Abstract
BACKGROUND AND PURPOSE: Our hypothesis is that the COVID-19 pandemic led to delayed presentations for patients with acute ischemic stroke. This study evaluates the impact of the coronavirus disease 2019 pandemic on presentation, treatment, and outcomes of patients with emergent large-vessel occlusion using data from a large health system in the Bronx, New York.
MATERIALS AND METHODS: We performed a retrospective cohort study of 2 cohorts of consecutive patients with emergent large-vessel occlusion admitted to 3 Montefiore Health System hospitals in the Bronx from January 1 to February 17, 2020, (prepandemic) and March 1 to April 17, 2020 (pandemic). We abstracted data from the electronic health records on presenting biomarker profiles, admission and postprocedural NIHSS scores, time of symptom onset, time of hospital presentation, time of start of the thrombectomy procedure, time of revascularization, presenting ASPECTS, TICI recanalization score, mRS, functional outcomes, and mortality.
RESULTS: Of 179 patients admitted with ischemic stroke during the study periods, 80 had emergent large-vessel occlusion, of whom 36 were in the pandemic group. Patients in the pandemic group were younger (66 versus 72 years, P < .061) and had lower ASPECTS (7 versus 9, P < .001) and took longer to arrive at the hospital (361 versus 152 minutes, P < .004) with no other major differences. There was a decreased rate of thrombolysis administration (22% versus 43%, P < .049) and a decreased number of patients treated with mechanical thrombectomy (33% versus 61%, P < .013).
CONCLUSIONS: The pandemic led to delays in patients arriving at hospitals, leading to decreased patients eligible for treatment, while in-hospital evaluation and treatment times remain unchanged.
ABBREVIATIONS:
- COVID-19
- coronavirus disease 2019
- ELVO
- emergent large-vessel occlusion
In March 2020, New York City became the epicenter of the coronavirus disease 2019 (COVID-19) pandemic, which disrupted regional systems of health care. The pandemic changed when and how patients presented for emergent evaluation. A recent study found a nearly 40% decrease in stroke-related imaging nationwide during the COVID-19 pandemic.1 While delays in treatment of myocardial infarction systems of care have been reported, the effect of the COVID-19 pandemic on systems of emergent large-vessel occlusion (ELVO) stroke care is unreported.2
Mechanical thrombectomy has been proved safe and effective in treating ELVO, but its success in decreasing morbidity depends on the prehospital system as well as a streamlined in-house process of care.3 Our current stroke triage process involves hospital prenotification, bypass of emergency department evaluation, direct advancement to CT scan assessment, and treatment before angiosuite arrival.
The aim of this study was to evaluate the impact of the COVID-19 pandemic on ELVO systems of care, treatment, and outcomes. We describe all cases of ELVO treated in our institution (Montefiore Health System) during the COVID-19 pandemic and compare them with those treated before the pandemic. Our hypothesis is that the COVID-19 pandemic led to delays in patients presenting to hospitals. This delay may have led to worse outcomes during the pandemic.
MATERIALS AND METHODS
Study Design and Participants
The data that support the findings of the study are available from the corresponding author on reasonable request. This retrospective cohort study included 2 cohorts of patients admitted to 3 of the hospitals in our health care network, including our comprehensive stroke center, which accepts transfers for complex cases from 8 community hospitals, from January 1 to February 17, 2020, (prepandemic) and March 1 to April 17, 2020, (pandemic). All patients diagnosed with ELVO were included. ELVO was defined as acute focal neurologic deficits with an associated occlusion of the internal carotid artery, M1 segment of the middle cerebral artery, M2 segment of the middle cerebral artery, or the basilar artery with radiologic confirmation by CTA. March 1 was the date chosen because it was the day of the first confirmed documented case in New York City. We also included patients with occlusions of the anterior cerebral artery, posterior cerebral artery, or vertebral artery and labeled them as “other” large-vessel occlusion. COVID-19 was confirmed by positive detection of Severe Acute Respiratory Syndrome coronavirus 2 RNA using real-time polymerase chain reaction assay testing performed within the hospital system or documented at an outside system before transfer. All patients presenting to our hospital during the pandemic period were tested for COVID-19 using real-time polymerase chain reaction assay testing.
This study was approved by the hospital institutional review board. Written informed consent was waived.
Case Ascertainment and Study Variables
Cases were identified through neuroradiology logs or neurologic consultation for transfers. Data abstracted from the medical records included demographics, clinical variables, laboratory values, and neuroimaging findings (initial ASPECTS, stroke treatment time points, results as they pertain to mechanical thrombectomy, outcome variables [discharge mRS 0–2], in-hospital mortality). Fourteen patients with inpatient presentation were excluded from analysis.
Statistical Analysis
We compared baseline characteristics between prepandemic and pandemic groups, performing parametric and nonparametric analyses with the t test, χ2 test, and Mann-Whitney U test as appropriate. No imputation was made for missing data. Missing data are labeled in the footnotes of the On-line Table. Main outcomes, poor outcomes (discharge mRS 3–5), and in-hospital mortality) with a χ2 test of P < .05 were analyzed through univariate and multivariate logistic regression controlling for explanatory variables. Multivariate analysis was performed with factors with P < .05 on univariate analysis controlling for explanatory variables with P < .25 on univariate analysis.
RESULTS
We found a total of 80 patients with ELVO during the entire study period, with 44 treated before and 36 during the COVID-19 pandemic. There was an 18% decrease in overall large-vessel occlusion volume during the pandemic. Pandemic patients were younger than those prepandemic (66 versus 72, P < .061); however, this difference was not significant. There was no significant difference in comorbidities or race or ethnicity between the 2 groups. In the pandemic cohort, 38.7% tested positive for COVID-19 at admission.
Compared with the prepandemic cohort, pandemic patients with ELVO presented with a lower ASPECTS score (7 versus 9, P < .001), despite no differences in occlusion location, and arrived at the hospital later (361 versus 152 minutes, P < .012). There was a significantly lower rate of thrombolysis administration (22% pandemic versus 43% prepandemic, P = .049) and a reduced proportion of patients treated with mechanical thrombectomy (33% versus 61%, P = .013). There was no significant difference in poor functional outcomes as scored using the mRS grades 3–5 (88.2% versus 69.6%, P = .08). There was no significant difference in mortality for patients with ELVO in prepandemic versus pandemic cohorts (15% versus 28.1%, P = .173) (On-line Table).
DISCUSSION
We aimed to evaluate the effect of the COVID-19 pandemic by comparing two 6-week epochs. We evaluated sociodemographic data, comorbidities, established treatment time parameters, established imaging parameters, neurologic outcomes, and mortality between the 2 groups.
Patient symptom-onset-to-hospital times more than doubled in the pandemic period, and patients presented with significantly lower ASPECTS scores. Because intravenous thrombolysis and mechanical thrombectomy have either strict time and/or neuroimaging criteria per current guidelines, delays to care have a cascading effect, as reflected in the significantly fewer pandemic patients undergoing these hyperacute stroke therapies.4 In our 2 cohorts, there was no significant difference in race, ethnicity, vascular risk factors, or comorbidities (On-line Table). There was no significant difference in where (direct to a comprehensive stroke center versus a primary stroke center) patients presented between the 2 groups.
The reasons for delays in seeking care are multifactorial. A New York statewide shelter-in-place order and widespread media coverage of overwhelmed emergency health system resources likely helped mitigate the spread of COVID-19 but may have also unintentionally led to underuse of the emergency health system for other emergencies. This finding was not unique to New York City because similar delays were seen in other areas.5⇓-7 One possibility is that patients with less severe symptoms did not seek early care; however, we did not see a significant difference in presenting NIHSS scores between the 2 groups. Other studies used last-known-well times to predict a delay of onset; this data point is often subject to miscalculation and bias. This study is the first to confirm objectively using ASPECTS that patients had a higher degree of completed infarct when presenting to the hospital during the pandemic. While delays to presentation could be the main reason for the objective difference in ASPECTS at presentation, another possibility is that the multisystem inflammatory syndrome and hypercoagulable state associated with COVID-19 create a more severe stroke syndrome at presentation.8
Our hospital continued to treat patients regardless of their COVID status on the basis of our prepandemic standards of care. This approach did not impact our in-hospital triage and treatment times. The mortality rates were higher in the pandemic cohort; however, they did not reach clinical significance. Similar smaller reviews have suggested poor outcomes for patients with stroke who arrived during the pandemic.9 Further multicenter studies are needed to confirm these findings.
The limitations of this study are its retrospective and single-center design and the sample size being small for the patients in the pandemic group.
CONCLUSIONS
Acute stroke is an example of when the COVID-19 pandemic led to “collateral damage” for noninfected patients. Awareness of this impact is a crucial first step in mitigating unintended health consequences during a massive emergency response.
Footnotes
Disclosures: David J. Altschul—UNRELATED: Consultancy: Stryker/MicroVention; Grants/Grants Pending: National Institutes of Health, Comments: R01 Subaward. Allan Brook—RELATED: Consulting Fee or Honorarium: InNeuroCo.
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References
- Received July 2, 2020.
- Accepted after revision July 27, 2020.
- © 2020 by American Journal of Neuroradiology
