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Background:
Systematic Review

Encephalitis in Patients with COVID-19: A Systematic Evidence-Based Analysis

by
Md Asiful Islam
1,2,†,
Cinzia Cavestro
3,†,
Sayeda Sadia Alam
4,
Shoumik Kundu
4,
Mohammad Amjad Kamal
5,6,7,8 and
Faruque Reza
9,*
1
Department of Haematology, School of Medical Sciences, Universiti Sains Malaysia, Kota Bharu 16150, Malaysia
2
Institute of Metabolism and Systems Research, University of Birmingham, Birmingham B15 2TT, UK
3
Headache Centre, Department of Neurology, San Lazzaro Hospital, ASL CN2, 12051 Alba, CN, Italy
4
Department of Biochemistry and Molecular Biology, Jahangirnagar University, Savar, Dhaka 1342, Bangladesh
5
Institutes for Systems Genetics, Frontiers Science Center for Disease-Related Molecular Network, West China Hospital, Sichuan University, Chengdu 610064, China
6
King Fahd Medical Research Center, King Abdulaziz University, Jeddah 22230, Saudi Arabia
7
Department of Pharmacy, Faculty of Allied Health Sciences, Daffodil International University, Dhaka 1207, Bangladesh
8
Enzymoics, 7 Peterlee Place, Novel Global Community Educational Foundation, Hebersham, NSW 2770, Australia
9
Department of Neurosciences, School of Medical Sciences, Universiti Sains Malaysia, Kota Bharu 16150, Kelantan, Malaysia
*
Author to whom correspondence should be addressed.
These authors contributed equally to this work.
Cells 2022, 11(16), 2575; https://doi.org/10.3390/cells11162575
Submission received: 7 July 2022 / Revised: 11 August 2022 / Accepted: 16 August 2022 / Published: 18 August 2022
(This article belongs to the Special Issue Neurological Symptoms and COVID-19 Pandemic)
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Abstract

:
Although severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) predominantly infects the respiratory system, several investigations have shown the involvement of the central nervous system (CNS) along the course of the illness, with encephalitis being one of the symptoms. The objective of this systematic review was to evaluate the characteristics (clinical, neuro-radiological aspects, and laboratory features) and outcomes of encephalitis in COVID-19 patients. PubMed, Scopus, and Google Scholar databases were searched from 1 December 2019 until 21 July 2022 to identify case reports and case series published on COVID-19 associated with encephalitis. The quality of the included studies was assessed by the Joanna Briggs Institute critical appraisal checklists. This systematic review included 79 studies, including 91 COVID-19 patients (52.7% male) experiencing encephalitis, where 85.6% were adults (49.3 ± 20.2 years), and 14.4% were children (11.2 ± 7.6 years). RT-PCR was used to confirm 92.2% of the COVID-19 patients. Encephalitis-related symptoms were present in 78.0% of COVID-19 patients at the time of diagnosis. In these encephalitis patients, seizure (29.5%), confusion (23.2%), headache (20.5%), disorientation (15.2%), and altered mental status (11.6%) were the most frequently reported neurologic manifestations. Looking at the MRI, EEG, and CSF findings, 77.6%, 75.5%, and 64.1% of the patients represented abnormal results. SARS-CoV-2-associated or -mediated encephalitis were the most common type observed (59.3%), followed by autoimmune encephalitis (18.7%). Among the included patients, 66.7% were discharged (37.8% improved and 28.9% fully recovered), whereas 20.0% of the reported COVID-19-positive encephalitis patients died. Based on the quality assessment, 87.4% of the studies were of high quality. Although in COVID-19, encephalitis is not a typical phenomenon, SARS-CoV-2 seems like a neuropathogen affecting the brain even when there are no signs of respiratory illness, causing a high rate of disability and fatality.

1. Introduction

The severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) virus attacks the respiratory system. According to the World Health Organization’s most recent data, over 550 million individuals have been infected, with over 6 million deaths globally [1]. As the coronavirus disease 2019 (COVID-19) pandemic continues, there is growing evidence that this virus also affects the central nervous system (CNS), exhibiting its potential neurotropic and neuroinvasive properties [2,3]. Besides systematic, respiratory, and gastrointestinal symptoms, [4,5,6], neurological manifestations are increasingly recognized in patients with COVID-19, including headache, smell dysfunction, taste disorder, and seizure [7,8,9]. Published data have been suggesting that encephalitis is one of the most fatal neurologic manifestations of COVID-19 involving both adult and pediatric patients [10,11,12]. While the exact mechanism of CNS invasion is still being investigated, possibilities have included both direct viral invasion and indirect damages via inflammatory and autoimmune pathways [13,14].
Encephalitis is an inflammation of the brain parenchyma, exerting serious neurological dysfunction, which is majorly caused by viruses characterized by clinical manifestations such as confusion, reduced or alternative levels of consciousness, fever, headache, seizures, and movement disorder. Diagnosis of encephalitis is usually a combinational approach of laboratory, neuroimaging, and electrophysiologic findings, including blood tests, bronchoalveolar lavage or sputum, urine and stool tests, computed tomography (CT) scan, X-ray, electroencephalogram (EEG), lumbar puncture, and magnetic resonance imaging (MRI) [15,16].
The first case of COVID-19-associated meningoencephalitis was confirmed in a 24-year-old male with severe febrile confusion and generalized tonic-clonic seizure in February 2020 [17]. A recent multicenter retrospective study conducted by the Spanish Society of Neurology reported that encephalitis was present in 2.2% of the COVID-19 patients with neurological symptoms [18]. Previous studies have reported several clinical and laboratory features of SARS-CoV-2-mediated encephalitis. As there has been an escalating number of incidents of encephalitis in COVID-19 patients, with alarming morbidity and mortality rates, this study aimed to systematically evaluate the characteristics (clinical, neuro-radiological aspects, and laboratory features) and outcomes of encephalitis in COVID-19 patients, as well as the possible causative mechanisms of CNS damage.

2. Methods

2.1. Study Guideline

This systematic review (PROSPERO registration number CRD42022354224) implemented the updated Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) 2020 guideline [19].

2.2. Search Strategies

We used the advanced and expert options of PubMed, Scopus, and Google Scholar databases, searching for journal articles published between 1 December 2019 and 21 July 2022, combining appropriate keywords associated with COVID-19 and encephalitis (Table S1).

2.3. Eligibility Criteria

We considered only case reports or case series published in the English language. In this systematic review, cases with confirmed encephalitis or meningoencephalitis were considered eligible; however, cases reporting only meningitis were excluded.

2.4. Study Screening and Selection

Following the removal of duplicate studies using EndNote X8 software (Clarivate Analytics, Philadelphia, PA, USA), titles, abstracts, and full texts were screened independently by two authors (MAI and SSA) to identify the eligible studies. The reference lists of the included studies were also reviewed to identify any potentially eligible studies. Any disagreements on whether a study should be included or excluded were discussed with the third author (CC) and resolved subsequently.

2.5. Data Extraction

From each study, all the important data and information was retrieved by two authors (MAI and SSA), including study ID (first author’s last name and year of publication), country of origin of the patient, number, age and gender of the patient, SARS-CoV-2 confirmatory test, past medical history, severity of COVID-19, onset of encephalitis from COVID-19 presentation, neurological and psychiatric symptoms, type of suspected or confirmed encephalitis, patients’ outcome, leukocyte types present, opening pressure when performing lumbar puncture, serum blood glucose value, IgG index, brain computerized tomography (CT) scan, magnetic resonance imaging (MRI) and electroencephalogram (EEG) results, white blood cells (WBCs) level, total protein and glucose concentration, status of SARS-CoV-2, and investigation of other pathogens. All the extracted data were verified by another author (CC).

2.6. Quality Assessment

The Joanna Briggs Institute (JBI) critical appraisal checklist for assessing case reports and case series were used to evaluate the methodological quality of the included studies. Two authors (SSA and SK) independently assessed the quality of each of the included studies, and discrepancies were resolved by discussing with the third author (MAI). Studies receiving scores of <50, 50–70, or >70% were classified as low quality (high risk of bias), moderate quality (moderate risk of bias), or high quality (low risk of bias) [9].

3. Results

3.1. Study Selection

After excluding review articles (n = 23), non-human research (n = 64), and duplicate studies (n = 310) from our initial search results (n = 540), 143 papers were evaluated for eligibility, and 79 studies were eventually included in this systematic review (Figure 1).

3.2. General Characteristics of the Included Studies

Major characteristics of the included studies are presented in Table 1. In brief, among the included 91 patients, 52.7% were male, 85.6% were adults (aged 49.3 ± 20.2 years), and 14.4% were pediatric patients (aged 11.2 ± 7.6 years), where a majority of the patients’ ages ranged between 41 and 70 years (Figure 2). The majority of the patients’ SARS-CoV-2 (92.2%) were confirmed by using the RT-PCR method.
A majority of the studies were reported on European (37.2%), followed by Asian (30.8%) and North American (23.1%), COVID-19 patients. Of these patients, 31.9 were healthy, without any past medical history of illness. Among the reported levels of severity of the COVID-19 patients, 11.7%, 38.3%, 11.7%, and 38.3% of the patients were denoted as asymptomatic, mild, moderate, and severe, respectively. Interestingly, the onset of encephalitis-associated symptoms was manifested in 78.0% of the COVID-19 patients as an initial presentation. Seizure (29.5%), confusion (23.2%), headache (20.5%), disorientation (15.2%), and altered mental status (11.6%) were the most frequently reported neurologic manifestations. Among the types of diagnosed encephalitis, a majority were confirmed to be SARS-CoV-2-associated or -mediated encephalitis (59.3%), followed by autoimmune encephalitis (18.7%). Among the included patients, 66.7% were discharged (37.8% improved, 28.9% fully recovered, and 12.2% patients were discharged without reporting their outcomes), whereas 20.0% of the reported COVID-19-positive encephalitis patients died. Looking at the MRI, EEG, and CT scan findings, 77.6%, 75.5%, and 64.1% of the patients presented with abnormal results, respectively. All the diagnostic features of the COVID-19 patients with encephalitis are presented in Table 2 and S2.

3.3. Evidence-Based Analyses

3.3.1. Infant to Children with COVID-19

Seizures were frequently present, and prognosis was often poor. Neurologic involvement in a term neonate with prenatal exposure to SARS-CoV-2 was described for the first time in 2022 [62]. The main and first symptoms of this baby’s infection were respiratory distress and ground glass pneumonia. She manifested seizure thereafter, and neurological deficit only at 49 days of disease following extubating and respiratory improvement. The neurological deficit corresponded to documented MRI lesions. Only IG therapy showed some benefit. A fatal case of acute hemorrhagic necrotizing encephalitis (AHNE) affected a 2-month-old boy, who presented with fever and general symptoms, but had cardiac arrest followed by brain death within a few days [66]. Another young patient was a 9-month-old infant [84]. The initial symptoms were fever and profuse vomiting for two days. Then, he manifested convulsive seizure and consciousness alteration. CT scan indicated severe hydrocephalus, and a high protein titer in the CSF suggested aseptic meningoencephalitis (Table 1). Despite antibiotic, antiviral, anticonvulsant, and anti-edematous medication, the child had a cardiac arrest and had to be resuscitated and intubated. Due to migrating to another country, the rest of the history of the infant remained unclear. A 34-month boy also had a poor prognosis [35]. He manifested with fever, seizure, and upward gaze, with progressive worsening, and was admitted to intensive care unit due to recurrent seizures and consciousness compromission. His brain MRI documented scattered foci of altered signal together with hemorrhagic foci. Therapy based on antibiotics, antiviral, and antiepileptic drug (AED) failed; he had a mild improvement after dexamethasone, hydroxychloroquine, and intravenous immunoglobulins (IVIG). He was finally in a vegetative state. Six more children—three girls, one aged 23 months [31] and two others aged 7 years [20,55], and two boys aged 7 and 11 years [11,46]—were described with febrile and manifesting epileptic seizures. Ahsan’s and McAbee’s [11,20] cases were with status epilepticus. Burr’s [31] child also showed neurological deficits with language disorders and involuntary movements. Neurological impairment occurred up to nine days after the onset of symptoms; an MRI of the brain revealed no abnormalities. Anti-NMDAR receptor antibodies were detected both in serum and CSF [31]. In this case, the initial treatment with IV methylprednisolone was unsuccessful; therefore, IV immunoglobulin (IVIG) was given instead. The case described by Ahsan et al. [20] tells a similar story, with status epilepticus and aphasia following sporadic self-limited seizures in the prior week and neurologic worsening one week later. This girl’s MRI documented alteration in the perirolandic and posterior area of the parietal lobe, with cortical edema. Following the investigation of various autoantibodies, anti-myelin oligodendrocyte glycoprotein (MOG) antibodies were detected. Following that, IVIG therapy was given, and the child improved over the following five days before being sent home; mild dysarthria persisted at follow-up. In addition, the boy described by Ferdosian et al. [46] had fever and aphasia, with consciousness alteration, for three days, and a history of recurrent seizures in the last five months. His MRI documented diffuse brain edema and CSF contained SARS-CoV-2 RNA. He improved initially with therapy with antibiotics, antiviral, and AED, but did not improve after therapy with IVIG, remdesivir, and AED.
The child described by McAbee et al. [11], who developed status epilepticus and fever after two days of generalized weakness, achieved a better prognosis. He was treated with anti-epileptic drugs (AED), and recovery was completed in six days. A girl, described by Kahwagi et al. [55], was the only child manifesting respiratory symptoms. She had a cough, headache, and fever for six days, followed on day six by multiple generalized tonic-clonic seizures. Her MRI was unremarkable. She experienced gait and behavioral issues, confusional syndrome, and osteotendinous hyperreflexia on day nine. Her EEG background displayed slowness and superimposed pseudoperiodic complexes. This girl was treated with only AED; her seizures diminished, and behavior disorders disappeared over the next two months. Finally, a five-year-old girl manifested with respiratory symptoms, low-grade fever, and neck edema with lymphadenopathy [87]. In a few days, she became lethargic; her EEG was characterized by slow-wave rhythm, and brain oedema with altered signal of splenium of corpus callosum and subcortical parietal lobes was detected in brain MR. She improved and was discharged after two weeks, after having been treated with antibiotics, antivirals, and steroids.

3.3.2. Adolescents with COVID-19

Seven teenagers suffered from encephalitis attributed to COVID-19 infection. Other than respiratory symptoms, headache, seizures, mood, and conscious level alteration were the main neurologic manifestations. Natarajan et al. [10] reported the case of a 13-year-old girl with a fluctuant history of fever, headache, tonic seizures, and status epilepticus. Although she did not manifest respiratory symptoms, her chest CT scan revealed patchy peripheral ground glass opacities. She was treated with levetiracetam and ceftriaxone, and improved in 48 h. Ground glass opacities in the lungs were also detected in the 16-year-old boy mentioned by Bhavsar et al. [29]. This boy suffered from pharyngitis, headaches, fever, and generalized weakness. On day 11, his neurologic status worsened, with progressive somnolence, confusion, incoherent speech, and walking. After that, he had seizures that required benzodiazepine and AED. Laboratory investigations revealed plasmatic and urinary alterations consistent with the syndrome of inappropriate antidiuretic hormone secretion (SIADH), and his EEG had a slow background. He was treated with antibiotics, and improvement of hyponatremia was accomplished, although he exhibited persistent neurologic disfunction. After one week, he developed an infrapopliteal deep venous thrombosis, and therapy with low-molecular-weight heparin was started. He was discharged to his home on day 15.
An 18-year-old girl was also infected with ground glass pneumonia [21]. She also manifested with seizures and mood disorders. A brain edema and the presence of anti-NMDA receptor antibodies were causative alterations. Steroids and IVIG determined a good prognosis. Two girls with learning disabilities worsened both intellectually/psychically and with neurological deficit. The 19-year-old described by Kasturiachi et al. [57] had progressive encephalopathy, epileptic EEG alteration without seizures, and multiple MR brain lesions. This case was complicated due to coexisting thrombotic thrombocytopenic purpura and other serologic poliautoimmunity; however, her prognosis was good after therapies with plasmapheresis, steroids, and rituximab.
A controversial case of a 16-year-old girl have been described by Gaughan et al. [48]. She had a history of mild learning needs; she complained of sore throat, fever, and psychotic behavior. After five days of IVIG therapy, the condition worsened, presenting mutism, little to no motor activity, incontinence, and being fed via nasogastric tube. Chest X-ray, MRI, and CSF were unremarkable. Two weeks later, following IVIG therapy, anti-GAD antibodies and extractable nuclear antigen appeared in the serum, transitorily. Repeated EEG showed slow activity. The girl improved 4 weeks after initial presentation and was discharged on day 48. The follow-up visit after six months revealed that she is still experiencing memory difficulties and fatigue.
Another 18-year-old girl, whose case has been described by Ayatollahi et al. [23], had fever, fatigue, malaise, and loss of appetite for a week, which progressed to drowsiness and confusion, and finally urinary retention and repeated generalized tonic-clonic seizure. Both CT brain scans and MRI were normal. In the following days, she had new seizures and fluctuating mood alterations, which were resistant to several therapies. Later on, a new MRI showed altered signals in the claustrum, external capsules, and some areas of the adjacent anterior insular cortex. Thereafter, therapy with intravenous methylprednisolone was started, and after three days, she was discharged in good condition. At follow-up, after one month, MRI showed nearly complete resolution of the previously described signal alterations. Seizures did not recur, although the memory deficit persisted. The last young girl mainly had retinal involvement, with subsequent encephalitis of the temporal lobes. Apart from fever, body pain, headache, and nausea with vomiting, the only neurologic symptom was drowsiness, and the prognosis was good [77].

3.3.3. Adults with COVID-19

Initial Presentation with Neurological and Respiratory Symptoms

Most cases manifested respiratory symptoms as an early manifestation of SARS-CoV-2 infection. Six cases also manifested neurological symptoms from the beginning of their clinical history [26,27,42,49,69,93]. Several cases developed neurological impairment following respiratory symptoms. The latency between the onset of the infection with respiratory manifestations and the onset of neurological complications varied between 3 days and 41 days [12,24,27,28,30,32,34,36,37,43,45,51,56,58,64,65,70,76,80,81,82,83,85,86,89,90,91,93,94]. Overall, 13 patients were intubated and mechanically ventilated due to respiratory distress; in these cases, the detection of neurological impairment happened when sedation was interrupted, with latency ranging between 4 and 38 days depending on the case [27,32,34,76,80,82,85,93]. In patients whose respiratory distress was less evident, neurological manifestation appeared after a few days in most cases [27,28,30,37,45,56,58,65,89,91,93,94]. In some cases, the latency ranged from over two weeks to 60 days [12,24,27,64,90]. Three patients began their illness with symptoms other than respiratory and developed neurological impairments between 5 and 17 days after the onset of the initial symptoms [22,47,50]. Their clinical presentations consisted of fatigue and malaise for two weeks in one case [47]; progressive diffuse arthralgia and sore throat, followed by fever [50]; and gastrointestinal manifestations in the third case [22]. An onset with neurological presentation was described in a number of reports [17,25,30,33,38,39,41,44,52,53,54,56,59,60,61,68,71,72,73,74,75,78,79,92]. Respiratory complications came later and were symptomatic in three cases [61,75,78]. Even though several patients did not have subjective respiratory difficulties or changes in arterial oxygen saturation, most of them had lung alterations on thorax CT and/or chest X-ray, which were typical of COVID-19 interstitial pneumonia, primarily as ground glass opacities and areas of parenchymal consolidation.

Neurological and Psychiatric Manifestations

Sleep disturbances, progressive altered mental status, psychiatric behavioural symptoms, and hallucination have been described by some authors [22,26,37,47,51,52,56,58,63,72,73,75,78,81,86,89,94]; most of these cases are associated with EEG representations [22,26,37,63,74,75], and some with brain neuroimaging alteration [51,52,56,78,81,94]. Neurological deficit referred to language deficit, cognitive deficits, akinetic syndrome with mutism, signs of cortical impairment, seizures, stroke, cerebellar signs, chorea, paralysis, coma, and signs of brain death [17,25,33,36,37,38,39,47,49,51,52,53,58,59,60,64,65,71,72,74,76,78,79,89,92].
Few cases presented with severe epileptic manifestations. Epileptic manifestations occurred from the first phase of infection, evolving into status epilepticus in some patients. Two of these patients died. The first developed intracranial hypertension with diffuse cerebral edema, and cerebellar herniation occurred [79]. The second case manifested a tonic-clonic seizure, followed by cardiac arrest, and was successfully resuscitated, intubated, and transferred to the intensive care unit. In this case, CT and MRI also showed brain edema and cerebellar herniation [45]. A third patient developed status epilepticus that required the patient to be intubated and mechanically ventilated. Chest CT showed interstitial pneumonia. He had an opening high pressure when lumbar puncture was performed, and SARS-CoV-2 RNA was detected in his CSF, while MRI revealed ventriculitis and encephalitis, mainly in the right mesial lobe and hippocampus [17]. The last case reported early onset of drug-refractory epilepsy; MRI and spectroscopy were suggestive for high-grade glioma; after lobectomy, histopathologic diagnosis was of encephalitis [41]. A late-onset status epilepticus with intracranial hypertension ion caused the death of another patient [12]. In this case, the disease had a two-phase evolution. He had a first respiratory phase, with recovery in 2–3 weeks. After 41 days, the fever reappeared, together with severe headache and vomiting. A brain CT scan and MRI showed unilateral hemispheric vasogenic edema with shift of the medial cerebral structures.

Particular Case of COVID-Linked Encephalitis

Some cases were marked by identification of specific neural antibodies. Three patients suffered from NMDA encephalitis [68,73,88]. Clinical manifestations were psychotic symptoms and seizures only. All of them improved with immuno-therapies, including IV methylprednisolone, IVIG, therapeutic plasma exchange. Only in the case described by Valadez-Calderon et al. [88], in which anti-NMDAR and anti-GAD65 antibodies were co-expressed, were EEG (slow rhythm) and MRI (MR signal alteration anterior cingulated cortex and temporal lobes bilaterally) both altered.
One patient developed an MOG antibody-associated encephalitis. He had minor clinical manifestations, but mulptiple MRI signal alterations: T2 and FLAIR, mainly with cortical distribution. This patient also improved after IV steroids [40]. Bickerstaff brainstem encephalitis involved three patients: two women and a man. Their main manifestation was truncal and cerebellar disfunction. In the case with anti-GD1 IgG antibodies [25], MRI images were altered (alterations in the caudal vermis and right flocculus of the cerebellum, and contrast enhancement in the floor of the IV ventricle). Improvement and resolution of symptoms were obtained with IV methylprednisolone. In the case with anti-gangliosides (GQ1b, GT1a, and GM1/GT1a), both EEG and MRI were normal. The patient improved after therapy with IV steroids, IVIG, but mainly after plasma exchange. The third case had serum onconeural antibodies against amphiphysin, and MR of brainstem encephalitis; this man also improved after steroidal therapy [59].
Another case of autoimmune encephalitis was described by Grimaldi et al. [50]. This man presented with progressive diffuse arthralgia and sore throat and interstitial pneumonia, and after 17 days, progressive action tremor, cerebellar syndrome, and diffuse myoclonus. EEG showed diffuse slowing, and MRI was normal, but PET with F-FDG showed putaminal, cerebellum, and diffuse cortical hypometabolism, confirmed by whole-brain voxel-based SPM quantification. Antibodies against the nuclei of Purkinje cell, striatal neurons, and hippocampal neurons were found in both serum and CSF. The patient was then treated with IVIG without clinical improvement. He improved after therapy with IV methylprednisolone and clonazepam.
Other particular cases of encephalitis were described. Three case reports described limbic encephalitis [43,76,92]. All of these patients had severe pneumonia, seizures or consciousness alteration, and anti-typical MRI alterations. All of them improved after having been treated with steroids, only in one case with IVIG added. A 67-year-old woman had an acute disseminated encephalitis (ADEM), with drowsiness; she had bilateral pneumonia and respiratory distress, was treated with IV steroids and IVIG, and unfortunately died after 4 weeks [44]. Two cases of mild encephalitis with reversible splenial lesion syndrome (RESLES) were described [42,54]. Both of them had interstitial pneumonia. The first patient [42] was afebrile, and presented a short loss of consciousness, cough, and headache. CSF and brain CT scan were normal, so he was discharged from the hospital. Nine days later, he manifested persistent headache, vertigo and intermittent disturbance of consciousness, myalgia, tiredness and persistent bibasilar rales, psychomotor slowing, and vestibular syndrome. MRI documented a signal alteration on the splenium of the corpus callosum. He was treated with analgesics and antibiotics. The patient improved gradually over the next few days. At one-month follow-up, lung complications were reduced, and MRI normalized. The second patient [54] showed marked dysmetria and mild ataxic gate. MRI documented abnormal alteration of the splenium of the corpus callosum, with a suspicion of RESLES. After a few hours, they manifested fever and hypoxemia. Treated with antiviral, antibiotics, and steroids, they neurologically improved but died at day 12 due to respiratory failure. Seven cases had AHNE [49,69,70,90]. This is a severe condition with poor prognosis. Neurological manifestations appeared after several days but were abrupt. Only four cases had pulmonary compromission [69,70,90]. All seven adults with AHNE died within 3 weeks.

Managing Severe Cases

Severe respiratory impairment was the main feature of some cases and required intubation. Benameur et al. [27] described three cases that manifested neurological complications after sedation was discontinued. In one case, cerebral edema with intracranial hypertensive signs was detected with MRI and CSF examination, consistent with encephalomyelitis and superimposed hypoxic ischemia. This woman died when life support was withdrawn. In the second case, profound encephalopathy with multifocal myoclonus was detected, and the patient was neurologically comatose. At lumbar puncture, there was a high opening pressure, suggesting intracranial hypertension. MRI disclosed a signal alteration at the splenium of the corpus callosum. The third case also had a profound encephalopathy without brainstem reflexes. He was treated with hydroxychloroquine, which caused myoclonus that disappeared at the cessation of this therapy. MRI showed signal alteration involving the temporal lobe. In this last case, the IgG anti-S1 receptor-bindle domain was present in serum, and a mild IgM level for SARS-CoV-2 S1 was found in CSF. In these cases, inflammatory molecules have been dosed in CSF, and in one case (the third), IL-8, IL-10, IP-10, and TNFα were increased. In the case series by Cao et al. [32], all five patients were intubated due to acute respiratory distress syndrome. When sedation was withdrawn, one patient was comatose, and the other four were in an unresponsive wakefulness syndrome (vegetative state). Four of them had high IL-6 level in serum, and one patient also had a slight increase of IL-6 in CSF. MRI showed several lesions in supratentorial deep white matter, in the pons, with several multiple small haemorrhagic lesions. Three out of five patients rapidly improved after therapy with intravenous steroids and therapeutic plasma exchange; one patient died. In addition, in the case by Svedung Wettervik et al. [85], the patient was comatose at the wake-up test after intubation. She had brain edema, and microhemorrhages with basal ganglia involvement, in line with acute hemorrhagic leukoencephalitis. An external ventricular drain was positioned, and CSF had fluctuating pressures, with a large amount of white and red cells. IL-6 was high in both plasma and CSF. This patient underwent therapeutic plasma exchange, after which she improved both clinically and in neuroimaging. Chalil et al.’s case developed respiratory distress two weeks from onset [34]. She was intubated, and severe lung complications were observed in chest CT. Therapy was hydroxychloroquine and tocilizumab. Due to the detection of very high D-dimer and ferritin levels, increased CRP, and severe hypoxemia, full anticoagulation started. Extensive bilateral parieto-occipital intraparenchymal hemorrage were observed with intraventricular extension and acute hydrocephalus. On day 15, brainstem reflexes were absent. Heparin was stopped, and external ventricular drain positioned. The authors interpreted this case as a post-infectious acute necrotizing hemorrhagic encephalopathy, due to thalamic involvement, suggested as typical for acute necrotizing hemorragic encephalopathy [34]. The patient was finally extubated, but severe neurologic deficit persisted.
The most prescribed drugs were antibiotics and antiviral agents. Quite often, hydroxychloroquine and high-dose methylprednisolone have been used. Until 2021, therapeutical plasmapheresis and immunosuppressive drugs were rarely prescribed. After the first period of the COVID-19 pandemic, immunomodulating agents, in particular IVIG and tocilizumab, plasmapheresis, and convalescent’s serum, have been used more often, with good response [21,51,59,60,70,81,83,88], except for the most severe cases, like in ANHE.

3.4. Quality Assessment

Among the included studies in this systematic review, based on the JBI critical appraisal tools assessing case reports and case series, 87.3% of the studies were of high quality, followed by 11.4% moderate- and 1.3% low-quality studies (Tables S3 and S4).

4. Discussion

In this systematic review, we comprehensively investigated the clinical and laboratory features, as well as the outcomes of COVID-19 patients with encephalitis. COVID-19 encephalitis can present before, together, or after respiratory manifestation of the illness. The most frequent neurological manifestations of encephalitis are seizure, confusion, headache, disorientation, status epilepticus, and altered mental status, and the degree of the condition is dependent mostly upon the severity of COVID-19 infection, entity of respiratory damage, and entity of neuronal damage and its site [91,95]. Severity of respiratory impairment and neuronal damage are the factors that seem to determine the worst prognosis. The knowledge of possible para- or post-infectious SARS-CoV-2 encephalitis, and of possible inflammatory or immune mechanisms of neuronal damage, can drive research for better therapies to improve outcomes [27,96].
In most cases, preforming a lumbar puncture can suggest the presence of encephalitic involvement. Brain CT scan in an emergency can be useful only in those cases that manifest with very acute neurological compromission, and can reveal brain edema, endocranial hypertension, massive necrosis, and or hemorrhagic lesions. A rapid intervention, acting to reduce intracranial hypertension, can help give the patient a chance to survive and receive the proper therapeutical efforts [97,98]. In those cases with psychiatric or epileptic presentation, CT scan can be unremarkable. MRI is also useful to detect small lesions, which can sometimes be transitory. In some cases, the only way to reveal neuronal disfunction is to use a neurological functional test, such as PET [99,100]. EEG is mostly aspecific, with slow background activity. Sometime EEG can also reveal epileptic activity of the non-convulsive type [101].
In the case of COVID-19, confirmed or suspected, it is important to consider possible neurological involvement. The clinician should consider any behavioral changes or alterations of consciousness. These can be due to hypoxic damage, hematochemical alteration, or circulatory problems, or they can be COVID-19-related. However, it can be a manifestation of neuronal involvement. The precocity of a specific intervention is essential to preserve neurons, and in case of any suspicion, proper tests and exams should be performed. Sometimes, neurological damage progresses slowly or tardively, and neuro-clinical symptoms can appear several day or weeks after the onset of the first symptoms. In these cases, an autoimmune mechanism of damage can be supposed, and this should drive the therapeutical approach [102,103].
Although the exact pathogenesis of the SARS-CoV-2 virus’s access to the CNS and triggering of various neurological manifestations is still under investigation, researchers have suggested a few mechanisms. SARS-CoV-2 can exert neurological manifestations by two main mechanisms. The first mechanism is the direct CNS infection, where SARS-CoV-2 gain access to the CNS from the peripheral nervous system, as RNA of the SARS-CoV-2 virus has been detected in the CSF of the COVID-19 patients. As in mature human olfactory nerves, ACE2 has not been reported, and ACE2 is most likely present at low levels in neurons [104,105]. SARS-CoV-2 possibly uses other facilitator(s) to access the CNS. One of the plausible routes for SARS-CoV-2 entry in the CNS could be that upon nasal infection, SARS-CoV-2 enters the CNS through the olfactory bulb, facilitated by neuropilin-1 (retrograde axonal transport), the only part of the CNS not protected by dura, causing inflammation and demyelination [106,107,108]. The second mechanism involves the disruption of the blood–brain barrier via SARS-CoV-2-ACE2 receptor-mediated vascular damage following viraemia. In this inflammation-mediated autoimmune-associated mechanism, both innate and adaptive immune systems play a role via upregulated inflammatory mediators exerting cytokine storm syndrome, which may result in acute hemorrhagic necrotizing encephalitis via perivascular demyelination [109,110,111].
Neurological symptoms seem to be the initial sign of illness in certain cases of COVID-19. A few cases, however, had already developed antibodies against SARS-CoV-2, suggesting a previous asymptomatic or pauci-symptomatic COVID-19 disease. That is why it is important, in case of neurological manifestation, to perform both the nasopharyngeal swab for SARS-CoV-2 and the serum test for antibodies against the virus. It is speculated that SARS-CoV-2-mediated encephalitis may present inflammatory injury, edema, and alterations in consciousness in patients with COVID-19 [91,96]. Although viral encephalitis confirmation requires virus isolation in the CSF, due to transient dissemination of SARS-CoV-2 virus and low CSF titre, it becomes extremely difficult to confirm viral encephalitis in COVID-19 [91]. For the management of encephalitis in COVID-19, we observed that IVIG therapy, plasma exchange, and corticosteroids may be useful in the treatment of COVID-19-related encephalitis.
There are some notable strengths of our study. First, this is the first systematic analysis based on the published case reports and series that was represented in a comprehensive way. Second, the search strategy was strong, as we used multiple databases with robust search strategies. Third, from our quality assessment, a majority of the studies were of high quality; therefore, the outcome of this systematic review is reliable, and it is based on high-methodological-quality studies. Nevertheless, there are some notable limitations. First, due to the study pattern, we could not analyze the data through a meta-analysis approach. Second, due to exploring the clinical, laboratory, and neuro-imaging data in a comprehensive way, we only included case reports and case series, and we did not consider any observational studies. Third, we could not retrieve our data of interest from all of the studies, which leads to incomplete data for some of the cases. However, since there is presently very little published information on encephalitis in COVID-19 patients, our analysis provided a strong early insight into the clinical, laboratory, and neuro-imaging characteristics of encephalitis in COVID-19 patients.
In the future, larger sample sizes would aid in determining if the neurological aspects, particularly the relationship with encephalitis, are purely coincidental, or whether there are phenotypes and associations particular to SARS-CoV-2.

5. Conclusions

COVID-19 patients with acute characteristic neurological signs such as seizure, confusion, headache, disorientation, status epilepticus, and altered mental status should be evaluated for viral encephalitis immediately, given the present condition of the COVID-19 pandemic. Patients with COVID-19 who are suspected of having encephalitis should have further testing, such as a brain MRI scan, long-term EEG monitoring, and lumbar puncture. The lack of a characteristic CSF profile of viral meningitis/encephalitis, as well as the negative PCR for SARS-CoV-2 virus in CSF, makes the diagnosis of encephalitis caused by the SARS-CoV-2 virus less evident, pointing to a possible autoimmune neuropathogenesis. In the post-acute phase of SARS-CoV-2 infection, it is critical to evaluate the neurological consequences. In this phase, encephalitis should be diagnosed only if there are clinical signs of brain inflammation, such as pleocytosis in the CSF, imaging alterations, focal seizures, or histological alterations. Even if the virus is found in the CSF, encephalitis should not be diagnosed until brain inflammation is present.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/cells11162575/s1, Table S1: Search strategies, Table S2: Laboratory features of encephalitis patients with SARS-Cov-2 infection, Table S3: Quality assessment of the included case reports, Table S4: Quality assessment of the included case series.

Author Contributions

Conceptualization, M.A.I. and C.C.; methodology, M.A.I., S.S.A., and S.K.; validation, C.C., M.A.I., S.S.A., and F.R.; formal analysis, C.C. and M.A.I.; investigation, M.A.I., C.C., S.S.A., and S.K.; resources, M.A.I., C.C., and F.R.; data curation, C.C., M.A.I., F.R., and S.S.A.; writing—original draft preparation, C.C. and M.A.I. writing—review and editing, M.A.I., C.C., M.A.K., and F.R.; project administration, M.A.I. and F.R.; funding acquisition, M.A.I. and F.R. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

The data presented in this study are available within the article and Supplementary Materials.

Conflicts of Interest

The authors declare no conflict of interest.

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Cells 11 02575 g001 550
Figure 1. PRISMA flow diagram showing the process of selecting eligible studies.
Figure 1. PRISMA flow diagram showing the process of selecting eligible studies.
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Cells 11 02575 g002 550
Figure 2. Age distribution of COVID-19 patients with encephalitis.
Figure 2. Age distribution of COVID-19 patients with encephalitis.
Cells 11 02575 g002
Table
Table 1. Major characteristics of the included studies.
Table 1. Major characteristics of the included studies.
No.Study ID, Country
[references]		No. of PatientAge (Years), GenderConfirmation of SARS-CoV-2Past Medical HistorySeverity of COVID-19Onset of Encephalitis from COVID-19 PresentationNeurological and Psychiatric SymptomsType of Suspected or Confirmed EncephalitisOutcome
1Ahsan 2021, USA
[20]		17, FSerology test positive (IgG in serum)HealthyAsymptomaticPost-SARS-CoV-2 infection1st admission: status epilepticus, aphasia, encephalopathy; 2nd admission: headache, encephalopathy, slurred speech, altered mental statusAutoimmune encephalitisDischarged and follow-up confirmed recovery with mild dysarthria
2Allahyari 2021, Iran
[21]		118, FRT-PCR positiveNRNRInitial presentationAltered mental status, tonic-clonic seizures, confused state, minor meningismus, neck stiffnessAutoimmune encephalitis (SARS-CoV-2-mediated anti-NMDAR encephalitis)Discharged with full recovery
3Andrea 2020, Italy
[22]		179, FRT-PCR positiveRheumatoid arthritisMildInitial presentationConfusion, somnolence, psychomotor retardation, and cephaleaSARS-CoV-2-mediated encephalitisComplete recovery in 15 days
4Ayatollahi 2020, Canada
[23]		118, FRT-PCR positiveNRMildInitial presentationDrowsiness and confusion, generalized tonic-clonic seizure, impaired orientation to time and place and recent memoryAutoimmune encephalitisNear complete
resolution of the claustrum hyperintensities following 1 month, no seizures
following 7 weeks
5Ayuningtyas 2022, Indonesia [24]134, FRT-PCR positiveObese SevereInitial presentationReduced consciousness, altered mental status aggressive behavior, seizure, headacheSARS-CoV-2-mediated encephalitisDischarged with full recovery
6Ayuso 2020, Spain
[25]		172, FRT-PCR positiveHypertension, hyperlipidemia, depression, and smokingNRPost-SARS-CoV-2 infection (after 8 days of discharge)1st admission: delirium; 2nd admission:
dizziness, oscillopsia, inattention, disorientation, unsteadiness, myoclonus, and ataxia		Autoimmune encephalitis (SARS-CoV-2-mediated Bickerstaff encephalitis)Discharged; after 2 months, very mild unsteadiness was observed
7Babar 2020, USA
[26]		120, FRT-PCR positiveObesity
and anxiety		MildInitial presentationAcute altered mental status, confusion, ageusia, insomnia, hypervigilance, obsessive thinking, and urinary incontinenceSARS-CoV-2-mediated encephalitisNear complete
resolution of the neurological symptoms after 12 days of discharge
8Benameur 2020, USA
[27]		331, FRT-PCR positiveSickle cell diseaseSevereInitial presentationVarious neurologic manifestations including myoclonus, affected brainstem reflexes, and encephalopathySARS-CoV-2-mediated encephalitisDied
34, MHypertensionInitial presentationNR
64, MHypertensionInitial presentationDischarged without major neurologic sequelae
9Bernard-Valnet 2020, Switzerland
[28]		264, FRT-PCR positiveNRMildInitial presentationTonic-clonic seizure,
disorientation,
strong attention deficit, verbal and motor perseverations and bilateral grasping, hyper-religiosity with mystic delusions, visual hallucinations, and non-convulsive status epilepticus		SARS-CoV-2-mediated meningoencephalitisResolution of her symptoms after 96 h of admission
67, FRT-PCR positiveNRMildInitial presentationIntense headache, drowsiness, confusion, motor perseverations,
bilateral grasping, and aggressiveness		SARS-CoV-2-mediated meningoencephalitisDischarged after 72 h without major neurologic symptoms
10Bhavsar 2020, USA
[29]		116, MRT-PCR positiveHealthyMildInitial presentationInitially intermittent headache; day 11: confusion, incoherent speech, seizure, and altered mental status, with inconsistent awareness of time and placeSARS-CoV-2-mediated encephalitisDischarged after day 15 with improved mental status
11Bodro 2020, Spain
[30]		225, MRT-PCR positiveHealthyNRInitial presentationHeadache, left-side paresthesia and ipsilateral paresis, progressing to confusion and agitationSARS-CoV-2-mediated encephalitisFully recovered within 2 days except for amnesia
49, MRT-PCR positiveHealthyMildInitial presentationAnomic aphasia, disorientation, confusion, and agitationFully recovered within 3 days except for amnesia
12Burr 2021, USA
[31]		123 months, FRT-PCR positiveHealthyNRInitial presentationInitial: fussiness, poor sleep; day 9: seizure, hyperkinetic movements, and mood labilityAutoimmune encephalitis (SARS-CoV-2-mediated anti-NMDAR encephalitis)Discharged and fully recovered after 2 weeks
13Cao 2020, France
[32]		549, MRT-PCR positiveRheumatoid
purpura		SevereInitial presentationHeadache and anosmiaSARS-CoV-2-mediated encephalitisImprovement after 6 days of immunotherapy
56, MRT-PCR positiveHypertensionSevereInitial presentationImprovement after 2 days of immunotherapy
61, MRT-PCR positivePulmonary sarcoidosis and thrombocytopeniaSevereInitial presentationImprovement after 7 days of immunotherapy
37, MRT-PCR positiveObesitySevereInitial presentationDied
77, FRT-PCR positiveObesity, hypertension and asthmaSevereInitial presentationVegetative state
14Casez 2021, France
[33]		196, FRT-PCR positiveNRNRInitial presentationAt onset: anosmia, dysgeusia; day 3: generalized epileptic seizures, and left hemiparesisSARS-CoV-2-mediated encephalitisNR
15Chalil 2020, Canada
[34]		148, FRT-PCR positiveHealthySevereInitial presentationAltered mental statusSARS-CoV-2-mediated acute hemorrhagic encephalitisDuring the report, she was undergoing
rehabilitation
16Cheraghali 2021, Iran [35]134 months, childRT-PCR positiveHealthyNRInitial presentationTonic-clonic seizures, and loss of consciousnessSARS-CoV-2-mediated encephalitisDischarged with decerebrate posture
17Dahshan 2022, Egypt [36]167, MRT-PCR positiveHypertensionNRPost-SARS-CoV-2 infection (8 days after SARS-CoV-2 infection)Acute confusion state, behavioral changes, agitation, and one attack of loss of consciousnessAutoimmune encephalitisDischarged with full recovery
18Dono 2021, Italy
[37]		181, MRT-PCR positiveMild hypertensionNRPost-SARS-CoV-2 infection (on day 14 during her hospitalization for COVID-19 infection)Since day 14: mild confusion with fluctuation
of the mental status; day 16: myoclonic jerks and non-convulsive status epilepticus with coma		Suspected autoimmune encephalitisDied
19Duong 2020 and Huang 2020, USA
[38,39]		141, FRT-PCR positiveT2DM and obesityNRInitial presentationSeizure, lethargy, disorientation, agitation,
and hallucination		SARS-CoV-2-mediated encephalitisMental status improved by hospital day 12
20Durovic 2021, Germany [40]122, MRT-PCR positiveHealthyNRPost-SARS-CoV-2 infection (10 days after SARS-CoV-2 infection)Severe headache, neck stiffness, general weakness, and a loss of smell and tasteAutoimmune encephalitisDischarged with full recovery
21Efe 2020, Turkey
[41]		135, FRT-PCR positiveNRNRInitial presentationHeadache,
nausea, dizziness, and drug-refractory seizures		SARS-CoV-2-mediated encephalitisNR
22El Aoud 2021, France
[42]		160, MSerology test positiveDyslipidemiaMildInitial presentationHeadache, disturbance of consciousness, and vertigoSARS-CoV-2-mediated encephalitisDischarged and recovered after 1 month
23Elmouhib 2022, Morocco [43]154, FRT-PCR positiveHealthySevereInitial presentationAltered mental state, dyspnea, altered consciousnessSARS-CoV-2-mediated autoimmune limbic encephalitisDischarged with improved state
24Esmaeili 2022, Iran [44]167, MRT-PCR positiveHealthySevereInitial presentationDrowsiness,
decreased level of consciousness,
deep tendon reflexes were brisk, and plantar reflexes were upward		Acute disseminated encephalitisDied
25Etemadifar 2020, Iran
[45]		151, MRT-PCR positiveHypothyroidism and migraineMildInitial presentationFor 3 days, episodic headache, nausea, and drowsiness, and generalized tonic-clonic seizureSARS-CoV-2-mediated encephalitisDied
26Ferdosian 2021, Iran [46]17, MRT-PCR positiveControlled seizures MildInitial presentationLoss of consciousness, inability to speakSARS-CoV-2-mediated encephalitisDischarged with supportive treatment
27Freire-Álvarez 2020, Spain [47]139, MRT-PCR positiveNRMildInitial presentationDrowsiness, mental disorientation, inconsistent language disorder, and headacheSARS-CoV-2-mediated encephalitisFollowing intravenous immunoglobulins and cytokine blockade with IL-6 receptor antagonist, the patient fully recovered after 30 days from admission
28Gaughan 2021, Ireland
[48]		116, FRT-PCR positiveMild learning disabilityAsymptomaticInitial presentationVisual and auditory
hallucinations, cognitive difficulties, and high-frequency tremor		Autoimmune encephalitisDischarged; at six months, showed significant improvements
29Ghosh 2020, India
[49]		144, FRT-PCR positiveHealthyNRInitial presentationFor 10 days: hypogeusia, hyposmia; then, confusion, disorientation, cognitive disorders, apraxia; then,
tonic-clonic seizure and coma		SARS-CoV-2-mediated AHNEDied
30Grimaldi 2020, France
[50]		172, MRT-PCR positiveTransient global amnesiaMildInitial presentationSince day 17: action
tremor, ataxia, dysarthria, and upper limb dysmetria and myoclonus		Autoimmune encephalitisImproved and discharged at day 37
31Gunawardhana 2021, Sri Lanka [51]147, FRT-PCR positiveUncomplicated T2DMMildPost-SARS-CoV-2 infection (4 weeks after SARS-CoV-2 infection)Confusion and abnormal behavior, seizures, status epilepticusSARS-CoV-2-mediated encephalitisDischarged
to home with only minor residual cognitive deficits
32Haider 2020, USA
[52]		166, MRT-PCR positiveBenign prostatic hypertrophy, fatty liver disease, and
hypertension		NRInitial presentationSeizure; impaired orientation to time, place, and person; and persistent confusionSARS-CoV-2-mediated encephalitisTwo months post-discharge, the patient showed significant improvements following rituximab
33Hassan 2021, Pakistan [53]158, MRT-PCR positiveHypertensionSevereInitial presentationAcute choreaSARS-CoV-2-mediated encephalitisDischarged
34Hayashi 2020, Japan
[54]		175, MRT-PCR positiveMild
Alzheimer’s disease		SevereInitial presentationLeft-dominant kinetic tremor in hands, alerted consciousness, dysmetria, ataxia, disorientation, and mild gait disturbanceSARS-CoV-2-mediated encephalitisDied
35Kahwagi 2021, Senegal
[55]		17, FRT-PCR positiveNRMildPost-SARS-CoV-2 infection (On day
6 during her hospitalization)		Initial: headache; day 6: generalized tonic-clonic seizures; day 9: gait and behavioral disturbance, confusional syndrome, osteotendinous, and hyperreflexiaSARS-CoV-2-mediated encephalitisComplete recovery over the follow-up of 2 months
36Kamal 2020, United Arab Emirates
[56]		131, MRT-PCR positiveHealthyMildInitial presentationDay 3, behavioral disturbance; day 5: altered mental state, acute behavioral changes, severe confusion, fluctuations in the level of consciousness, and drowsinessSARS-CoV-2-mediated encephalitisDischarged; further follow-up confirmed good condition
37Kasturiarachi 2022, USA [57]119, FRT-PCR positiveMenorrhagia, learning disability, and remote suicidal ideationNRPost-SARS-CoV-2 infection (recent infection)Headaches, vomiting, and psychosis, left gaze deviation and right hemiplegia,
unable to follow commands or open her eyes spontaneously, seizures, hyperreflexia in the right upper and lower extremities, no hyperkinetic movements		Sjogren’s-associated encephalitisDischarged with improved mental status but needed to be monitored closely as
an outpatient
38Khoo 2020, UK
[58]		165, FRT-PCR positiveAlzheimer’s disease, osteoarthritis, and
gastro-esophageal
reflex disease		MildPost-SARS-CoV-2 infection (2 weeks after SARS-CoV-2 infection)Week 2: widespread involuntary movements, diplopia, cognitive decline, speaking difficulties, increasing confusion; at entry: myoclonus, ocular movement disorder, aphasia, and perseverationAutoimmune encephalitisDischarged with improved neurological symptoms; back to baseline after 1 month from onset
39Kimura 2021, Japan [59]168, FRT-PCR positiveHypertensionNRPost-SARS-CoV-2 infection (2 weeks after SARS-CoV-2 infection)Her eyes were fixed in position and complete flaccid paralysis with diminished tendon reflexes in all extremities; no pathological reflexAutoimmune encephalitis (SARS-CoV-2-mediated Bickerstaff encephalitis)Discharged with residual double vision and bilateral disturbance in abduction
40Koh 2022, Republic of Korea [60]120, FRT-PCR positiveHealthyModerateInitial presentationTonic-clonic seizure
On her left face and arm, drowsy mentality, personality change, dizziness, and somnolence		Suspected autoimmune encephalitisDischarged with near-complete recovery
41Kumar 2020, India
[61]		135, MRT-PCR positiveHeadacheNRInitial presentation10 days before: headache; at entry: comaSARS-CoV-2-mediated ANEDied
42Kumar 2022, India [62]19 days, neonateRT-PCR positive Respiratory distress,
hypoxia 		NRPost-SARS-CoV-2 infection (MRI done after 42 days of illness)Generalized hypotonia generalized seizuresSARS-CoV-2-mediated encephalitisDischarged with tachypnoea without hypoxia
43Marques 2022, Portugal [63]249, FRT-PCR positiveHealthyNRPost-SARS-CoV-2 infection (6 days after SARS-CoV-2 infection)Altered mental status, lethargic, not oriented to time and place, could not follow commands, neck rigidity, amnesiaSARS-CoV-2-mediated encephalitisTwo months post discharge, she was doing well, with no neurological signs and symptoms
50, FRT-PCR positiveDepressionNRPost-SARS-CoV-2 infection (8 days after SARS-CoV-2 infection)Restless, sometimes physically aggressive, mutism Three months post discharge, she was doing well with no neurological signs and symptoms
44McAbee 2020, USA
[11]		111, MRT-PCR positiveHealthyAsymptomaticInitial presentationStatus epilepticusSARS-CoV-2-mediated encephalitisRecovered within 6 days
45Mekheal 2022, USA [64]188, FNRHypertensionNRPost-SARS-CoV-2 infection (2 months after SARS-CoV-2 infection)Right leg weakness, dysarthria, altered mental statusAutoimmune encephalitisNR
46Meshref 2021, Egypt [65]166, FRT-PCR positiveChronic bronchitis and ischemic heart diseaseNRInitial presentationDelirious state, confusion, fluctuant conscious level, and disorientationSARS-CoV-2-mediated encephalitisDischarged home with full consciousness, no neurological deficits
47Mierzewska-Schmidt 2022, Poland [66]12 months, BoyRT-PCR positiveHealthyNRInitial presentation Irritability, nystagmus, agitation then apathySARS-CoV-2-mediated AHNEThe baby showed signs of brain death
48Miqdad 2021, Saudi Arabia [67]136, MRT-PCR positiveGlucose-6 phosphate dehydrogenase deficiencyNRInitial presentationCognitive impairment and decreased responsivenessSARS-CoV-2-mediated encephalitisDischarged home with regular follow-up in the neurology clinic
49Monti 2020, Italy
[68]		150, MRT-PCR positiveMild hypertensionAsymptomaticInitial presentationConfabulations and delirious ideas; day 4: impaired awareness and status epilepticusAutoimmune encephalitisDischarged after 4 months of hospitalization without neurological deficits
50Moriguchi 2020, Japan
[17]		124, MRT-PCR positiveNRMildInitial presentationHeadache, consciousness disturbance, generalized seizures, and status epilepticusSARS-CoV-2-mediated encephalitisNR
51Morvan 2020, France
[69]		156, MRT-PCR positiveMalnutrition, renal
lithiasis with left renal abscess and Mycobacterium abscessus pulmonary infection		NRInitial presentationComaSARS-CoV-2-mediated ANEDied
52Mullaguri 2021, USA [70]277, FRT-PCR positiveParkinson’s disease, cognitive impairment, and hypertensionSevereInitial presentationOriented to self but not to place or timeSARS-CoV-2-mediated AHNEDied
68, FRT-PCR positiveChronic lymphocytic leukemia and
hypertension		SeverePost-SARS-CoV-2 infection (5 days after SARS-CoV-2 infection)Comatose, persistent severe encephalopathyDied
53Natarajan 2020, India
[10]		113, FRT-PCR positiveHealthyMildInitial presentationHeadache and generalized tonic-clonic seizureSARS-CoV-2-mediated encephalitisDischarged home in a normal neurological state
54Oosthuizen 2021, South Africa [71]152, MRT-PCR positiveHealthyNRInitial presentationMultidirectional gaze-evoked nystagmus, dysarthria, and truncal and appendicular ataxiaSARS-CoV-2 mediated encephalitisDischarged while walking independently, mild emotional lability persisted
55Orsini 2021, Brazil [72]152, MRT-PCR positiveHealthySevereInitial presentationIntense agitation, cognitive impairment, tonic-clonic seizureSARS-CoV-2 mediated encephalitisDied
56Panariello 2020, Ecuador
[73]		123, MNRHealthyModerateInitial presentationPsychomotor agitation, anxiety, thought disorganization, persecutory delusions, dyskinesias and auditory hallucinationsAutoimmune encephalitisClinical condition improved
57Picod 2020, France
[74]		158, FSerology test positiveHypertension and chronic kidney diseaseAsymptomaticPost-SARS-CoV-2 infectionClonic seizure, aphasia, right-side hemiparesis, coma, and myoclonusSARS-CoV-2-mediated encephalitisDischarged from intensive care unit on day 17, with mild short-term memory impairment
58Pilotto 2020, Italy
[75]		160, MRT-PCR positiveHealthyMildInitial presentationFirst 5 days: irritability, confusion, and asthenia; day 4–5: cognitive fluctuation, at entry: severe akinetic syndrome, mutism, and inhibited, archaic reflexesSARS-CoV-2-mediated encephalitisDischarged with normal neurological features
59Pizzanelli 2021, Italy
[76]		174, FRT-PCR positiveMild hypothyroidismSevereInitial presentationDay 13: mild confusion and brief episode of impaired awareness;
day 14: generalized tonic-clonic seizure		SARS-CoV-2-mediated autoimmune limbic encephalitisDischarged on day 35
60Poursadeghfard 2021, Iran [77]118, FRT-PCR positiveHealthyNRInitial presentationBlurred vision, drowsy SARS-CoV-2-mediated encephalitisNR
61Rebeiz 2020, USA
[78]		130 s, MRT-PCR positiveHistory of alcohol abuseAsymptomaticInitial presentation1st admission: confusion, behavioral changes, psychotic features including hallucinations; 2nd admission: worsened mental status, non-verbal, progressive neurological deterioration, and seizuresSARS-CoV-2-mediated encephalitisDied
62Reddy 2021, USA
[79]		122, FRT-PCR positiveInfantile
seizures		AsymptomaticInitial presentation2 days of headache;
at entry: acute altered mental status; while hospitalized: status epilepticus		SARS-CoV-2-mediated encephalitisDied
63Sangare 2020, France
[80]		156, MRT-PCR positiveHypertensionSevereInitial presentationVegetative stateSARS-CoV-2-mediated encephalitisDischarged after 5.5 months, with mild attention deficit disorder
64Sarmast 2022, Pakistan [81]163, FRT-PCR positiveHypothyroidism and diabetes mellitusNRInitial presentationConfusion accompanied by restlessness, fearfulness, and visual hallucinations. She was anxious, agitated, and aggressive. Altered level of consciousness, slight tremors of the limbs, and psychomotor restlessnessSARS-CoV-2-mediated encephalitisTwo weeks post discharge, she was doing well, with no neurological signs and symptoms
65Sattar 2020, Pakistan
[82]		144, MRT-PCR positiveHealthyModerateInitial presentationDay 20: generalized tonic-clonic seizures and confusionSARS-CoV-2-mediated encephalitisDischarged on day 34 with normal neurological state
66Sharma 2022, USA [83]343, MRT-PCR positiveHealthyMildInitial presentationBitemporal headache, tonic-clonic seizures, Self-limiting hemorrhagic encephalitisDischarged with occasional headaches
43, MRT-PCR positiveHealthySeverePost-SARS-CoV-2 infection (5 days after SARS-CoV-2 infection)Non-verbal, and had
an episode of rapid eye fluttering and gaze deviation, acute respiratory distress syndrome		Self-limiting leukoencephalopathyDischarged but complained about recurrent headaches
52, MRT-PCR positiveDiabetes, hypertension, and hyperlipidemiaSeverePost-SARS-CoV-2 infection (3 weeks after SARS-CoV-2 infection)Bifrontal headache, blurred vision, left- and right-sided ptosis, ischemic third and
sixth nerve palsy		SARS-CoV-2-mediated encephalitisDischarged with assistance. No light perception in the left eye with complete ophthalmoplegia, intact vision in the right eye with ptosis
67Sofijanova 2020, Republic of Macedonia
[84]		19 months, infantRT-PCR positiveNRSevereInitial presentationTonic-clonic seizures, disturbed consciousness, shortness of breath, weakened reaction to painful stimuliNRNR
68Svedung Wettervik 2020, Sweden
[85]		140′s, FRT-PCR positiveHealthySevereInitial presentationComaSARS-CoV-2-mediated AHLEAfter TPE treatment for 5 days, patient showed clinical and biochemical improvements
69Tee 2022, Malaysia [86]169, MRT-PCR positiveHypertension and atrial fibrillationNRInitial presentationAltered behaviorSARS-CoV-2-mediated encephalitisSubsequently remained well, with no neurological sequelae
70Urso 2022, Italy [87]15, FRT-PCR positiveHealthyNRInitial presentationNeck swelling, right latero-cervical and painful lymphadenopathy,
altered mental status,
and drowsiness		SARS-CoV-2-mediated encephalitisDischarged when COVID-19 test came back negative
71Valadez-Calderon 2022, Mexico [88]128, MNRNo history of
chronic disease		MildPost-SARS-CoV-2 infection (2 weeks after SARS-CoV-2 infection)Incoherent
speech, somnolence, auditory hallucinations, suicidal
ideation, and generalized tonic-clonic seizures		Autoimmune encephalitis (anti-NMDAR and anti-glutamic acid decarboxylase 65 co-expression)Discharged home, but after six weeks-follow-up, he
continues physical rehabilitation and presents neurological sequelae related to mood changes, irritability, and agitation episodes
72Vandervorst 2020, Belgium
[89]		129, MRT-PCR positiveHealthyModerateInitial presentationConfusion, disorientation in time and space, immediate and short-term memory deficits, concentration and attention difficulties,
anxiety, paranoid delusions, followed by dysgeusia and anosmia		Suspected SARS-CoV-2-associated encephalitisImproved during hospitalization
73Woldie 2020, Canada
[90]		124, MRT-PCR positiveAIHASeverePost-SARS-CoV-2 infection (one week later at his follow-up appointment)Persistent headache, decreased level of consciousness, and seizure activity.SARS-CoV-2-mediated ANEDied
74Ye 2020, China
[91]		1NR, MRT-PCR positiveNRModerateInitial presentationConfusion, altered consciousnessSARS-CoV-2 associated encephalitisDischarged with cleared consciousness
75Zambreanu 2020, UK
[92]		166, FRT-PCR positiveNRMildInitial presentationConfusion, seizure, disoriented to
time and place, amnestic and mild word-finding difficulties		Limbic encephalitisNeurological recovery
76Zandifar 2020, Iran
[93]		249, MNot performedNRSevereInitial presentationSeizures; disorientation to place, time, and persons; and decrease of consciousnessSuspected SARS-CoV-2 associated encephalitisDied
39, MRT-PCR positiveModerateDisoriented, agitated headache, tonic seizure, decreased consciousness and non-responsive verbal or painful commandsSARS-CoV-2 associated encephalitis
77Zanin 2021, Italy
[12]		147, MRT-PCR positiveHealthyMildInitial presentationIntense headache, epileptic seizuresSARS-CoV-2 associated encephalitisDied
78Zuhorn 2020, Germany
[94]		154, MRT-PCR positiveArterial hypertension, obesity (BMI 34 kg/m2), obstructive sleep apnea syndromeModerateInitial presentationAggressiveness,
Disorientation, and stupor		Parainfectious encephalitisRecovered and was discharged with only mild cognitive impairment
Abbreviations: NR: not reported, M: male, F: female, T2DM: type 2 diabetes mellitus, AHLE: acute hemorrhagic leukoencephalitis, AIHA: autoimmune hemolytic anemia (AIHA), TPA: tissue plasminogen activator, AHNE: acute hemorrhagic necrotizing encephalitis, ANE: acute necrotizing encephalitis.
Table
Table 2. Diagnostic features of encephalitis in patients with COVID-19.
Table 2. Diagnostic features of encephalitis in patients with COVID-19.
No.Study IDNeuroimagingNeurophysiologySerum AnalysisCSF AnalysisOther Pathogen Investigation
Brain CT Scan ResultBrain MRI ResultEEG ResultWBCTotal Protein (mg/dL)Glucose (mg/dL)SARS-CoV-2Other Explorations
1Ahsan 2021NRAxial T2 showed left perirolandic cortex and posterior parietal lobe cerebral edema, and axial DWI showed restricted diffusion.Cerebral slowing with left focal slowingMOG IgG positiveElevated4846NROCB positiveBacterial or viral pathogens were negative
2Allahyari 2021Generalized brain edemaGeneralized brain edemaNRCRP 2+Elevated24155PositiveAnti-NMDAR Positive, HSV 1 and HSV 2 DNA negativeNR
3Andrea 2020Presented with non-specific
diffuse cortical atrophy		NRTriphasic waves were observedNormal CRP and LDH,
severe hyponatremia		Normal6149NegativeNoneHSV negative
4Ayatollahi 2020Normal1st admittance: normal; 2nd admittance: signal hyperintensities on FLAIR and T2-weighted sequences in the claustrum bilaterally1st admittance: slow wave activity; 2nd admittance: moderate bilateral non-epileptiform abnormalitiesThrombocytopenia, normal RBC, WBC and hemoglobin, CRP. ANA, aPL, aCL, anti-dsDNA, and ANCA were negativeElevated3041NegativeNoneHSV negative
5Ayuningtyas 2022NRNo lesion or intracerebral or intracerebellar pathological enhancement was foundNRIncreased CRP level, and increased D-dimer levelElevated10863PositiveNo Bacteria and AFBAnti-HIV, HbSAg, anti-HCV, HSV, and CMV negative
6Ayuso 2020Normal2nd admittance: hyperintense
lesions in the caudal vermis and right flocculus, and
contrast enhancement was observed in the floor of the fourth
ventricle		NormalNormalNormal4170NROCB, anti-Hu, anti-Yo, anti-Ri, anti-CV2,
anti-Ma2, and anti-amphiphysin abs were negative		Anti-GD1 was positive. HIV, VZV, EBV, CMV, and Mycoplasma
Pneumoniae were negative
7Babar 2020NormalNormalGeneralized
slowing		Elevated CRP, ferritin, TPO ab, and D-dimer. Negative anti-NMDAR ab, anti-GAD ab, VGKC ab, ANA, ANCA, IgM anti-β2-GPI ab, anti-DNase B ab, anti-streptolysin ab, IL-1 β, IL-6, IL-10, IL-2, C3, and C4Normal1874NegativeNoneGram bacteria negative
8Benameur 2020NRCerebral hemispheric restricted diffusion and cerebral edemaNRIncreased levels of anti-S1 IgM; anti-E IgM, IL-6, IL-8, IL-10, IP-10, and TNF-αElevated>20040NegativeNoneInfluenza A virus positive, influenza B virus negative
NRSplenium lesion and FLAIR recoveryDiffuse slowingNormal37111NegativeNoneBacterial or viral pathogens were negative
NREquivocal fluid-attenuated inversion recovery, FLAIR abnormality in the right temporal lobeNRNormal2188NegativeNoneBacterial or viral pathogens were negative
9Bernard-Valnet 2020NRNormalNonconvulsive,
focal status epilepticus, slowed theta
background rhythm		NRMild elevated46.6NRNegativeNoneBacterial or viral pathogens were negative
NRNormalNRNRMild elevated46.1NRNegativeNone
10Bhavsar 2020NormalNRSlow background without epileptiform discharges or seizuresNormal CBC, CRP and ESR, negative autoimmune encephalopathy antibody panel, hyponatremiaElevated17335NegativeNoneBacterial or viral pathogens were negative
11Bodro 2020NormalNormalNRElevated D-dimerElevated105.580NegativeElevated
IL-1β, IL-6, ACE		Bacterial or viral pathogens were negative
NormalNormalNRElevated CRP, ferritin, LDH, and D-dimer, mild platelet reductionElevated115.554NegativeElevated
IL-6, ACE		NR
12Burr 2021NRNormalNRNormal CRP and ESR and positive NMDAR-IgG positivityNR2556NegativeNoneBacterial or viral pathogens were negative
13Cao 2020NRBilateral hyperintense lesions in the deep and periventricular
supratentorial white matter, either punctiform and slightly diffuse (cases 1–3) or diffuse and confluent (cases 4 and 5), associated with lesions in the pons for two patients
(cases 1 and 2)		Unspecific slow-wave activityElevated IL-6normal32NRNegativeNormal IL-6NR
Normal IL-626NegativeNormal IL-6
Elevated IL-6115NegativeElevated IL-6
Elevated IL-618NegativeNone
Elevated IL-618NegativeNormal IL-6
14Casez 2021NRHyperintensity of the olfactory tracts on T2 fluid-attenuated inversion recovery, and diffusion-weighted imagingNRNR8 WBCNormalNRNegativeNoneNR
15Chalil 2020Extensive bilateral parietal and occipital intraparenchymal hemorrhage and extensive
edema causing
hydrocephalus		Cortical gadolinium enhancement with hyper-intense T2 and
FLAIR signal surrounding the hemorrhages		Mild diffuse slowingElevated D-dimer, CRP, and ferritinElevatedNRNRNegativeElevated CSF IgG ratioNegative for VZV, HSV, and ENV
16Cheraghali 2021NRSymmetric, cortical, and juxtacortical high T1 and T2 signal abnormality, in bilateral parieto-occipital lobesNRElevated level
of blood sugar, AST, ALT, ESR, LDH, and positive CRP test		Normal15100PositiveNegative for bacterial growthHSV 1 and HSV 2 negative
17Dahshan 2022NormalNormalNRNRNormalNormalNormalNRHSV 1 and HSV 2 negativeNR
18Dono 2021NRAxial T2 fluid-attenuated
inversion recovery (T2-FLAIR) and axial diffusion-weighted
imaging showed
hyperintense lesions of the bilateral parietal cortex, left temporal cortex, and right cingulate cortex		Epileptiform abnormalities, continuous sharp
waves and spike-and-slow-wave complexes		Slight lymphocytopenia, elevated D-dimer, normal CRPElevated4778NegativeOCB positiveHSV, EBV, CMV, and VZV were negative
19Duong 2020 and Huang 2020NormalNRGeneralized slowing with no epileptic
discharges		NormalElevated100120PositiveNoneNegative for bacterial culture and HSV 1
20Durovic 2021NRMultiple disseminated pathological T2 and FLAIR hyperintensitiesNRLyme borreliosis and HIV was negative, MOG antibody positiveElevated39.964NegativeHSV 1 and HSV 2 negativeComplete recovery over the follow-up of 2 months
21Efe 2020NRHyperintense
signal in the left temporal lobe in T2 and T2 FLAIR		NRNRNRNRNRNRNoneNR
22El Aoud 2021NormalFocal hyperintense signal in the splenium of the corpus callosum on T2 FLAIR and diffusion-weighted imagesSlow oscillations
without epileptiform features		Lymphophenia, elevated CRP and ferritin, hypoalbuminemia,
ANA, and ANCA were negative		normal4955NRNoneMycoplasma pneumoniae, syphilis, HIV, influenza A and B were negative
23Elmouhib 2022NormalHigh-signal intensity lesion on DWI, T2 FLAIR in the temporal lobes, without diffusion restriction on apparent diffusion coefficient mapNRCRP at 200 mg/L with a negative PCT at 0.05 μg/L, ferritin at 2300 μg/LNormal10063NRNRNR
24Esmaeili 2022NRExtensive high signal lesions in T2W and FLAIR sequences on bilateral cerebral hemispheres, para-ventricular and subcortical white matter, middle cerebellar peduncles, centrum semi vale, corpus callosum, basal ganglia, thalami, midbrain, and pons. Post-contrast MRI showed sparse enhancements on midpart of the midbrain and left parietal lobeNRElevated CRP and ESR, prothrombin time and partial thromboplastin time were normalNormalNormalNormalNegativeEBV, HSV, CMV, VZV negativeNR
25Etemadifar 2020Generalized brain edema and signs of brain herniationGeneralized
brain edema, downward herniation of cerebellar tonsils and brain stem, and FLAIR hyperintensities in bilateral cerebral cortices and corpus striatum		NormalLeukocytosis, lymphopenia, elevated D-dimerNRNRNRNRNoneNR
26Ferdosian 2021NRDiffuse brain edemaNRCPK: 42, LDH: 554,
CRP: weakly +, ESR: 6. COVID-19 PCR was negative		Normal3057PositiveHSV, Enterovirus negativeNR
27Freire-Álvarez 2020NormalExtensive
involvement of the brain, including cortical and subcortical right frontal regions, right thalamus, bilateral temporal lobes and cerebral peduncles, with no leptomeningeal enhancement		NRElevated ferritin, IL-6, and D-dimerElevated19848NegativeNoneCMV, HSV 1 and 2, human HHV 6, HPeV, and VZV negative
28Gaughan 2021NRTwo tiny punctate T2/FLAIR hyper-intensities in the centrum semiovale bilaterallyDelta slowingAutoimmune antibody panel negativeNR4352.2NegativeAutoimmune antibody panel negativeHSV and VZV negative
29Ghosh 2020NRNon-enhancing altered intensity lesions in the left high fronto-parietal and right posterior parietal areas with peri-lesional edema; isolated cortical venous thrombosisNRAll blood parameters normalElevated6070NegativeElevated IgG index, and OCB negativeBacterial or viral pathogens were negative
30Grimaldi 2020NRNormalSymmetric diffuse background
slowing		Elevated fibrinogen and CRP, IgG autoantibodies extremely highNormal49NRNegativeOCB negative and IgG autoantibodiesNR
31Gunawardhana 2021Bi-frontal white matter oedemaT2 FLAIR
hyperintensities in the periventricular white matter, mainly clustered around frontal and occipital horns. FLAIR hyperintensities were also noted in the splenium, basal ganglia, and ventral pons		Low wave discharges consistent with encephalitisHemoglobin, liver function tests, creatinine and electrolytes were within normal limits, inflammatory markers (ESR, CRP) were mildly elevatedElevatedNormalNormalSARS-CoV-2 IgM and IgG antibodies are positive SARS-CoV-2 RNA negativeHSV 1 and HSV 2, Japanese encephalitis, VZV were negativeNR
32Haider 2020NormalSmall acute/subacute lacunar infarcts and a patchy area of T2 bright signals in the cortical and periventricular regions, consistent with cerebritisGlobal cerebral dysfunction and severe toxic metabolic encephalopathyAutoimmune antibody panel negativeNormal7786NegativeNoneBacterial or viral pathogens were negative
33Hassan 2021NRMild periventricular ischemic changesNRIncreased CRP, D-dimer, and serum ferritinNormalNRNRPositiveHSV, OCBs were negativeNR
34Hayashi 2020NRAbnormal hyperintensity in the splenium of corpus callosum on diffusion-weighted imageNRElevated CRP, lymphopeniaNRNRNRNRNoneNR
35Kahwagi 2021NRNormalOverall slowing of the pattern with the presence of diffuse pseudoperiodic complexes predominating in fronto-temporal areaElevated CRPNormal76NRNRNoneNR
36Kamal 2020Multiple hypodensities
in the external capsules bilaterally, the insular cortex, and the
deep periventricular white matter of the frontal lobes bilaterally		Abnormal signal intensity in the temporal lobe cortex bilaterally in a rather symmetrical fashion. In addition, the involvement of the parasagittal frontal lobes
bilaterally was evident as well, displaying bright signals on
T2-fluid-attenuated inversion recovery and T2-weighted
images with corresponding diffusion restriction		Did not display any significant
epileptic discharges, possibly due to the masking effect of lorazepam		Elevated D-dimerNormal5567PositiveNormal LA, RF, ANA and aCLMycobacterium
Tuberculosis, Gram bacteria, HSV, HHV, and VZV were negative
37Kasturiarachi 2022NRContrast-enhancing lesion in the left occipital, temporal, and frontal lobes, the vermis folia, and tectal plate colliculi; hyperperfusion on arterial spin labeling in the left hemisphereLeft hemispheric poly spike and wavesElevated LDH, reticulocyte count and bilirubin, schistocytes, and low haptoglobin. Positive ANA, high anti-SSA (anti-Ro) and anti-SSB (anti-La) antibodies, and significantly elevated COVID-19 antibodyNRNRNRNegativeMeningitis/encephalitis panel negativeNR
38Khoo 2020NRNormalNormalElevated CRP and D-dimerNormalNormalNormalNegativeAnti-NMDAR ab and A panel of antineuronal
abs and OCB were negative		NR
39Kimura 2021NRNo significant abnormalitiesNo evidence of seizure activity nor
response to photic and sound stimuli		Seropositive for
anti–SARS-CoV-2 antibodies		Normal20164NegativeOCBs positiveCampylobacter
jejuni, Haemophilus influenzae, Mycoplasma pneumoniae,
cytomegalovirus, and EBV negative
40Koh 2022Patchy ground-glass opacities on bilateral lung
fields, compatible with COVID-19 pneumonia		Diffuse cortical high signal intensities,
especially on bilateral insula with increased arterial spin labeling signals		Repeated high-amplitude polymorphic delta activities
from the right frontotemporal area evolving to generalized
1–2 Hz spike-wave discharges, suggesting an impending focal status epilepticus		IL-6 was
mildly elevated to 21.7 pg/mL, CRP level normal		ElevatedNRNRNegativeElevated IL-6HSV, VZV, enterovirus, tuberculosis,
EBV, toxoplasmosis, and syphilis negative
41Kumar 2020Hypodensities in both thalami and left caudate nucleus; left parasellar-middle cranial fossa massLeft parasellar-middle cranial fossa mass
(MRI was performed about 2 weeks earlier than CT)		NRLeukocytosisNormalElevatedNRNRNoneHSV and VZV were negative
42Kumar 2022NRSubcortical volume loss (right occipital and left parieto occipital) with cystic changes, tiny hemorrhages at the caudothalamic groove with loss of myelination at the posterior limb of internal capsuleNormalCOVID Ig G And Ig M antibodies were positiveNormalNormalNormalNRNRNR
43Marques 2022NormalDid not show any pathological changesModerate encephalopathyElevated LDH and d-dimersElevated8259NegativeHSV, VZV, cytomegalovirus negativeHSV, HIV, VZV negative
NormalDid not show any pathological changesMild encephalopathy, without epileptiform activityHSV 1–2, HIV, and VZV NegativeNormal1693NegativeHSV, VZV, cytomegalovirus negativeNR
44McAbee 2020NegativeNRFrontal intermittent
delta activity		NRMild elevated9792NRNoneNR
45Mekheal 2022Without contrast, an old left
cerebellar infarct, with no evidence of acute infarct or hemorrhage		Old infarct, acute infarct involving the left cerebellum, as well as an effacement of the left temporal horn and edema
within the left pons, midbrain, left temporal lobe, and surrounding the basal ganglia		Moderate-severe diffuse encephalopathy without epileptiform discharges or seizuresElevated ESR, CRP, and D-dimer, serum COVID-19 IgG antibody positiveElevated14575NegativeMeningitis/encephalitis panel by PCR were negative, including all microbial culturesNR
46Meshref 2021Right temporal hypo-dense areaIll-defined area of
faint low signal intensity lesion in T1, hyperintense in T2. FLAIR images showed partial restriction in DWI with no significant enhancement post IV gadolinium contrast injection, involving the right cerebral hemisphere, mainly at the temporal area, suggesting encephalitis		NRNRNRNormalNormalNRNo bacterial growth, herpes virus was negativeNR
47Mierzewska-Schmidt 2022NRDiffuse areas of oedema associated with numerous symmetrical changes with punctate hemorrhages in basal ganglia, thalami, brainstem, and cerebral gray matterNRLow Hb 9.3 g/dL and Platelet count 183 × 103/μL, CRP 7.4 mg/L, D-dimers 0.97Elevated660.00< 10PositiveElevated lactic acid, meningoencephalitis PCR panel was negativeAll bacterial cultures were negative
48Miqdad 2021UnremarkableNormalDifferent abnormalities suggestive of encephalitisCRP, D-dimer, and procalcitonin were highElevated8322.59NRHSV PCR and gram stain negativeNR
49Monti 2020NRNormalAbnormalElevated levels of IL-6ElevatedNRNRNROCB and anti-NMDAR ab positive, with elevated levels of IL-6 and IL-8Bacterial or viral pathogens were negative
50Moriguchi 2020NormalDiffusion
-weighted images showed hyperintensity along the wall of inferior horn of right lateral ventricle. FLAIR images showed hyperintense signal changes in the right mesial temporal lobe and hippocampus with slight hippocampal atrophy		NRElevated levels of WBC and CRPMild elevatedNRNRPositiveNRHSV and VZV were negative
51Morvan 2020Acute
hydrocephalus with diffuse cerebral edema, spontaneous bilateral thalamic hyperdensities,
with discrete contrast enhancement and spontaneous hyperdensity in subarachnoidal spaces.		Hypersignal of both thalami brainstem and
cerebellum with some hemorrhagic component on T2 sequences		NRElevated levels of CRP, fibrinogen, and D-dimer
Low Hb, high AST, low factor V, high troponin, high creatinine, very low kaliemia		Normal79NRNegativeNoneHIV negative
52Mullaguri 2021Axial sections of the brain showed punctate
hemorrhages in the right frontal and left frontal and parietal areas		Axial section showed hyperintensities in bilateral centrum semiovale areas. MRI of the brain showing innumerable punctate microhemorrhages in the cerebellar peduncles and subcortical regions of bilateral hemispheres, including bilateral basal ganglia and internal capsulesNRHyponatremia (132 mMol/L), significant elevations in
D-dimer, LDH, ferritin, CRP,
and CK		NRNRNRNRNRNR
53Natarajan 2020NRNormalNormalNRElevated8677NegativeNoneHSV, CMV, and VZV were negative
54Oosthuizen 2021Central
midbrain hypodensity		Features consistent with brainstem encephalitisNormalElevated ESRElevated3765PositiveImmunoglobulin G index 0.62, SARS-CoV-2 antibody negativeTests for infections and malignancy negative
55Orsini 2021NRNormalNormalNRNormal6053PositiveBacterial culture negativeNR
56Panariello 2020NormalNRTheta activity at 6 HzElevated CRP and D-dimer with negative ANA, ANCA, anti-ENA, aCL, and anti-β2-GPI absNR65.470NegativeElevated IL-6 and anti-NMDAR abHSV, EBV, CMV, VZV, and enterovirus were negative
57Picod 2020NormalBilateral lesions (hypersignal or enhancement of meninges, cortical and subcortical regions spread over the insula, the cingula, the medial part of occipital areas, and the internal part of the left-side temporal lobe)Diffuse intermittent periodic activityModerately elevated IL-6Normal28NRNegativeElevated IL-6 and OCB negativeHSV negative
58Pilotto 2020NormalNormalGeneralized
slowing, with decreased reactivity to acoustic stimuli		Elevated D-dimer, a wide immunological
screening of immune-mediated encephalitis was negative		Mild elevated69.6NRNegativeSlightly elevated IL-6, strongly elevated IL-8, TNF-α and β2MNeurotropic viruses negative
59Pizzanelli 2021NormalBilateral symmetrical mesial temporal lobes T2/FLAIR/DWI hyperintensities, with mild hippocampal thickeningAutoimmune panel for encephalitis negativeElevated CRP and fibrinogenNormal10467NegativeOCB and autoimmune panel for encephalitis negativeNeurotropic viruses negative
60Poursadeghfard 2021NRFLAIR increased signal intensity in the cortical and subcortical regions of both mesial temporal lobe as well as both side hippocampal tails, with relative symmetrical appearance without evidence of significant enhancement or restricted DWI compatible with viral or autoimmune encephalitisNRNRNRNRNRNRNRCat-scratch disease, toxoplasmosis, syphilis, Lyme disease, brucellosis, HIV, VZV, HSV, CMV, EBV, and hepatitis B and C were negative
61Rebeiz 2020A questionable subarachnoid hemorrhage within the mesial parietal region and nonspecific
hypoattenuation in the splenium of the corpus callosum		1st MRI: DWI and FLAIR hyperintensity of the splenium of corpus callosum; 2nd MRI (after readmission): new abnormal T2/FLAIR hyperintense and restricted diffusion involving the left thalamus,
right parasagittal frontal cortex, and bilateral genu of the corpus callosum		Generalized slowingVES 27;
Normal IL-6 and CRP		Elevated29756NegativeNoneNeurotropic viruses negative
62Reddy 20214 days after admission: severe diffuse cerebral edema
with cerebellar tonsillar herniation		No acute intracranial
process		NRNRNormal10888NRNoneBacterial or viral pathogens were negative
63Sangare 2020NRMultiple small hemorrhagic
lesions in the pontine tegmentum, bilateral subinsular region
Poorly reactive delta slow wavesNRNormalNormalNormalNRNoneNR
64Sarmast 2022UnremarkableHyperintense signals in frontoparietal and parietotemporal lobes on FLAIR/T2 sequenceNRMildly elevated CRP, elevated LDH, CPK, ferritin, and D-dimerNormal6681NegativeVZV PCR, HSV 1–2 PCR, CMV PCR, bacterial antigen negativeNegative for HSV 1–2, HIV, enterovirus, and VZV virus
65Sattar 2020Day 20: few scattered foci of white
matter hypo-attenuation		Day 25: abnormal medial cortical signals in the bilateral frontal lobe regionNRAutoimmune antibody panel negativeMild elevated3975PositiveCSF color pinkishBacterial or viral pathogens were negative
66Sharma 2022left temporal
hypodensity		Intense focal edema within the left hippocampus with mild restricted diffusion, postcontrast enhancement, and hemorrhage seen on susceptibility-weighted imagingNormalCreatinine of 1.3 mg/dL, CRP of 42.4 mg/L, ESR of 95 mm/h, CK 858 IU/L, D-Dimer of 1821 FEU, fibrinogen of 644 mg/dL, ferritin of 1352.9 ng/mL, LD of 392 IU/L, prothrombin
time (PT/INR) of 1.3/15		Elevated4459NRGram stain, bacterial culture, and meningitis/
encephalitis panel were negative. VZV PCR, cryptococcal antigen, culture, AFB smear and culture, and CMV PCR were negative. VZV IgG elevated		NR
Small right temporal hyperdensity (0.6 cm diameter)
suggestive of a hemorrhage with normal vasculature		Right anterior temporal lobe intraparenchymal hemorrhage; additional multiple scattered foci of
susceptibility artifact particularly in the gray–white junctions and corpus callosum; and sulcal FLAIR hyperintensity in the right frontal, biparietal, and left temporal lobes		NRElevated IL-6, fibrinogen, and thrombocytopeniaElevated11828NRMeningitis/encephalitis panel, AFB smear and culture, cryptococcal antigen, and VZV PCR, CMV PCR, CSF cytology were negativeNR
1st admission: stenosis of the cavernous
segment of the right ICA. 2nd admission: unremarkable		1st admission: mild periventricular white matter disease. 2nd admission: multiple punctate foci of restricted diffusion in the bilateral frontal, parietal, occipital, and temporal lobes, mild meningeal enhancement of the anterior and middle cranial fossa, and opacification of multiple ethmoid and mastoid air cellsNR1st admission; creatinine of 1.4 mg/dL, ESR 111 mm/h, CRP 43.5 mg/L, and HbA1c 12.6%. 2nd admission: fibrinogen of >1000 mg/dL, ferritin of 743 ng/mL, ESR of >130 mm/h, CRP of 313 mg/L, PT/INR of 19/1.6, procalcitonin of 1.24 ng/mL, and antithrombin-3
activity of 62%		Elevated8278NRBorrelia burgdorferi IgM/IgG titer (0.09 LIV, 0.09 LIV), negative CSF ACE, VDRL,
and cryptococcal antigen, EBV PCR positive		AIDP, myasthenia gravis, or vasculitis, secondary infections, mycoplasma IgM, anti-cardiolipin antibodies, B-2 glycoprotein, anti-Xa essay, HIV antibodies,
hepatitis panel, serum cryoglobulin PAVAL, autoimmune encephalitis panel were negative
67Sofijanova 2020Enlargement of the lateral ventricles, intraventricular masses, pronounced internal hydrocephalus.NRNRNormalNR202.791.4NRNoneNR
68Svedung Wettervik 2020White matter brain edema with compressed
convexity sulci		Increased white matter intensity on flair images, microhemorrhages with involvement of basal ganglia on susceptibility-weighted imagingPronounced, generalized
slowing over both hemispheres, no electrographic epileptic activity		Mild increased IL-6ElevatedNR86.4NegativeElevated levels of IL-6Negative for bacteria and neurotropic viruses
69Tee 2022Noncontrast brain CT revealed an old right lenticular infarctPerformed 1 month later, normal findingsPerformed 3 weeks
later, normal findings		NRElevated116NRPositiveNRNR
70Urso 2022NRCNS involvement, suggestive of encephalitisA slow base rhythm (theta-delta) together with synchronous bilateral potentials formed by slow waves with predominance on the right side.NRNormal27NormalNegativeNo bacterial or tuberculous infectionHSV1, varicella-zoster,
EBV, and CMV were negative
71Valadez- Calderon 2022, MexicoNRHyperintensities in the bilateral anterior cingulate cortex and temporal lobesSubcortical dysfunction in frontal, temporal,
and occipital regions		NormalNormalNormalNormalNegativeNRNR
72Vandervorst 2020NormalAsymmetric FLAIR hyperintensity of the left medial temporal cortex associated with mild gyral expansionGeneral excess
of beta-rhythm		NRNormalNormalNormalNegativeNoneNegative for enterovirus and HSV
73Woldie 2020Non-specific
symmetric cerebral enhancement		T2/FLAIR hyper intensity on the medial aspect of each temporal lobe, bilateral basal ganglia, and medial thalami consistent with severe acute necrotizing encephalitisNRElevated LDHNRNRNRNRNRPositive for Cryptococcus neoformans
74Ye 2020NormalNRNRLow WBC and lymphocytesNormal2756.5negativeNoneNegative for bacterial or tuberculous infection
75Zambreanu 2020NormalNon-enhancing,
symmetrical T2 and FLAIR hyperintensities in mesial temporal lobes and medial thalami and to a lesser extent upper pons, as well as scattered subcortical white matter hyperintensities		NRElevated CRP, lymphopeniaNormal10063NegativeAutoimmune antibody panel negativeNegative for streptococci, meningococcus,
haemophilus, listeria, Escherichia coli, HSV
1 and 2, HHV6,
enteroviruses, parechovirus, CMV, VZV,
and Cryptococcus
76Zandifar 2020Diffuse brain parenchymal edema and reduced lateral ventriclesNRNRLeukocytosis and lymphopeniaMild elevated7030NegativeNoneNR
NRLeukocytosis and lymphopenia
and LDH elevated		Mild elevated7433Positive
77Zanin 2021Increasing vasogenic oedema in the right temporo-fronto-parietal region with extension to the capsular region, to the cerebral peduncle and in the ipsilateral
mesencephalic region. Severe compressive effect on the right lateral ventricle		Severe vasogenic oedema of the white matter with 10 mm shift of the midline and compression of the right lateral ventricle; DWI: extensive cortical marked restrictionNRIncreased CRP and WBC with lymphopeniaNRNRNRNRNoneNR
78Zuhorn 2020NRSignal alterations within the claustrum/external capsule region, showed reduced diffusionNRLDH, D-dimer, myoglobin, IL-6 and CRP, IgA and IgG positive for SARS-CoV-2Mild elevated39.657NegativeNoneNegative for HSV, VZV, cytomegaly and Epstein Barr virus
Abbreviation: NR: not reported, AFB: acid-fast bacilli, CT: computed tomography, WBC: white blood cells, RBC: red blood cell, MOG: myelin oligodendrocyte glycoprotein, AST: aspartate aminotransferase, ALT: alanine aminotransferase, HSV: herpes simplex virus, CRP: C-reactive protein, LDH: lactate dehydrogenase, FLAIR: fluid-attenuated inversion recovery, ANA: antinuclear antibody, aCL: anticardiolipin antibody, dsDNA: double-stranded DNA, ANCA: antineutrophil cytoplasmic antibodies, NMDAR: N-methyl-D-aspartate receptor, GAD: glutamic acid decarboxylase, VGKC: voltage gated potassium channel, IL: interleukin, GPI: glycoprotein I, ab: antibody, TPO: thyroid peroxidase, IP: induced protein, CBC: complete blood count, ESR: erythrocyte sedimentation rate, CPK: creatine phosphokinase, CK: creatine kinase, VZV: varicella-zoster virus, ENV: erythrocytic necrosis virus, EBV: Epstein–Barr virus, CMV: cytomegalovirus, OCB: oligoclonal band, DWI: diffusion-weighted imaging, HIV: human immunodeficiency virus, HHV: human herpes virus, HPeV: human parechovirus, LA: lupus anticoagulant, RF: rheumatoid factor, ENA: extractable nuclear antigens, β2M: β2-microglubulin. Normal protein level: 15–45 mg/dL, normal glucose level: 40–70 mg/dL.
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Islam, M.A.; Cavestro, C.; Alam, S.S.; Kundu, S.; Kamal, M.A.; Reza, F. Encephalitis in Patients with COVID-19: A Systematic Evidence-Based Analysis. Cells 2022, 11, 2575. https://doi.org/10.3390/cells11162575

AMA Style

Islam MA, Cavestro C, Alam SS, Kundu S, Kamal MA, Reza F. Encephalitis in Patients with COVID-19: A Systematic Evidence-Based Analysis. Cells. 2022; 11(16):2575. https://doi.org/10.3390/cells11162575

Chicago/Turabian Style

Islam, Md Asiful, Cinzia Cavestro, Sayeda Sadia Alam, Shoumik Kundu, Mohammad Amjad Kamal, and Faruque Reza. 2022. "Encephalitis in Patients with COVID-19: A Systematic Evidence-Based Analysis" Cells 11, no. 16: 2575. https://doi.org/10.3390/cells11162575

APA Style

Islam, M. A., Cavestro, C., Alam, S. S., Kundu, S., Kamal, M. A., & Reza, F. (2022). Encephalitis in Patients with COVID-19: A Systematic Evidence-Based Analysis. Cells, 11(16), 2575. https://doi.org/10.3390/cells11162575

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