci 2020;11(07):995–998,¹⁴14 Wang Z, Yang Y, Liang X, et al. COVID-19 Associated Ischemic Stroke and Hemorrhagic Stroke: Incidence, Potential Pathological Mechanism, and Management. Front Neurol 2020;11:571996

The affinity of the SARS-CoV-2 spike protein to ACE2 receptors in brain capillary endothelium can also cause direct vascular injury. The explanation for this involves the process of binding of viral particles by the endothelial cells and, subsequently, damage to the endothelial lining that can cause ruptures and bleeding. This same process can occur within neurons from the viral invasion of the CNS.¹¹11 Baig AM, Khaleeq A, Ali U, Syeda H. Evidence of the COVID-19 Virus Targeting the CNS: Tissue Distribution, Host-Virus Interaction, and Proposed Neurotropic Mechanisms. ACS Chem Neurosci 2020;11(07):995–998,⁶⁷67 Wang H, Tang X, Fan H, et al. Potential mechanisms of hemorrhagic stroke in elderly COVID-19 patients. Aging (Albany NY) 2020;12(11):10022–10034

There is a release of cytokines and proteases that accompanies the immune response to SARS-CoV-2 infection, involving massively increased levels of interleukin 6 (IL-6), IL-7, IL-10, IL-1β, interferon-gamma (IFN) -γ), and tumor necrosis factor α (TNF-α), while there is a reduction in CD4 + and CD8 + T cells, indicating that the cytokine storm attenuates adaptive immunity against SARS-CoV infection.¹³13 Pedersen SF, Ho YC. SARS-CoV-2: a storm is raging. J Clin Invest 2020;130(05):2202–2205,⁶⁸68 Perrin P, Collongues N, Baloglu S, et al. Cytokine release syndrome-associated encephalopathy in patients with COVID-19. Eur J Neurol 2021;28(01):248–258 In critically-ill patients with COVID-19, higher serum levels of inflammatory markers (e.g., C-reactive protein and D-dimers) and an increase in neutrophil-lymphocyte ratio can be seen, also present in the inflammatory process of ICH.²⁷27 Kvernland A, Kumar A, Yaghi S, et al. Anticoagulation use and Hemorrhagic Stroke in SARS-CoV-2 Patients Treated at a New York Healthcare System. Neurocrit Care 2021;34(03):748–759,⁶⁹69 Zhang F, Ren Y, Shi Y, et al. Predictive ability of admission neutrophil to lymphocyte ratio on short-term outcome in patients with spontaneous cerebellar hemorrhage. Medicine (Baltimore) 2019;98(25):e16120,⁷⁰70 Lattanzi S, di Napoli M, Ricci S, Divani AA. Matrix Metalloproteinases in Acute Intracerebral Hemorrhage. Vol. 17, Neurotherapeutics Springer; 2020:484–496

The cytokine storm usually starts in the second week of infection, with the activation of macrophages, dendritic cells, other immune cells, and subsequent massive release of proinflammatory cytokines.⁶⁸68 Perrin P, Collongues N, Baloglu S, et al. Cytokine release syndrome-associated encephalopathy in patients with COVID-19. Eur J Neurol 2021;28(01):248–258 Consequently, via a mechanism that is still unclear, changes in the permeability of the BBB can be impaired, facilitating the influx of inflammatory molecules to activate C macrophages and microglia. Ultimately, these cells become hyper-activated and start producing their own set of inflammatory molecules, which can lead to cerebral edema and even hemorrhagic events.⁵⁶56 Mishra S, Choueka M, Wang Q, et al. Intracranial Hemorrhage in COVID-19 Patients. J Stroke Cerebrovasc Dis 2021;30(04):105603,⁶⁸68 Perrin P, Collongues N, Baloglu S, et al. Cytokine release syndrome-associated encephalopathy in patients with COVID-19. Eur J Neurol 2021;28(01):248–258

Thus, BBB breakdown is a possible additional mechanism for several cerebrovascular events associated with this infection, such as hemorrhagic transformation of IS, ICHs, and cases of PRES reported in some patients with COVID-19.⁷¹71 Dakay K, Kaur G, Mayer SA, Santarelli J, Gandhi C, Al-Mufti F. Cerebral Herniation Secondary to Stroke-Associated Hemorrhagic Transformation, Fulminant Cerebral Edema in Setting of COVID-19 Associated ARDS and Active Malignancy. J Stroke Cerebrovasc Dis 2020;29(12):105397

72 Dias DA, de Brito LA, Neves LO, Paiva RGS, Barbosa Júnior OA, Tavares-Júnior JWL. Hemorrhagic PRES: an unusual neurologic manifestation in two COVID-19 patients. Arq Neuropsiquiatr 2020;78(11):739–740-⁷³73 Princiotta Cariddi L, Tabaee Damavandi P, Carimati F, et al. Reversible Encephalopathy Syndrome (PRES) in a COVID-19 patient. J Neurol 2020;267(11):3157–3160

The binding of spike protein may also promote a downregulation of ACE 2 expression in the brain, thereby triggering an increase in local angiotensin II levels and reduction in the vasodilator heptapeptide (angiotensin 1–7). Ang 1–7 acts as a neuroprotective factor by stimulating the release of prostaglandin and nitric oxide, as well as inhibiting the growth of smooth muscle cells and action of catecholamines.⁶⁷67 Wang H, Tang X, Fan H, et al. Potential mechanisms of hemorrhagic stroke in elderly COVID-19 patients. Aging (Albany NY) 2020;12(11):10022–10034,⁷⁴74 Sweid A, Hammoud B, Bekelis K, et al. Cerebral ischemic and hemorrhagic complications of coronavirus disease 2019. Int J Stroke 2020;15(07):733–742

Patients with hypertension normally have low ACE2 expression, which is further reinforced with SARS-CoV-2 infection, increasing the risk of stroke.⁷⁵75 Wang HY, Li XL, Yan ZR, Sun XP, Han J, Zhang BW. Potential neurological symptoms of COVID-19. Ther Adv Neurol Disord 2020;13:1756286420917830 The intrinsic relationship between systolic BP variability and poor prognosis of cerebral hemorrhage should be pointed out, as a high variation in BP during the first 24 hours of admission was associated with an unfavorable hospital prognosis in patients with ICH. The lack of BP control might be explained by autonomic dysfunction, with sympathetic predominance, associated with the production of proinflammatory cytokines, hyperglycemia, and increased permeability of the BBB, which are present in SARS Cov2 infection.⁷⁵75 Wang HY, Li XL, Yan ZR, Sun XP, Han J, Zhang BW. Potential neurological symptoms of COVID-19. Ther Adv Neurol Disord 2020;13:1756286420917830,⁷⁶76 Divani AA, Liu X, Di Napoli M, et al. Blood Pressure Variability Predicts Poor In-Hospital Outcome in Spontaneous Intracerebral Hemorrhage. Stroke 2019;50(08):2023–2029

Diabetic patients with COVID-19 are at increased risk of serious complications. The possible mechanisms that lead to an increased risk of stroke in these patients include excessive proinflammatory responses and reduced ACE2 expression by advanced glycosylation, leading to increases in angiotensin I and II.⁷⁷77 Pal R, Bhansali A. COVID-19, diabetes mellitus and ACE2: The conundrum. Diabetes Res Clin Pract 2020;162:108132

Coagulation disorders may be a plausible hypothesis to explain how SARS-CoV-2 infection can induce brain hemorrhage, as patients with COVID-19 may suffer from consumption coagulopathy with prolonged prothrombin time and reduced fibrinogen, both of which also contribute to secondary cerebral hemorrhage.⁷⁵75 Wang HY, Li XL, Yan ZR, Sun XP, Han J, Zhang BW. Potential neurological symptoms of COVID-19. Ther Adv Neurol Disord 2020;13:1756286420917830

The older population has several aggravating factors for the development of intravascular hemorrhages, such as cerebral microembolism, white matter lesions, vascular basement membrane thickening, and increased BBB permeability, which promote endothelial damage, changes in elasticity, and subsequent fluctuations in blood flow and pressure causing loss of self-regulation and increase in ICH risk.⁷⁸78 Camacho E, LoPresti MA, Bruce S, et al. The role of age in intracerebral hemorrhages. J Clin Neurosci 2015;22(12): 1867–1870

Study limitations

The main limitation of this review was the lack of complete data from the majority of articles in the literature. Especially in relation to data from laboratory tests, in-hospital outcomes, and rehabilitation. Furthermore, some studies failed to report details of the statistical method, which imposed difficulty to standardize a measure of central tendency. In this way, as the COVID-19 pandemics is a recent object of study, the overall quality and details of the studies could have been compromised by the urge to provide enlightenment about clinical manifestations of COVID-19.

In conclusion, despite the unusual association, the combination of these two diseases is associated with high rates of mortality and morbidity, as well as more severe clinical-radiological presentations. Further studies are needed to provide robust evidence on the exact pathophysiology behind the occurrence of intracranial hemorrhages after COVID-19 infection.

References

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