Pressing Issues in COVID-19: Probable Cause to Seize SARS-CoV-2 for Its Preferential Involvement of Posterior Circulation Manifesting as Severe Posterior Reversible Encephalopathy Syndrome and Posterior Strokes

DISCUSSION

Our series shows a high prevalence of posterior circulation vascular events, not directly referable to a secondary cause as opposed to the heterogeneous etiology in the remaining cases. We speculate that SARS-CoV-2 may have played a role leading to acute brain injury, with a preferential involvement of the posterior circulation, which may be more susceptible to the SARS-CoV-2 infection effects.

Although SARS-CoV-2 targets primarily the lung parenchyma, earlier evidence in the literature highlighted its neurotrophic and neuroinvasive tendencies.⁶ SARS-CoV-2 invades the CNS through different pathways, from peripheral nerves, especially via the olfactory nerves, through the bloodstream by infecting endothelial cells and altering the BBB, by lymphatic pathways, and, last, by the disruption of the gastrointestinal environment, which may indirectly alter BBB integrity.⁷ SARS-CoV-2 can interact with host cells through the angiotensin-converting enzyme 2 cell membrane receptor expressed in a wide variety of cells such as airway epithelia, lung parenchyma, kidney cells, small intestine cells, as well as neurons and vascular endothelia.⁶ Once it binds to neuronal angiotensin-converting enzyme 2 receptors, it is able to activate a self-reinforcing inflammatory response through a cytokine storm, which ultimately results in irreversible neuronal damage.⁸ Angiotensin-converting en-zyme 2 receptors are expressed in cerebral endothelial cells that take part in hormone formation, the sympathoadrenal system, and vascular autoregulation.⁹ Endothelial disruption as a consequence of endotheliitis induced by SARS-CoV-2 can contribute to the pathophysiology of brain damage.⁶ Infective lymphocytic endotheliitis has been proved by postmortem analysis.¹⁰ The neuroinvasive potential is also supported by clinical experience as reported by several recent studies. For example, a Chinese study⁵ reported various manifestations of CNS involvement in 53 patients with COVID-19 in a sample of 214 patients. In another study, SARS-CoV-2 was found in the CSF in a patient diagnosed with encephalitis, therefore confirming its direct CNS invasion.¹¹ Other studies have also highlighted imaging features of COVID-19 brain involvement.^12-15

As recently described, ischemic stroke is a known complication in patients with COVID-19. In our series, we found 5 ischemic strokes of the posterior circulation in line with other studies. Mao et al⁵ described 4 cases of acute stroke, while others described the onset of acute ischemic stroke in 5 younger patients.¹⁵ Beyrouti et al¹² described 6 cases of acute stroke, 4 of which were posterior strokes. Goldberg and Goldberg¹⁶ recently showed a case of ischemic stroke with occlusion of the MCA and bilateral anterior cerebral arteries.

Ischemic stroke could be related both to the endotheliitis process¹⁰ and hypercoagulability status, which can evolve to embolism.¹⁷ Endothelium inflammation may shift vascular equilibrium toward vasoconstriction, leading to ischemia.¹⁸ We also reported 1 parieto-occipital hemorrhage, 1 case of complicated hemorrhagic PRES, and the hemorrhagic transformation of 2 ischemic strokes. Intracranial hemorrhage in patients with COVID-19 has already been reported.^5,19 In our series, we also noted 4 hemorrhagic strokes involving the anterior circulation.

One patient in our cohort presented with clinical and imaging features of a severe form of PRES. A recent case report has shown 2 cases of hemorrhagic PRES.²⁰ Our patient presented with extensive edema on a baseline CT scan with the presence of hemorrhagic lesions which is a severe and rare manifastation of PRES (Fig 2).²¹ PRES is a multifactorial clinical-radiologic entity characterized by reversible subcortical vasogenic edema. Although not completely elucidated, several pathogenetic theories entailing rapid increase of arterial blood pressure beyond the autoregulatory potential, the release of vasoconstrictors, and endogenous or exogenous stimulants in addition to T-cell-derived cytokine release converge to an abnormal activation and consequent disruption of endothelial cell homeostasis.^22,23 Moreover, infective agents promote polymorphonuclear leukocyte activation and lead to additional release of mediators, resulting in increased vessel permeability, which leads to the development of interstitial edema.²³ Most interesting, the well-known frequent association of PRES with posterior circulation involvement has been ascribed to its lack of sympathetic innervation in contrast to the anterior circulation.^22,24 We ruled out other potential PRES mimickers, such as hypoxic-ischemic encephalopathy, meningoencephalitis, and acute toxic leukoencephalopathy in light of clinical and laboratory data and imaging follow-up. The improvement of pneumonia and laboratory parameters as well as the negative results on subsequent nasopharyngeal swabs paralleled by neurologic symptom resolution may strengthen the hypothesis of SARS-CoV-2 as a primary causative agent. Therefore, endothelial dysfunction, possibly at the capillary level, set off by SARS-CoV-2 infection, may be the etiopathogenesis of PRES.

In our cohort, we found that the posterior circulation was the most common primary site of acute vascular injury. The endothelial disruption related to SARS-CoV-2 could be a common feature acting as a promoting and synergistic agent underlying the preferential involvement of the posterior circulation, presumably due to its intrinsic hemodynamic weakness compared with the anterior circulation. Further studies with larger sample sizes are needed to support our hypothesis.