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Neuropsychiatric manifestations in a patient with prolonged COVID-19 encephalopathy: case report and literature review

Published online by Cambridge University Press:  21 September 2021

J. O’Leary ,
J. McAndrew ,
A. Shukralla  and
K.C. Murphy
J. O’Leary*
Affiliation:
Department of Liaison Psychiatry, Beaumont Hospital, Dublin, Ireland
J. McAndrew
Affiliation:
Department of Liaison Psychiatry, Beaumont Hospital, Dublin, Ireland
A. Shukralla
Affiliation:
Department of Neurology, Beaumont Hospital, Dublin, Ireland
K.C. Murphy
Affiliation:
Department of Liaison Psychiatry, Beaumont Hospital, Dublin, Ireland Department of Psychiatry, Royal College of Surgeons in Ireland, Dublin, Ireland
*
Address for correspondence: J. O’Leary, Email: [email protected]
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Abstract

While the respiratory complications of COVID-19 infection are now well known, psychiatric manifestations are an emerging issue. We report a case of prolonged encephalopathy secondary to COVID-19 which was associated with prominent neuropsychiatric features. The patient went on to develop sub-clinical seizures, a rare but recognised complication of SARS-CoV-2.

Keywords

COVID-19deliriumencephalopathy
Type
Case Report
Information
Irish Journal of Psychological Medicine , Volume 40 , Issue 3 , September 2023 , pp. 487 - 490
Copyright
© The Author(s), 2021. Published by Cambridge University Press on behalf of The College of Psychiatrists of Ireland

Introduction

The newly identified SARS-associated coronavirus (SARS-CoV2) emerged in Wuhan, China, in late 2019, and rapidly spread globally (Wuhan Municipal Health Commission, 2020; Lu et al. Reference Lu, Stratton and Tang2020; Hui et al. Reference Hui, Azhar, Madani, T., Ntoumi, Kock, Dar, Ippolito, Mchugh, Memish, Drosten, Zumla and Petersen2020; Paules et al. Reference Paules, Marston and Fauci2020). Coronavirus disease (COVID-19) was declared a pandemic by the World Health Organisation (WHO) on March 11 2020 (WHO, 2020). The first confirmed case of coronavirus in the Republic of Ireland was announced on the 29 February 2019 (Irish NPHET Statement, 2020).

High rates of anxiety, depression, post-traumtic stress disorder, distress and stress have been reported in the general population during the COVID-19 pandemic, (Kelly, Reference Kelly2020). Risk factors specific to distress include the presence of psychiatric or chronic illness (Xiong et al. Reference Xiong, Lipsitz, Nasri, Lui, Gill, Phan, Chen-Li, Iacobucci, Ho, Majeed and McIntyre2020). Other than prior psychiatric disorder, those with greater levels of pandemic-related disruption in daily life are more likely to show signs of depression, anxiety and trauma-related symptoms (Sherman et al. Reference Sherman, Williams, Amick, Hudson and Messias2020).

COVID-19 has been shown to be associated with an increased incidence of first psychiatric disorder up to 3 months after diagnosis, while a previous psychiatric diagnosis may be an independent risk factor for COVID-19 diagnosis (Taquet et al. Reference Taquet, Luciano, Geddes and Harrison2021). A large study of 40,469 COVID-19 adult patients found that 22.5% had neuropsychiatric manifestations. While the most common included anxiety and related disorders (4.6%), a broad range of presentations including sleep disorders, affective disorders, psychosis, encephalopathy and seizure were noted (Nalleballe et al. Reference Nalleballe, Reddy Onteddu, Sharma, Dandu, Brown and Jasti2020).

A UK-based surveillance project of neuropsychiatric and neurological complications of SARS-CoV-2 found that in COVID-19 patients with altered mental state, 92% of these were new diagnoses of neuropsychiatric disorders. New-onset psychosis, neurocognitive syndrome and affective disorders were recorded, (Varatharaj et al. Reference Varatharaj, Thomas, Ellul, Davies, Pollak and Tenorio2020).

In patients presenting with COVID-19, it is estimated that 36% will have neurological symptoms, including impaired consciousness, dizziness, headache and neuromuscular dysfunction (Mao et al. Reference Mao, Jin, Wang, Hu, Chen, He, Chang, Hong, Zhou, Wang, Miao, Li and Hu2020). A study of critically ill patients with COVID-19 found that 74% had COVID-19 related encephalopathy and common MRI findings were diffuse deep white matter, corpus callosum and basal ganglia T2/FLAIR hyperintensity (Scullen et al. Reference Scullen, Keen, Mathkour, Dumont and Kahn2020). An analysis of case reports and case series suggested that encephalopathy is more common in patients of 50 years or more and is more common in critically ill patients (Garg et al. Reference Garg, Paliwal and Gupta2020). However, in most patients, cerebral spinal fluid (CSF) does not demonstrate evidence of encephalitis. Although SARS-CoV-2 RNA can be detected in CSF with polymerase chain reaction (PCR) testing (Huang et al. Reference Huang, Jiang and Huang2020), repeated negative CSF has been reported with concurrent COVID-19 and neurological disease (Al Saiegh et al. Reference Al Saiegh, Ghosh, Leibold, Avery, Schmidt, Theofanis, Mouchtouris, Philipp, Peiper, Wang, Rincon, Tjoumakaris, Jabbour, Rosenwasser and Gooch2020).

While there are several case reports of patients with COVID-19-related encephalopathy with associated subclinical seizures (Bernard-Valnet et al. Reference Bernard-Valnet, Pizzarotti, Anichini, Demars, Russo, Schmidhauser, Cerutti-Sola, Rossetti and Du Pasquier2020; Vollono et al. Reference Vollono, Rollo, Romozzi, Frisullo, Servidei, Borghetti and Calabresi2020; Somani et al. Reference Somani, Pati, Gaston, Chitlangia and Agnihotri2020; Balloy et al. Reference Balloy, Leclair-Visonneau, Péréon, Magot, Peyre, Mahé and Derkinderen2020), little attention has been paid to the neuropsychiatric presentation of these cases.

In this case report, we present a case of prolonged encephalopathy secondary to COVID-19 which was associated with prominent neuropsychiatric features

Case

A 56-year-old White Irish male presented to the Emergency Department of Beaumont Hospital, a large Dublin academic teaching hospital, complaining of chest pain, shortness of breath and cough, 2 weeks after the first COVID-19 case was diagnosed in Ireland. His past medical history included hypertension, hypercholesterolaemia and drug-induced hepatitis (from a prescribed antibiotic). He was apyrexic and normotensive with a respiratory rate of 20. Sp02 was 94% on room air. The patient was alert and coherent.

C-Reactive Protein (CRP) was raised at 54 mg/L (normal range <10 mg/L) while other inflammatory markers were within normal ranges. Electrocardiogram was unremarkable. Troponin level was 15 ng/Land 14 ng/L on serial data (normal range <14 ng/L). A coronary angiogram showed no obstructive coronary disease. CT Thorax with contrast showed multifocal mucous plugging with subadjacent foci of peribronchovacular nodularity and groundglass change. SARS-CoV2 PCR nasopharyngeal swab was negative. The patient was treated for community-acquired bacterial pneumonia with IV amoxicillin and was discharged with a prescription for a further 5 days of oral amoxicillin.

The patient represented to the Emergency Department 6 days later, with confusion, agitation and complaining of ‘pressure in the head’. His family gave a collateral of rapidly progressive disorientation, forgetfulness and difficulty using his phone, driving and performing complex tasks. The patient had a good functional and cognitive baseline. He was employed on a full-time basis in a skilled job.

On examination, he was amnestic with executive dysfunction, significant attentional deficits, and poor spatial awareness. There were no localising sensorimotor findings. Vitals showed pyrexia at 38.5°, heart rate of 96 bpm, normotensive blood pressure, respiratory rate between 16–22/minute and Sp02 of 96% on room air. SARS-CoV2 PCR nasopharyngeal swab was positive. The patient underwent a sequence of investigations in order to reach a definitive diagnosis as to the cause of his acute neurological presentation. CSF revealed <1/uL leucocytes, <1/uL erythrocytes, glucose of 2.9 mmol/L and total protein of 35. CSF PCR was negative for herpes simplex type 1 (HSV-1), herpes simplex type 2 (HSV-2), varicella zoster virus (VZV), parechovirus (HPeV) and mumps virus RNA. Paraneoplastic antibody screen was negative (anti-Hu, Yo, Ri, Ma, CV2, PNMA2, MA2TA, recoverin, TITIN, SOX1 ZIC4, GAD65, Tr (DNER), amphiphysin). Anti-N-methyl D-aspartate (NMDA) antibodies were negative. Autoimmune screen and vasculitic screen were negative. Frontotemporal dementia screen of CSF tau, phospho-tau and beta-amyloid were within normal ranges. Ammonia and copper levels were within normal ranges. Electroencephalogram (EEG) showed normal background rhythm with no focal or generalised epileptiform discharges. Magnetic Resonance Imaging (MRI) Brain showed non-specific subcortical FLAIR hyperintensities in the superior frontal lobes bilaterally, and increased T2 signal within the caudate heads bilaterally and possibly the right parasagittal region, indicating inflammation. Dopamine Transporter (DAT) scan showed no evidence of loss of presynaptic dopaminergic terminals.

The impression ultimately was toxic encephalopathy secondary to COVID-19 infection. This was a diagnosis of exclusion. Unfortunately, SARS-CoV2 PCR of CSF could not be tested at the time as it had not yet been validated locally or nationally in the National Virus Reference Laboratory (NVRL).

The patient continued to be confused throughout his admission, presenting as partially orientated, labile in mood and impulsive. On mental state examination the patient was distracted and overly familiar in manner. He presented as impulsive, with increased agitation, and his speech was pressured with formal thought disorder including perseveration. His affect and mood were labile, while his thought form was disordered. Although he expressed fleeting paranoid ideation, there were no fixed delusional beliefs or over-valued ideas. The patient scored 10/30 in the Mini-Mental State Exam (Folstein et al. Reference Folstein, Folstein and McHugh1975) after 1 week of admission, losing points for attention and calculation, delayed recall, visuospatial construction and executive functioning. He was aware of a change in his memory and mental state, and repetitively rang family members seeking reassurance. There was close collaboration between the Neuropsychiatry and Neurology teams to manage the patient’s fluctuating level of consciousness. A diagnosis of hyperactive delirium was made, and the Beaumont Hospital Delirium Protocol (BHDP) was commenced (Patel et al. Reference Patel, Carey, Cotter and Murphy2020). Haloperidol was introduced at a low dose and titrated up to 2 mg twice daily, and this was subsequently augmented with trazodone 100 mg nocte. Quetiapine was later substituted for haloperidol due to the development of extrapyramidal side effects, at a dose of 50 mg twice daily. The patient scored 12/30 in the Montreal Cognitive Assessment Test (MoCA) (Nasreddine et al. Reference Nasreddine, Phillips, Bédirian, Charbonneau, Whitehead, Collin, Cummings and Chertkow2005) at week two of the admission, losing marks for visuospatial and executive functioning, attention, delayed recall, and fluency of language. The Trail Making Test (TMT) (Army Individual Test Battery, 1944) at week four showed significant deficits in attention.

Over a period of weeks, the patient appeared to show gradual improvement in his levels of agitation and cognitive impairment, although a fluctuating element was still present. Repeat MRI Brain showed initially showed resolution of the high signal intensity in the caudate heads of the inferior frontal lobes and parasagittal right frontal lobe at the vertex, suggesting a resolving toxic aetiology. On week 10 of admission, the patient was treated with Privigen IVIg at a dose of 20 g for 5 consecutive days. The decision was made to trial IVIg in light of promising case reports emerging in the literature of treatment of COVID-encephalopathy. The patient was subsequently transferred to a step-down facility for neurorehabilitation at week 12 of admission, where he initially made good progress. The patient scored 24/30 in a MoCA prior to transfer.

Four weeks into his rehabilitation (16 weeks after his initial presentation), the patient deteriorated from a cognitive and psychiatric perspective. He again became disorientated and agitated, with increased non-purposeful motor activity. His speech was repetitive with increased flow. Short-term memory and working memory were impaired. He was re-admitted to Beaumont Hospital for further evaluation. The BHDP was utilised and regular haloperidol 2 mg BD was prescribed. SARS-CoV2 PCR nasopharyngeal swab was negative. Repeat lumbar puncture was unremarkable. Positron emission topography (PET) scan did not show signs of malignancy. MRI Brain showed no residual caudate or frontal lobe abnormalities. Due to the complex nature of the patient’s presentation, he underwent a right frontal lobe core biopsy, but no abnormalities were detected. Video EEG showed bi-frontal periodic epileptiform discharges. The patient remained alert but apathetic throughout the EEG. Bolus administration of lorazepam significantly improved alertness and prosody of speech, with resolution of frontal discharges. This finding confirmed sub-clinical seizures, that is, seizures recorded on EEG without motor or somatic seizure activity (Zangaladze et al. Reference Zangaladze, Nei, Liporace and Sperling2008).

The patient showed clinical improvement with introduction of anti-epileptic drugs; levetiracetam 750 mg BD, and clobazam 10 mg BD A subsequent EEG showed complete resolution of the epileptiform discharges. Some 2 months after his readmission, he scored 26/30 on the MOCA, losing points for visuospatial executive functioning and delayed recall. In addition, he scored 88/100 on the Addenbrooke’s Cognitive Assessment (ACE-III) (Hsieh et al. Reference Hsieh, Schubert, Hoon, Mioshi and Hodges2013), losing points in visuospatial abilities, language, and attention. The diagnosis of COVID-19 encephalopathy with associated sub-clinical epileptiform seizures was made. The patient will remain on anti-epileptic medication and will be regularly reviewed in neurology clinic to review his progress. Prognosis for the future is uncertain in this emerging condition.

Discussion

We present the case of a 56-year-old male with neuropsychiatric sequelae of COVID-19 encephalopathy including hyperactive delirium associated with confusion, agitation, pressure of speech, formal thought disorder, perseveration and paranoid ideation.

Challenges in this case included the absence of a confirmatory diagnostic test, evolution of the presentation over time and difficulty predicting disease trajectory.

Human coronavirus (hCoV) has neuroinvasive properties and has been suggested to induce overactivation of the autoimmune system in susceptible individuals (Desforges et al. Reference Desforges, Le Coupanec, Brison, Meessen-Pinard and Talbot2014). SARS-CoV-2 may have higher neuroinvasive potential than hCoV predecessors (Natoli et al. Reference Natoli, Oliveira, Calabresi, Maia and Pisani2020). While direct central nervous system pathology due to viral illness is most frequently linked with neurotropic viruses, respiratory viral illnesses (such as the human respiratory syncytial virus (hRSV), the influenza virus (IV), the coronavirus (CoV) and the human metapneumovirus (hMPV)) are also known to be associated with neurological sequelae (Bohmwald et al. Reference Bohmwald, Gálvez, Ríos and Kalergis2018). The mechanism of injury causing encephalopathy in COVID-19 patients is likely multifactorial, involving inflammatory, thrombotic, and viral impacts on the endothelium and parenchyma, (Bodro et al. Reference Bodro, Compta and Sánchez-Valle2020). Although the patient tested negative for COVID-19 during his first admission, sensitivity of nasal swabs is estimated at only 63% (Wang et al. Reference Wang, Xu, Gao, Lu, Han, Wu and Tan2020). CT Thorax showing bilateral ground-glass change may be clinically suggestive of COVID-19 (Salehi et al. Reference Salehi, Abedi, Balakrishnan and Gholamrezanezhad2020). It was noted following the Middle East Respiratory Syndrome (MERS) viral pandemic that neurological complications could be delayed 2–3 weeks following respiratory symptoms (Kim et al. Reference Kim, Heo, Kim, Song, Park, Park, Ahn, Kim and Choi2017). Neurological manifestations of COVID-19 are thought to be both immune and non-immune mediated (Needham et al. Reference Needham, Chou, Coles and Menon2020), although the pathways are incompletely known at present. Plasmapheresis for COVID-19-related autoimmune meningoencephalitis is an emerging treatment which may prove promising (Dogan et al. Reference Dogan, Kaya, Sarikaya, Zengin, Dincer, Akinci and Afsar2020) and was considered novel at the time of this case. It was unclear in this case what, if any, the contribution of IVIg treatment was to the improvement of the patient.

As a definitive test confirming direct SARS-CoV2 neuro-invasion was lacking, the patient required extensive investigations, including a brain biopsy, to prove the diagnosis of exclusion. This was a major limitation of this case. While CSF PCR for SARS-CoV2 is now possible in Ireland, very low positivity rates of PCR for SARS-CoV-2 have been found in COVID-19 patients with acute neurological symptoms (Lewis et al. Reference Lewis, Frontera, Placantonakis, Lighter, Galetta, Balcer and Melmed2021), although high levels of non-specific autoantibodies in CSF support the argument for an indirect autoimmune response (Lucchese, Reference Lucchese2020). This creates a challenge for clinicians treating similar cases, to strike a balance between thorough assessment and over-investigation.

In this patient, an initial EEG at the time of the first neurological presentation was normal, however a later video-EEG showed epileptiform discharges. A case series found that 40% of COVID-19 positive patients had abnormal EEG findings, the most common being frontal sharp wave pattern (Galanopoulou et al. Reference Galanopoulou, Ferastraoaru, Correa, Cherian, Duberstein and Gursky2020). Frontal sharp wave patterns can indicate interictal epileptiform activity (Krakow et al. Reference Krakow, Allen, Symms, Fish and Lemieux1999).

Abnormal EEG findings have been shown to be associated with more critically ill patients (Petrescu et al. Reference Petrescu, Taussig and Bouilleret2020).

Recovery in this case has been slow but promising, with a protracted period of encephalopathic symptoms. The best predictor of recovery for this and similar patients is likely that of SARS patients. Functional disability in SARS survivors has been found to be due to a complex interplay of physical deconditioning, neuropsychiatric and psychological factors (Hui et al. Reference Hui, Wong, Antonio, Tong, Chan and Sung2009). Unfortunately, in the COVID-19 cohort, patients admitted with neurological disease have been shown to have higher mortality, higher rates of delirium and greater disability (Benussi et al. Reference Benussi, Pilotto, Premi, Libri, Giunta and Agosti2020). Long term neuropsychiatric, particularly cognitive, complications of COVID-19 are expected to pose future significant challenges to the healthcare system, especially given the high prevalence of the disorder (Needham et al. Reference Needham, Chou, Coles and Menon2020; Troyer et al. Reference Troyer, Kohn and Hong2020). The new diagnosis of COVID-19 related encephalopathy, although rare, should be included as a differential in patients presenting with new behavioural disturbance, particularly for those in whom COVID-19 is confirmed or suspected.

Conflict of interest

Authors have no conflicts of interest to disclose.

Ethical standards

The authors assert that all procedures contributing to this work comply with the ethical standards of the relevant national and institutional committee on human experimentation with the Helsinki Declaration of 1975, as revised in 2008. This case report adhered to the standards of the Beaumont Hospital Research and Ethics Committee. Written informed consent was obtained from the patient. Consent was freely and voluntarily given, information regarding the case report was provided in written and verbal form, the patient was given the opportunity to ask questions, with satisfactory answers provided. All data was stored in compliance with the General Data Protection Regulation 2016.

Financial support

This research received no specific grant from any funding agency, commercial or not-for-profit sectors.

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