Abstract
Coronavirus disease (COVID-19) was first identified in late December 2019. The disease began in Wuhan, Hubei province in China and since then it has spread quickly to many countries all over the world. COVID-19 is caused by a novel coronavirus, named severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). The virus was majorly seen to overwhelm the respiratory system with mild to severe acute respiratory syndrome considered pathognomic for the disease. However, with time a plethora of symptoms was observed in the patients infected with COVID-19 including strong evidence for neurological symptoms. Evidence suggests that the virus has both central and peripheral nervous system manifestations. Patients, particularly those who suffer from a severe illness, have a central nervous system (CNS) involvement and neurological manifestations. There is precise and targeted documentation of neurological symptoms with details of clinical, neurological, and electrophysiological findings. This review article thus gives an insight into the neuro-invasive potential of COVID-19 and discusses the possible pathogenesis.
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Introduction
There was a sudden spike in the cases of pneumonia, most of unknown etiology, in late December 2019 in Wuhan, Hubei province in China, with an epidemiological link to the Huanan Seafood Wholesale Market [1]. It appears that most of the early cases had contact history with the original seafood market suggesting animal to human transmission; however, the global spread of the disease has largely been due to human-to-human contact [2].
Initially referred to as “2019-nCoV” and “Wuhan coronavirus”, on February 11, 2020, the virus strain was officially termed "severe acute respiratory syndrome coronavirus 2" (SARS-CoV-2). However, the WHO officially renamed the disease as "coronavirus disease 2019" (COVID-19) [3].
Genomic analysis shows that COVID-19 is in the betacoronavirus (βCoV) clade as SARS‐CoV and MERS‐CoV, which also infected the human population in this century [4]. COVID-19 shares at least 70% similarity in genetic sequence to SARS-CoV. [1]. Many SARS-related coronaviruses (SARSr-CoVs) have been discovered in bats which is their natural reservoir host. A study suggests that COVID-19 is 96% identical at the whole-genome level to a bat coronavirus [2].
Initially presenting as a febrile respiratory illness, the typical clinical symptoms of COVID-19 patients are fever, dry cough, breathing difficulties (dyspnea), headache, pneumonia which may progress to respiratory failure owing to alveolar damage [2]. COVID-19 exploits the angiotensin-converting enzyme 2 (ACE2) receptor to gain entry inside the cells and hence invades the human respiratory tract due to the presence of ACE2 receptors that are present abundantly in the epithelia of the lungs [3, 5].
However, there have been reports of COVID-19 patients exhibiting only neurological symptoms as their initial symptoms, such as headache, languidness, unstable gait, and malaise [6].
There is also evidence of several neurological complications of the virus, including polyneuritis, Guillain–Barre syndrome (GBS), meningitis, encephalomyelitis, and encephalopathy [3]. In the current outbreak, a study conducted in a hospital in China involving 214 patients, reported neurological manifestations in 78 (36.4%) patients with COVID-19 [7].
There is evidence of neurological tissue expression of ACE2 receptors in the brain, detected over the glial cells and neurons, which makes them a potential target of COVID-19 [3]. Also, the neuroinvasive potential of CoVs has been previously documented for almost all the βCoVs, including SARS‐CoV, MERS‐CoV, and others [4].
To further our rationale of the neurotropic potential of the COVID-19 virus, and to summarise the neurological findings discussed in the previous studies and case reports so that a clinician can get an overview of all the previous literature by going through a single article, we aim to describe the neurological manifestations of COVID-19.
Methodology
An extensive literature search was conducted using Pubmed and Google Scholar. In both electronic databases, the following search strategy was implemented and these keywords (in the abstract) were used: 'COVID-19′ AND 'CNS' OR 'PNS' OR 'Nervous system'. The aim was to include all the various CNS and PNS findings in one document so the documents which reported similar manifestations were excluded. No specific time frame was selected, however, most of the articles were from 2020 and a few articles from previous years regarding SARS and MERS were also included. To ensure literature saturation, the reference lists of the included studies were thoroughly scanned for other relevant articles. The three authors actively participated in writing the article and then critically reviewing it at the end. The neurological manifestations discussed below are summarized in Table 1.
Central nervous system (CNS) manifestations of SARS-CoV2
Encephalitis
Encephalitis refers to inflammation of the brain parenchyma and is characterized by symptoms of headache, fever, vomiting, convulsions, and altered sensorium. The association between viral encephalitis and COVID-19 was revealed when the treatment team at Beijing Ditan Hospital detected the presence of SARS-CoV-2 in the cerebrospinal fluid (CSF) of patients diagnosed with COVID-19 [8]. The same virus was also isolated from the CSF of a patient in Japan who had clinically proven meningoencephalitis, as well as a 56-year old woman in Wuhan who was diagnosed with encephalitis, hence reiterating the association [9, 10]
Another Wuhan male was also diagnosed with encephalitis associated with SARS-CoV-2 infection based on physical evaluation of the neurological symptoms though the CSF specimen did not indicate the presence of SARS-CoV-2. The negative results are assumed to be because the dissemination of the virus is transient, and the CSF titers are too low for the virus [11].
It is believed that the presence of pro-inflammatory cytokines in the CSF increases the permeability of the blood–brain barrier and thus allows the virus to invade the CNS and produce neurological manifestations [12].
Encephalopathy
Encephalopathy is a type of reversible brain dysfunction syndrome, with no evidence of inflammation on CSF analysis, which is potentially caused by factors such as toxemia, hypoxia, and viral infection. Guo et al. mentioned that COVID-19 causes viremia and hypoxia, so it can be conjectured that COVID-19 is a potential cause of encephalopathy [8].
It was also suggested that elderly patients with pre-existing conditions, respiratory distress, and prior neurological symptoms had a higher potential of presenting with encephalopathy due to COVID-19 infection. There is evidence of a 74-year-old male patient with a past medical history of cardioembolic stroke, atrial fibrillation, chronic obstructive pulmonary disease (COPD), Parkinson's disease, and recent cellulitis that tested positive for COVID-19 and was simultaneously diagnosed with encephalopathy [13]. Another case of a 58-year-old COVID-19 positive female was diagnosed with acute necrotizing encephalopathy, the most probable cause of which was infection-induced cytokine storm [12]. Helms et al. also observed a person with electroencephalography findings consistent with encephalopathy while studying neurological signs and symptoms in COVID-19 patients [14].
Therefore, physicians should consider COVID-19 in the differential diagnosis in patients presenting with confusion, lethargy, and strange behavior.
Acute cerebrovascular disease
Out of the 37 studies used in a comparative review, 370 patients with SARS-CoV2 infection were reported to have an acute ischemic stroke or transient ischemic attack. These patients were those who already had certain co-morbidities which put them at an increased risk of thromboembolic events [15].
Cerebral hemorrhage
A 79-year-old male patient with a confirmed COVID-19 infection had presented with intracerebral hemorrhage accompanied with intraventricular and subarachnoid hemorrhage that was hypothesized to be because of dysfunction of brain ACE2 receptors which thereby led to the disruption of autoregulation and resulted in high blood pressure and arterial wall rupture [16].
The same hypothesis is further supported in another study which stated that hypertensive patients who already have reduced expression of ACE2 receptors are more prone to develop intracerebral hemorrhage when infected with SARS-CoV-2 because the latter further reduces the expression and function of ACE2 proteins [6].
A prospective study by Di Castelnuovo et al. described the relationship between intracerebral hemorrhage and elevated D-dimer levels in which he stated that D-dimers lead to fibrinolysis and a resultant hypocoaglable state which predisposes to hemorrhages [17]. Since severely ill COVID-19 patients have elevated levels of D-dimers [8], this is a plausible mechanism for the development of cerebral hemorrhages.
This endothelial rupture in cerebral arteries and capillaries occurs long before the neuronal damages and can have fatal consequences due to bleeding within the cerebral tissues [3].
Patients infected with COVID-19 sometimes suffer from coagulopathy and prolonged prothrombin time which further suggests that the virus can lead to secondary cerebral hemorrhages [18, 19].
Ischemic stroke
A report described a patient with a complaint of right limb weakness who was later diagnosed with COVID-19. It is suggested that the infection caused hypoxemia and release of inflammatory cytokines that led to the development of ischemic stroke which was causative of the right limb weakness [20].
In a study by Oxley et al. five COVID-19 positive patients who were under the age of 50 and who had no previous history of cerebrovascular accidents presented with large-vessel stroke. After excluding all other probable causes, their stroke was attributed to COVID-19 infection [21]. This suggests that middle-aged and healthy patients are at an equal risk of COVID-19 induced stroke similar to the elderly and severely ill patients.
A previous study suggests that COVID-19 infection induces a cytokine storm, which may be one of the causes for the development of CVD [22].
Moreover, severely ill patients infected with COVID-19 have elevated levels of D-dimers and a reduced platelet count which may make them more susceptible to acute CVD [8].
CVD in the form of secondary cerebral infarctions has also been reported in SARS and hence it is anticipated that the same might occur in COVID-19 infection [6].
Acute respiratory failure due to loss of brain function
Given the previous studies that report the neuro-invasive potential of COVID-19 [7], it is conjectured that the respiratory failure reported in COVID-19 patients might be due to damage of the respiratory center in the medulla as the latency period of 8 days from the first symptoms to intensive care might be enough to destroy the medullary neurons [4]. The lack of dyspnea observed in severe cases of COVID-19 patients further supports the fact that the respiratory failure is due to neuronal involvement and not merely due to viral pneumonia because the pulmonary C fibers that play a role in dyspnea are damaged due to the infection-induced cytokine storm [23].
A finding published on a patient who had a loss of involuntary control over breathing was found to be different from the acute respiratory failure reported in several patients as the former was because of neuroinvasion and not because of pneumonia and thus physicians should be able to differentiate between the neurologically affected patients and those who are devoid of any neurological manifestations [3].
However, another study states that respiratory failure is not due to brain dysfunction as the latter causes type 2 respiratory failures unlike the type 1 respiratory failure found in COVID-19 infected patients [24].
Guillain–Barre syndrome
A patient infected with COVID-19 was diagnosed with GBS and it was speculated that the viral infection had led to the development of demyelinating neuropathy. This was the first such case that came to attention [25]. Two more variants of GBS, Miller Fisher syndrome and polyneuritis cranialis, that characteristically affect the ocular muscles were further diagnosed among two patients. [26]. A literature review later presented by Ahmed I et al. also discussed many more cases of COVID-19 infected patients who developed GBS thereby proving a vivid association between COVID-19 and GBS [27].
Seizures
The presence of seizures in COVID-19 patients was first reported by Moriguchi and his colleagues. A 24-year-old male patient, who was brought to the hospital due to a convulsion followed by unconsciousness, developed transient generalized seizures. He was later diagnosed with aseptic encephalitis and his cerebrospinal fluid tested positive for SARS-CoV-2 RNA [9].
A 30-year-old female, previously in her usual healthy state was reported to present with generalized tonic–clonic seizures. According to the patient she had seizures at a frequency of five times every eight hours. She tested positive for COVID-19 using real-time PCR assay. Her brain MRI was normal. However, her symptoms improved with anticonvulsive and antiviral medications. [28]
Subclinical seizures were documented with critical illness [29]. Studies indicate that those with existing primary seizure disorder are at higher risk of seizures and status epilepticus in the setting of severe infection [30]. In their research, Zubair et al. reported a high proportion of breakthrough seizures in patients with epilepsy who developed COVID-19 [31].
Miscellaneous
A study conducted among patients in Wuhan reported neurological manifestations in 78 out of 214 patients diagnosed with COVID-19 amongst which the most common complaints were dizziness and headaches [7]. In another survey conducted among physicians in Italy, 82% of them observed neurological symptoms among COVID-19 patients amongst which the most common reported symptoms were headaches, myalgias, and taste and smell abnormalities [32].
Headache was a very frequent complaint among patients; 34% of the patients in a study in Zhejiang complained of headaches [33]. Recently, it was reported as a predominant complaint in a case series, along with fever, cough, sore throat, and breathlessness [34]. There is variation in the prevalence of headache in different reports, however, it can affect up to one-third of diagnosed patients [35].
Neurological symptoms including vomiting and delirium were also present in many patients [36]. Studies have reported that neurological symptoms are significantly more common among the more severely ill patients [7].
Ping Wu et al. reported various ocular symptoms in patients including conjunctivitis, conjunctival hyperemia, chemosis, epiphora, and increased secretions. Of the 38 clinically confirmed cases of COVID-19 in their study, 2 patients yielded positive results on RT-PCR, for SARS-CoV 2 in their conjunctival specimen [37].
Although most of the specific, as well as non-specific neurological manifestations, have been reported among the elderly population, a study in France reported four COVID-19 positive infants who presented with atypical findings such as axial hypotonia, drowsiness, and moaning [38].
Peripheral nervous system (PNS) manifestations of SARS-CoV2
Oculomotor nerve palsy
A case study revealed acute unilateral isolated oculomotor nerve palsy in a 62-year-old male who presented with a drooping left eye and diplopia. Health care providers tested him for common causes of third nerve palsy including an aneurysm, GBS, diabetes complication, tumor which were all negative. Although the typical COVID-19 symptoms of fever, cough, and dyspnea were initially absent, he eventually tested positive for the disease which led the medical team to attribute this palsy to SARS-CoV-2 infection [39].
In another case report, Dinkin et al. discussed two patients who presented with ophthalmoparesis and diplopia after experiencing COVID-19 symptoms. This provides further evidence that is supportive of the association between COVID-19 infection and oculomotor nerve palsy [40].
Olfactory and gustatory dysfunction
Many cases of altered sense of smell and taste were reported in COVID-19 patients. These include symptoms ranging from dysgeusia, dysosmia to ageusia, and anosmia. These terms refer to an altered sense of taste and smell and these symptoms have been attributed to olfactory and trigeminal nerve damage, in the form of inflammation or receptor damage, due to COVID-19 infection and also to the increased use of disinfectants by the people during the viral epidemic [41]. However, the exact mechanism of damage requires further investigation.
In a study conducted among hospitalized patients in Wuhan, the prevalence of hypogeusia and hyposmia was 5.6 and 5.1%, respectively [7].
Esmaeil et al. in their review article included evidence from various countries such as the USA, UK, Iran, Spain, Italy, China, France, Norway, Switzerland, Cuba, and Denmark. Anosmia was reported in 23 out of the 24 articles reviewed in the study and hence was the most common symptom, establishing strong evidence of a surge in olfactory abnormalities during COVID-19. This was followed by reports of hyposmia, ageusia, and dysgeusia, in order of decreasing frequency [42].
Zubair et.al in their study reported anosmia as an early symptom of COVID-19 and suggested that testing for anosmia might offer a potential early detection of COVID-19 infection [31].
Proposed mechanism of action of SARS-CoV2 infection on the nervous system
ACE 2
Perhaps this mechanism is the one that is most commonly discussed in the existing literature; ACE2 is present in many organs of the body such as vessels, brain, lungs, kidneys and has a role in regulating blood pressure by opposing the effects of ACE. ACE is an enzyme responsible for increasing angiotensin II in the body which is a vasoconstrictor, ACE2 acts by catalyzing the breakdown of angiotensin II into the vasodilators angiotensin 1–7. Hence by increasing the vasodilators and reducing the vasoconstrictors ACE2 lowers the blood pressure.
Like SARS-CoV, SARS-CoV-2 uses spike proteins present on its surface to bind with ACE2 [3]. This binding may negatively impact this blood pressure regulating mechanism and predispose the patient to cerebrovascular events (CVE) like hemorrhage and ischemic stroke. Elderly or those with co-morbid conditions like hypertension and a history of stroke are particularly at high risk of these cerebrovascular emergencies [8].
In the brain, ACE2 is found specifically in the brainstem where nuclei responsible for cardiovascular and respiratory activities are present; hence viral interaction with these can have deleterious effects on the normal physiology of both the essential functions [36, 43]. An experimental study also showed their potential presence in glial cells, and viral interaction with these may directly damage neurons [36].
ACE2 was also linked to a possible role in the anti-atherosclerosis mechanism by an experimental study conducted on rabbits [44]. So, another consequence of virus-ACE2 binding may be to disrupt this process. In congruence, a study found the levels of D-dimers to be increased in COVID-19 patients attesting to this possibility [45]. Perhaps the CVE is the aftermath of a pro-atherosclerotic state created by the virus.
More recent studies discuss ACE2 as a point of entry of the virus into the body by calling the human transmembrane serine proteases (TMRSS2 and TMPRSS4) as co-receptors which may enhance the ACE2 and spike protein fusion [46].
Neuronal pathway
According to this mechanism the SARS-CoV-2 enters peripheral nerves and travels in a trans-synaptic and retrograde fashion to invade the CNS.
The most discussed entrance seems to be through the olfactory nerve because of its unique anatomy. It is proposed that intranasal occupancy by the virus results in infection of the olfactory epithelium this is followed by a transcribrial route to reach the olfactory bulb and eventually the CNS. Studies that demonstrate the uptake of the coronaviruses (SARS and MERS) through this pathway in mice are suggestive of this pathway considering the similarities between SARS-CoV-2 and other viruses in the CoV family [37]. However, recent studies propose that the entry of the virus is not due to direct infection of all cells of olfactory epithelium but it is due to the infection of supporting, non-neuronal cells present in the epithelium which possess ACE2 and transmembrane proteases [47].
Evidence for this neuronal mechanism can be derived from studies conducted on mice in which removal of olfactory bulbs led to a decreased invasion of CNS by CoV [48, 49]. Perhaps the greatest support for this mechanism is the occurrence of dysosmia in COVID-19 affected patients [7].
In addition to the olfactory pathway, which is a well-proven one, some neurologists believe that the oculomotor, trigeminal, vagus and glossopharyngeal nerves likely serve the same purpose [37, 41]. Once inside the CNS, the virus may cause further injury by initiating demyelination and an inflammatory reaction [8].
Esposito et al. in their letter detail a mechanism that involves the gastrointestinal system. They state that the virus infects the gastrointestinal tract as the epithelium has a high expression of ACE2; from here virus may ascend to CNS via vagal afferent fibers or affect the enteric nervous system [50].
Hypoxia
This mechanism entails that viral proliferation in the lung parenchyma causes pneumonia which disturbs respiration enough to bring about a general hypoxic state in the body. An anaerobic state is induced owing to the lack of oxygen. This causes a buildup of acid in the brain which develops into cerebral edema and congestion and the resulting intracranial hypertension might be responsible for drowsiness and coma. Since COVID-19 patients often suffer from severe hypoxia, hypoxic injury is thought to be a probable cause of the neurological manifestations seen in this infection [8].
Inflammation related injury
Cytokine storm due to invasion of immune cells
It has been suggested that SARS-CoV-2 triggers a systemic inflammatory response syndrome (cytokine storm) which damages the blood–brain barrier leading to CNS infection [36].
The persistence of the CoV infection and its propensity to invade the immune cells in the brain such as macrophages, glial cells, and astrocytes leads to chronic inflammation and brain damage [8]. An experimental study confirmed that glial cells infected with HCoV liberate a variety of inflammatory factors including interleukin-6 (IL-6) [49]. In support of this, the anti-IL-6 medicine, tocilizumab, was recently approved for trial and did show some improvement in COVID-19 patients [51]. A similar infection-induced cytokine storm was associated with the development of acute necrotizing encephalopathy, discussed above. It is hypothesized that this widespread pro-inflammatory state causes damage to organs in addition to the nervous system. Muscles are specifically targeted, thereby leading to rhabdomyolysis [7, 45].
Cytokine storm due to disruption of the cholinergic pathway
Recently, a unique theory emerged involving the immune mechanism mentioned above and the cholinergic system. The study first established the importance of the cholinergic pathway in controlling inflammation and preventing an acute immune response. It stated that Acetylcholine (Ach) interacts with nicotinic acetylcholine receptor (nAChRs) α7 subunit present on macrophages and B-lymphocytes inhibiting and limiting the release of TNF and other cytokines. The authors then explained that after infection with SARS-CoV-2, cellular debris may attach to and block nAChR impeding the anti-inflammatory function. The resulting unimpeded pro-inflammatory state gives rise to the cytokine storm which leads to acute respiratory distress, coagulation disorders, and eventually multiple organ failure. Coagulation disorders occur because platelets too have the α7-AChRs.
The study further reinforces this hypothesis by laying down similarities in the amino acid sequence of SARS-CoV-2 and snake neurotoxins which also bind to nAChRs. This theory is one of its kind and should be investigated more [52].
Hematogenous
Soon after the infection, the virus disseminates throughout the body and then neurotropism may occur via the circulation. A study proposed that the presence of a virus in the circulation may result in interaction with the ACE2 receptors on the endothelium of the cerebral capillaries, this may cause viral budding which damages the endothelial linings thereby permitting entry into the CNS [3].
Another study postulates that as some pathogens target the cells of the blood like leukocytes, SARS-CoV-2 may also replicate within these cells and then be released into the blood in a larger amount. This may trigger an immune response that enables infection of CNS by damaging the blood–brain barrier [6]. This barrier is the only thing separating the blood from the CSF, hence the study claiming the presence of SARS-CoV in CSF may indicate the potential of coronaviruses to undertake this route [3].
Despite all this, a different study negated the hematogenous spread as an early and primary mechanism alleging that the previously discovered CoVs were not found in non-neuronal tissues in patients who had passed away due to the disease [4]. Given the above contradiction, further studies need to be conducted to affirm the potential of spread of SARS-CoV-2 into the CNS via the hematogenous route.
Conclusion
Clinical evidence suggests that neurological manifestations in association with COVID-19, are various and prevalent.
To justify the neurological invasion, autopsies of the COVID-19 patients must be performed. Isolates taken from neurological tissues and fluids such as glial cells, neurons, and cerebrospinal fluid, can clarify the role of COVID-19 in nervous system damage.
Patients infected with COVID- 19 have reported coagulopathy, prolonged prothrombin time, evidence of elevated levels of D-dimers, and a reduced platelet count. These changes in blood have also been witnessed with neurological manifestations and need to be studied in more detail to establish their correlation with the severity of symptoms.
As suggested by Abdul Mannan Baig et al., the study of the viral isolates in the area close to the olfactory bulb will help establish whether dysosmia and dysgeusia are due to the route of invasion (transcribrial), olfactory and trigeminal nerve damage, or from the increased use of disinfectants by the people during the viral epidemic as stated in some studies [3].
With reports of type 1 respiratory failure found in COVID-19 infected patients, there is also existing literature on respiratory failure due to breathing problems arising from brain damage in COVID-19 positive individuals [24]. Due to the above-mentioned contradiction, future studies must be conducted to confirm whether the acute respiratory failure is due to brain dysfunction or due to end-stage viral pneumonia.
With significant reports of neurological symptoms in the COVID-19 outbreak, there is an urgent need to understand the neurotropic potential of the COVID-19 virus. Healthcare providers should be on the lookout for neurological signs and symptoms in all patients, belonging to all age groups. Based on the severity of symptoms and the site of damage, treatment modalities must be chosen for the patient's benefit and to reduce the burden on the health care system.
Data availability
Not applicable.
Abbreviations
- ACE:
-
Angiotensin-converting enzyme
- ACE2:
-
Angiotensin-converting enzyme 2
- Ach:
-
Acetylcholine
- AIDP:
-
Acute inflammatory demyelinating neuropathy
- AMAN:
-
Acute motor axonal neuropathy
- CNS:
-
Central nervous system
- COPD:
-
Chronic obstructive pulmonary disease
- CoV:
-
Coronavirus
- COVID-19:
-
Coronavirus disease 2019
- CoVs:
-
Coronaviruses
- CSF:
-
Cerebrospinal fluid
- CVD:
-
Cerebrovascular disease
- CVE:
-
Cerebrovascular event
- EEG:
-
Electroencephalogram
- GBS:
-
Guillain Barre Syndrome
- HCoV:
-
Human coronavirus
- IL-6:
-
Interleukin-6
- MERS:
-
Middle East Respiratory Syndrome
- MERS-CoV:
-
Middle East Respiratory Syndrome Coronavirus
- nAChR:
-
Nicotinic acetylcholine receptor
- PNS:
-
Peripheral nervous system
- RNA:
-
Ribonucleic acid
- SARS:
-
Severe Acute Respiratory Syndrome
- SARS-CoV-2:
-
Severe Acute Respiratory Syndrome Coronavirus 2
- TMPRSS:
-
Transmembrane serine protease
- TNF:
-
Tumour necrosis factor
- βCoV:
-
Beta coronavirus
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TT had the idea for the article and then a thorough literature search was conducted by TT, ABS, and FA. All three authors contributed to the writing of the manuscript. The first draft of the manuscript was written by TT and ABS, and the introduction and conclusion were written by FA. All three authors commented on this version of the manuscript and FA made the suggested changes. FK critically revised the final manuscript and offered improvements.
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Taher, T., Sheikh, A.B., Anwar, F. et al. SARS-CoV-2: its potential neurological manifestations and plausible mechanism: a review article. Acta Neurol Belg 121, 331–339 (2021). https://doi.org/10.1007/s13760-020-01577-y
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DOI: https://doi.org/10.1007/s13760-020-01577-y