Hostname: page-component-586b7cd67f-g8jcs Total loading time: 0 Render date: 2024-11-26T03:23:30.516Z Has data issue: false hasContentIssue false

Neuroimmunological antibody-mediated encephalitis and implications for diagnosis and therapy in neuropsychiatry

Published online by Cambridge University Press:  03 December 2019

Joseph E. Marinas
Affiliation:
Neurochemical Research Unit, Department of Psychiatry, University of Alberta, Edmonton, AB, CanadaT6G 2G3
Dmitriy Matveychuk
Affiliation:
Neurochemical Research Unit, Department of Psychiatry, University of Alberta, Edmonton, AB, CanadaT6G 2G3
Serdar M. Dursun
Affiliation:
Neurochemical Research Unit, Department of Psychiatry, University of Alberta, Edmonton, AB, CanadaT6G 2G3
Glen B. Baker*
Affiliation:
Neurochemical Research Unit, Department of Psychiatry, University of Alberta, Edmonton, AB, CanadaT6G 2G3
*
Author for correspondence: Glen B. Baker, Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

The past decade has seen a surge of reports and investigations into cases of autoimmune-mediated encephalitis. The increasing recognition of these disorders is especially of relevance to the fields of neurology and psychiatry. Autoimmune encephalitis involves antibodies against synaptic receptors, neuronal cell surface proteins and intracellular targets. These disorders feature prominent symptoms of cognitive impairment and behavioural changes, often associated with the presence of seizures. Early in the clinical course, autoimmune encephalitis may manifest as psychiatric symptoms of psychosis and involve psychiatry as an initial point of contact. Although commonly associated with malignancy, these disorders can present in the absence of an inciting neoplasm. The identification of autoimmune encephalitis is of clinical importance as a large proportion of individuals experience a response to immunotherapy. This review focuses on the current state of knowledge on n-methyl-d-aspartate (NMDA) receptor-associated encephalitis and limbic encephalitis, the latter predominantly involving antibodies against the α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptor, the γ-aminobutyric acid (GABA)B receptor and leucine-rich glioma-inactivated 1 (LGI1) protein. In addition, we briefly describe anti-dopamine D2 receptor encephalitis. A summary of the literature will focus on common clinical presentations and course, diagnostic approaches and response to treatment. Since a substantial proportion of patients with autoimmune encephalitis exhibit symptoms of psychosis, the relevance of this disorder to theories of psychosis and schizophrenia will also be discussed.

Type
Review Article
Creative Commons
Creative Common License - CCCreative Common License - BYCreative Common License - NCCreative Common License - SA
This is an Open Access article, distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike licence (http://creativecommons.org/licenses/by-nc-sa/4.0/), which permits non-commercial re-use, distribution, and reproduction in any medium, provided the same Creative Commons licence is included and the original work is properly cited. The written permission of Cambridge University Press must be obtained for commercial re-use.
Copyright
© Scandinavian College of Neuropsychopharmacology 2019

Summations

  • There are multiple types of autoimmune encephalitis mediated by antibodies against synaptic receptors, neuronal cell surface proteins and intracellular targets.

  • These patients often present with predominant psychiatric symptoms and may have psychiatry as an initial point of contact.

  • A substantial proportion of patients respond favourably to immunotherapy.

Considerations

  • Initial diagnosis of autoimmune encephalitis remains a challenge, sometimes presenting with normal imaging, CSF and serological investigations.

  • Although often associated with malignancy, autoimmune encephalitis often presents without discovery of inciting cancer.

Introduction

Autoimmune encephalitis (also known as antibody-mediated encephalitis) is an increasingly recognised group of conditions (Table 1) with neuropsychiatric presentations. Given the increasing attention to immune-mediated aetiologies of encephalitis, further study is underway to develop approaches to these conditions as well as to delineate them from infectious causes (Graus et al., Reference Graus, Titulaer, Balu, Benseler, Bien, Cellucci, Cortese, Dale, Gelfand, Geschwind, Glaser, Honnorat, Hoftberger, Iizuka, Irani, Lancaster, Leypoldt, Pruss, Rae-Grant, Reindl, Rosenfeld, Rostasy, Saiz, Venkatesan, Vincent, Wandinger, Waters and Dalmau2016). Current research is also investigating the link between chronic psychotic disorders and inflammation (Herken & Pruss, Reference Herken and Pruss2017; Riedmuller & Muller, Reference Riedmuller and Muller2017). Generally, autoimmune encephalitis involves antibodies against the neuronal cell surface proteins, synaptic proteins or intracellular targets (Lancaster & Dalmau, Reference Lancaster and Dalmau2012; Dalmau & Graus, Reference Dalmau and Graus2018). Systemic/rheumatic conditions such as systemic lupus erythematosus and vasculitis can also present with neuropsychiatric symptoms (Oldham, Reference Oldham2017); however, these syndromes are outside the scope of this review. The antibody-mediated encephalitis examples in this review do not usually have other systemic presentations, distinguishing them from many autoimmune disorders with neuropsychiatric presentations. Although there is some overlap with other autoimmune-mediated conditions such as stiff person spectrum syndrome and neuromyelitis optica, the altered mental status, impaired cognition and psychotic symptoms usually seen in antibody-mediated encephalitis are not typical in these other conditions (Dalmau & Graus, Reference Dalmau and Graus2018), which are also outside the scope of this review.

Table 1. Selected types of antibody-mediated encephalitis and their associated general classification

LRR, leucine-rich repeat; EPTP, epitempin.

Immune-mediated encephalitis can be organised in multiple ways such as by neuroanatomical correlates; however, we have organised our review according to the antibodies involved and their pathological mechanisms – antibodies against intracellular antigens, synaptic receptors and cell surface proteins. Given that the neuropsychiatric symptoms of antibody-associated encephalitis may be the first presentation of neoplastic processes, these disorders have garnered interest with regard to their early identification, diagnosis and appropriate treatment.

This review focuses on anti-n-methyl-d-aspartate (NMDA) receptor encephalitis (NMDARE) and antibodies against intracellular antigens, synaptic receptors and cell surface proteins with an emphasis on clinical presentation in adults. Limbic encephalitis mediated by antibodies against AMPA receptors, GABAB receptors and LGI-1 will also be explored.

To construct this review, we searched PubMed, Web of Science and PsycINFO databases with the following search terms: ‘antibody-mediated encephalitis’, ‘autoimmune encephalitis’, ‘NMDA receptor encephalitis’, ‘limbic encephalitis’, ‘AMPA encephalitis’, ‘GABA encephalitis’, ‘dopamine D2 encephalitis’ and ‘leucine-rich glioma-inactivated 1 encephalitis’. We reviewed articles published between 2000 to 2018 inclusive in addition to the references cited within.

NMDARE

NMDARE was first described in a case series of 12 patients with neuropsychiatric symptoms in association with teratomas in 2007 (Dalmau et al., Reference Dalmau, Tuzun, Wu, Masjuan, Rossi, Voloschin, Baehring, Shimazaki, Koide, King, Mason, Sansing, Dichter, Rosenfeld and Lynch2007). Investigative findings revealed that these patients had antibodies to the NMDA receptor subunits in either the cerebrospinal fluid (CSF) or the serum. Cases of neurologic and cognitive dysfunction in patients with ovarian teratomas suggested an immune-related mechanism (Dalmau et al., Reference Dalmau, Tuzun, Wu, Masjuan, Rossi, Voloschin, Baehring, Shimazaki, Koide, King, Mason, Sansing, Dichter, Rosenfeld and Lynch2007). Subsequent studies have shown that the majority of cases first draw clinical attention due to psychiatric symptoms (Dalmau et al., Reference Dalmau, Gleichman, Hughes, Rossi, Peng, Lai, Dessain, Rosenfeld, Balice-Gordon and Lynch2008). Current models of NMDARE link tumours with proposed pathophysiology, clinical presentation and response to treatment; however, this association is not always straightforward (Irani et al., Reference Irani, Bera, Waters, Zuliani, Maxwell, Zandi, Friese, Galea, Kullmann, Beeson, Lang, Bien and Vincent2010b; Dalmau et al., Reference Dalmau, Lancaster, Martinez-Hernandez, Rosenfeld and Balice-Gordon2011).

Although the exact prevalence is not known, the literature suggests that NMDARE is more common than any single viral cause of encephalitis and appears to be the most common antibody-mediated encephalitis (Dalmau et al., Reference Dalmau, Lancaster, Martinez-Hernandez, Rosenfeld and Balice-Gordon2011; Gable et al., Reference Gable, Sheriff, Dalmau, Tilley and Glaser2012). The incidence of NMDARE is reported to be 5 in 100 000 people per year, although this is thought to be an underestimate due to the previous lack of awareness of the diagnosis (Dalmau & Graus, Reference Dalmau and Graus2018). Furthermore, Granerod et al. (Reference Granerod, Ambrose, Davies, Clewley, Walsh, Morgan, Cunningham, Zuckerman, Mutton, Solomon, Ward, Lunn, Irani, Vincent, Brown and Crowcroft2010) found that antibody-related encephalitis cases tended to have more longer-lasting residual dysfunction and higher mortality rates in comparison to encephalitis of infectious aetiologies. Cases of NMDARE are most common in children and young adults, with a median age of 21 years, but have been diagnosed in patients as young as 2 months (Titulaer et al., Reference Titulaer, Mccracken, Gabilondo, Armangue, Glaser, Iizuka, Honig, Benseler, Kawachi, Martinez-Hernandez, Aguilar, Gresa-Arribas, Ryan-Florance, Torrents, Saiz, Rosenfeld, Balice-Gordon, Graus and Dalmau2013; Armangue et al., Reference Armangue, Leypoldt, Malaga, Raspall-Chaure, Marti, Nichter, Pugh, Vicente-Rasoamalala, Lafuente-Hidalgo, Macaya, Ke, Titulaer, Hoftberger, Sheriff, Glaser and Dalmau2014). NMDARE affects younger women with a 4:1 preponderance, but this distribution does not apply to populations at ages <12 or >45 years of age. NMDARE is also more common in patients of African descent (Titulaer et al., Reference Titulaer, Mccracken, Gabilondo, Armangue, Glaser, Iizuka, Honig, Benseler, Kawachi, Martinez-Hernandez, Aguilar, Gresa-Arribas, Ryan-Florance, Torrents, Saiz, Rosenfeld, Balice-Gordon, Graus and Dalmau2013).

NMDARE has mainly been associated with ovarian teratomas, which have been seen in up to 58% of younger female patients. Other extragonadal teratoma presentations are also seen, although much less commonly (Titulaer et al., Reference Titulaer, Mccracken, Gabilondo, Armangue, Glaser, Iizuka, Honig, Benseler, Kawachi, Martinez-Hernandez, Aguilar, Gresa-Arribas, Ryan-Florance, Torrents, Saiz, Rosenfeld, Balice-Gordon, Graus and Dalmau2013). Additional malignancies and neoplasms associated with NMDARE include mediastinal and testicular teratomas, sex cord stromal tumours, small cell lung cancer, breast cancer, thymic carcinoma, pancreatic cancer, neuroblastomas and Hodgkin’s lymphoma (Venkatesan & Adatia, Reference Venkatesan and Adatia2017). Cases of men and children with NMDARE have a weaker association with tumours in comparison to women. The presence of neoplasms in antibody-mediated encephalitis can influence the treatment approach and prognosis; these topics are explored later in this review.

Pathophysiology

The pathophysiology of NMDARE is thought to involve the production of antibodies against the GluN1 subunit of the NMDA receptor. In tumour-positive patients, these antibodies may be synthesised in response to the presentation of tumour cells with antigens similar to the NMDA receptor (Dalmau et al., Reference Dalmau, Geis and Graus2017; Dalmau & Graus, Reference Dalmau and Graus2018). Interestingly, ovarian teratomas associated with NMDARE appear to have differing histopathological features in comparison to sporadic teratomas, including a higher frequency of containing nervous tissue components and expression of GluN1 by glial cells, as well as demonstrating prominent infiltration of nervous tissue by immune cells (Chefdeville et al., Reference Chefdeville, Treilleux, Mayeur, Couillault, Picard, Bost, Mokhtari, Vasiljevic, Meyronet, Rogemond, Psimaras, Dubois, Honnorat and Desestret2019). Antibodies may traverse the blood–brain barrier (BBB) and cross-link with cell surface NMDA receptors, leading to endocytosis. Of note, increased clinical severity and symptom progression correlate with increased antibody titre and decreased concentration of NMDA receptors. As antibody titres decrease with treatment, symptoms resolve in reverse sequence, often leading to the resurgence of clinical features seen earlier in presentation (Gresa-Arribas et al., Reference Gresa-Arribas, Titulaer, Torrents, Aguilar, Mccracken, Leypoldt, Gleichman, Balice-Gordon, Rosenfeld, Lynch, Graus and Dalmau2014).

Clinical presentation

The typical clinical course of NMDARE starts with a viral prodrome characterised by non-specific flu-like symptoms, such as fever and headache, in up to 70% of cases (Dalmau et al., Reference Dalmau, Lancaster, Martinez-Hernandez, Rosenfeld and Balice-Gordon2011). Within 1–2 weeks, there is development of cognitive and psychiatric symptoms, including sleep disturbance, agitation, psychosis, catatonia, impaired memory and speech difficulties. Seizures may also be seen during this period. Further deterioration is marked by the onset of dyskinetic movements, dysautonomia, respiratory failure and coma (Dalmau et al., Reference Dalmau, Lancaster, Martinez-Hernandez, Rosenfeld and Balice-Gordon2011). With treatment, these symptoms tend to recur in reverse sequence. As such, counselling the team and the patient’s family about the expectation of return of the behavioural symptoms may be prudent.

Post-HSV anti-NMDA receptor encephalitis

A different mechanism of autoimmunity occurs in approximately 20% of patients with herpes simplex virus (HSV) encephalitis, leading to a secondary autoimmune encephalitis usually seen in adults as neuropsychiatric and cognitive dysfunction following the initial treatment of viral encephalitis (Pruss et al., Reference Pruss, Finke, Holtje, Hofmann, Klingbeil, Probst, Borowski, Ahnert-Hilger, Harms, Schwab, Ploner, Komorowski, Stoecker, Dalmau and Wandinger2012; Armangue et al., Reference Armangue, Moris, Cantarin-Extremera, Conde, Rostasy, Erro, Portilla-Cuenca, Turon-Vinas, Malaga, Munoz-Cabello, Torres-Torres, Llufriu, Gonzalez-Gutierrez-Solana, Gonzalez, Casado-Naranjo, Rosenfeld, Graus and Dalmau2015; Linnoila et al., Reference Linnoila, Binnicker, Majed, Klein and Mckeon2016). The model for these cases proposes that the viral infection (such as HSV) causes cell damage leading to antigen exposure and the initiation of immune response and antibody production (Dalmau et al., Reference Dalmau, Geis and Graus2017; Baizabal-Carvallo & Jankovic, Reference Baizabal-Carvallo and Jankovic2018; Dalmau & Graus, Reference Dalmau and Graus2018). The presence of antibodies in the CSF, but not the serum, coupled with findings of BBB disruption in certain cases suggests the possibility of intrathecal antibody synthesis where B cells migrate past the BBB and produce antibodies rather than serum antibodies crossing the BBB (Dalmau et al., Reference Dalmau, Gleichman, Hughes, Rossi, Peng, Lai, Dessain, Rosenfeld, Balice-Gordon and Lynch2008, Reference Dalmau, Geis and Graus2017). In cases of NMDARE secondary to viral encephalitis, treatment with immunomodulating agents can lead to clinical improvement and does not seem to result in the re-emergence of HSV infection in children (Nosadini et al., Reference Nosadini, Mohammad, Corazza, Ruga, Kothur, Perilongo, Frigo, Toldo, Dale and Sartori2017). In comparison to patients without antecedent viral encephalitis, cases of secondary NMDARE show more persistent deficits (Gable et al., Reference Gable, Gavali, Radner, Tilley, Lee, Dyner, Collins, Dengel, Dalmau and Glaser2009; Dalmau et al., Reference Dalmau, Geis and Graus2017). Secondary autoimmune encephalitis also occurs with antibodies to targets other than the NMDA receptor; however, this appears to be less common (Dalmau et al., Reference Dalmau, Geis and Graus2017). Compared to secondary NMDARE, HSV encephalitis usually has a faster progression of symptoms and is not frequently associated with autonomic instability (Dalmau & Graus, Reference Dalmau and Graus2018).

Limbic encephalitis

Limbic encephalitis involves a group of autoimmune conditions with antibodies targeting the limbic structures. Historically, limbic encephalitis was thought to always have an associated neoplasm, but this relationship has not been as strong as previously thought (Tuzun & Dalmau, Reference Tuzun and Dalmau2007). Limbic encephalitis is characterised by magnetic resonance imaging (MRI) findings with hyperintesities in the medial temporal areas in addition to other structures such as the brainstem and cerebellum (Dalmau et al., Reference Dalmau, Graus, Villarejo, Posner, Blumenthal, Thiessen, Saiz, Meneses and Rosenfeld2004; Graus et al., Reference Graus, Titulaer, Balu, Benseler, Bien, Cellucci, Cortese, Dale, Gelfand, Geschwind, Glaser, Honnorat, Hoftberger, Iizuka, Irani, Lancaster, Leypoldt, Pruss, Rae-Grant, Reindl, Rosenfeld, Rostasy, Saiz, Venkatesan, Vincent, Wandinger, Waters and Dalmau2016). Common symptoms involve changes in mood, altered mental status and working memory as well as seizures. Limbic encephalitis is most known for subacute loss of short-term memory function, usually over a period of less than 3 months (Graus et al., Reference Graus, Titulaer, Balu, Benseler, Bien, Cellucci, Cortese, Dale, Gelfand, Geschwind, Glaser, Honnorat, Hoftberger, Iizuka, Irani, Lancaster, Leypoldt, Pruss, Rae-Grant, Reindl, Rosenfeld, Rostasy, Saiz, Venkatesan, Vincent, Wandinger, Waters and Dalmau2016).

Paraneoplastic limbic encephalitis

Limbic encephalitis can involve one of many antibodies that target epitopes at the cell surface, synaptic or intracellular level (Table 1). Determination of antibody type can help predict response to immunotherapy and which associated tumours are likely. The onconeuronal/paraneoplastic antibodies Hu and Ma2 have intracellular antigen targets and demonstrate a weaker response to immunotherapy. Anti-Hu antibodies are usually associated with small cell lung carcinoma, while anti-Ma2 antibodies are commonly associated with testicular seminoma. These onconeuronal antibodies are distinguished from other types of autoimmune encephalitis because they are much more frequently associated with neoplasms. Immunohistochemical and immunopathological findings show that anti-Hu and Ma2 antibodies do not localise to the cell surface. These findings suggest a T-cell-mediated response against intracellular antigens rather than directly pathogenic antibodies (Bernal et al., Reference Bernal, Graus, Pifarre, Saiz, Benyahia and Ribalta2002; Bien et al., Reference Bien, Vincent, Barnett, Becker, Blumcke, Graus, Jellinger, Reuss, Ribalta, Schlegel, Sutton, Lassmann and Bauer2012; Lancaster & Dalmau, Reference Lancaster and Dalmau2012; Dalmau et al., Reference Dalmau, Geis and Graus2017). This T-cell-mediated intracellular mechanism and resulting cell death may explain the relative refractoriness of these subtypes to usual immunomodulating treatment. Other intracellular antigen targets include Yo, Ri and CV2.

The pathophysiology of the onconeuronal paraneoplastic syndromes is thought to start with a loss of immune tolerance against proteins expressed by both cancer cells and intracellularly in neurons. These antigens may be detected following apoptosis with uptake by antigen-presenting cells. Cytotoxic T-cells causing cell death are thought to be the main immunologic mechanism rather than directly pathogenic antibodies. The presence of irreversible neuronal damage and/or death leads to reduced response to immunotherapy in comparison to outcomes with cell surface antibody-mediated conditions (Bernal et al., Reference Bernal, Graus, Pifarre, Saiz, Benyahia and Ribalta2002; Darnell & Posner, Reference Darnell and Posner2003; Dalmau et al., Reference Dalmau, Gleichman, Hughes, Rossi, Peng, Lai, Dessain, Rosenfeld, Balice-Gordon and Lynch2008; Bien et al., Reference Bien, Vincent, Barnett, Becker, Blumcke, Graus, Jellinger, Reuss, Ribalta, Schlegel, Sutton, Lassmann and Bauer2012).

Autoimmune limbic encephalitis

Glutamic acid decarboxylase (GAD) antibodies target intracellular GAD, an enzyme involved in the conversion of glutamate to GABA. Anti-GAD antibodies are associated with stiff person syndrome – a condition characterised by fluctuating stiffness in various muscle groups, painful spasms and increased startle response. Anti-GAD65 cases usually affect younger women, who present with seizures (Solimena et al., Reference Solimena, Folli, Aparisi, Pozza and De Camilli1990; Dalmau et al., Reference Dalmau, Geis and Graus2017). Although cancer is not always present at the time of initial diagnosis, there is an increased risk of small cell lung carcinoma and thymoma being found in patients older than 50 as well as those who test positive for concomitant anti-GABAB receptor antibodies. Anti-GAD65 antibodies may be involved with a separate pathogenic mechanism where either T-cells or antibodies disrupt synaptic vesicle fusion (Lancaster & Dalmau, Reference Lancaster and Dalmau2012). These antibodies are sometimes grouped separately in the literature given the different outcomes and pathological mechanisms (Dalmau et al., Reference Dalmau, Geis and Graus2017).

Within the limbic encephalitis group, common neuronal cell surface antibody targets include AMPA receptors, GABAB receptors, LGI-1, contactin-associated protein-like 2 (Caspr2), glycine receptors and metabotropic glutamate receptors (mGluR5). Numerous other antibody targets are listed in Table 1. In the literature, reports of antibody-mediated limbic encephalitis have largely focused on antibodies against the AMPA, GABAB and LGI-1 targets. As such, we will describe these types of encephalitis in detail for this review.

Anti-AMPA receptor encephalitis

Glutamatergic AMPA receptors are ionotropic receptors mediating fast excitatory neurotransmission. They are tetrameric in structure and composed of combinations of GluR1-4 subunits. Activation of AMPA receptors results in the removal of the NMDA receptor channel magnesium ion block and facilitates NMDA receptor activation. As such, AMPA receptors are usually co-localised with NMDA receptors and play a role in long-term potentiation, a cellular mechanism postulated to be involved in learning and memory.

Since 2009, there have been several published case studies and series describing autoimmune encephalitis caused by antibodies to GluR1 and GluR2 AMPA receptor subunits. In two separate analyses of anti-AMPA receptor encephalitis, it appears that this disorder affects individuals of older age (median ages of 60–62 years) and has a 64%–90% female predominance (Lai et al., Reference Lai, Hughes, Peng, Zhou, Gleichman, Shu, Mata, Kremens, Vitaliani, Geschwind, Bataller, Kalb, Davis, Graus, Lynch, Balice-Gordon and Dalmau2009; Höftberger et al., Reference Höftberger, Van Sonderen, Leypoldt, Houghton, Geschwind, Gelfand, Paredes, Sabater, Saiz, Titulaer, Graus and Dalmau2015). Most patients (64%–70%) had an underlying neoplasm, either of the lung, breast, thymus or ovarian teratoma. The majority of individuals present with symptoms of limbic encephalitis, including short-term memory loss, disorientation, confusion and behavioural changes such as aggression and agitation. Seizures, either focal or generalised tonic-clonic, were noted in less than half of patients on presentation. Furthermore, several cases were reported to exhibit psychotic features with or without other neurological abnormalities (Graus et al., Reference Graus, Boronat, Xifro, Boix, Svigelj, Garcia, Palomino, Sabater, Alberch and Saiz2010; Höftberger et al., Reference Höftberger, Van Sonderen, Leypoldt, Houghton, Geschwind, Gelfand, Paredes, Sabater, Saiz, Titulaer, Graus and Dalmau2015). Of interest, one of these patients developed neuroleptic malignant syndrome as a result of treatment with an antipsychotic medication. On CSF analysis, approximately half of patients had elevated lymphocyte counts. The majority of patients exhibited MRI findings of increased signal in the temporal lobes and EEG abnormalities, although some had unremarkable MRI and electroencephalography (EEG) results. According to Lai et al. (Reference Lai, Hughes, Peng, Zhou, Gleichman, Shu, Mata, Kremens, Vitaliani, Geschwind, Bataller, Kalb, Davis, Graus, Lynch, Balice-Gordon and Dalmau2009), response to immunotherapy approached 90%. In the Höftberger et al. (Reference Höftberger, Van Sonderen, Leypoldt, Houghton, Geschwind, Gelfand, Paredes, Sabater, Saiz, Titulaer, Graus and Dalmau2015) investigation, 24% of patients had a good response to immunotherapy, whereas 48% had a partial response and 29% did not improve. It appears that anti-AMPA encephalitis is also prone to relapses, as 5%–50% of individuals in the aforementioned studies experienced up to several relapses following initial treatment.

In cultures of live rat hippocampal neurons, GluR2 antibodies isolated from patients reduced the number of AMPA receptor clusters and decreased the co-localisation of GluR2 with presynaptic and postsynaptic markers (Lai et al., Reference Lai, Hughes, Peng, Zhou, Gleichman, Shu, Mata, Kremens, Vitaliani, Geschwind, Bataller, Kalb, Davis, Graus, Lynch, Balice-Gordon and Dalmau2009). Furthermore, patient antibodies against GluR1 and GluR2 were shown to decrease synaptic AMPA receptor cluster density through the induction of receptor internalisation (Peng et al., Reference Peng, Hughes, Moscato, Parsons, Dalmau and Balice-Gordon2015). These studies suggest that AMPA receptor antibodies are associated with a loss of function of the AMPA receptor.

Anti-GABAB receptor encephalitis

Inhibitory neurotransmission in the central nervous system is mainly mediated by GABA. This neurotransmitter interacts primarily with two types of receptors: the ionotropic GABAA and metabotropic GABAB receptors. While the GABAA receptor activation mediates fast inhibition by enabling chloride ion entry into the postsynaptic neuron, GABAB receptors are G-protein-coupled and facilitate presynaptic and postsynaptic inhibition of voltage-gated calcium channels and opening of potassium channels. The GABAB receptors are dimeric in structure and are composed of GABAB1 and GABAB2 subunits.

The first report of encephalitis associated with GABAB receptors was described in 15 patients by Lancaster et al. (Reference Lancaster, Lai, Peng, Hughes, Constantinescu, Raizer, Friedman, Skeen, Grisold, Kimura, Ohta, Iizuka, Guzman, Graus, Moss, Balice-Gordon and Dalmau2010). This appears to be a relatively rare cause of encephalitis, comprising approximately 4% of suspected paraneoplastic or immune-related encephalitis cases investigated. Individuals with anti-GABAB receptor encephalitis all presented with seizures, confusion and memory impairment. All were determined to have antibodies directed against the GABAB1 subunit, with only one of the patients having additional reactivity with GABAB2. Out of the 15 patients included, 10 had MRI findings in medial temporal lobes, consistent with limbic encephalitis, and 4 had normal MRI imaging. Most, but not all, exhibited abnormal EEG findings of seizure activity and CSF pleocytosis. The median age was 62 with 53% of patients being males. Nearly half were noted to have a malignancy, predominantly small cell lung cancer. Of note, five individuals were younger with a median age of 30 and did not appear to have any form of cancer. Of those who received immunotherapy and treatment of the primary malignancy, 90% demonstrated neurological improvement.

Subsequent case series by Boronat et al. (Reference Boronat, Sabater, Saiz, Dalmau and Graus2011) and Höftberger et al. (Reference Höftberger, Titulaer, Sabater, Dome, Rozsas, Hegedus, Hoda, Laszlo, Ankersmit, Harms, Boyero, De Felipe, Saiz, Dalmau and Graus2013) reaffirmed a strong association of anti-GABAB receptor antibodies with limbic encephalitis (91%–95%) and small cell lung cancer (50%–73%). Most patients were male (60%–82%) and presented with seizures, confusion and memory deficits. Of interest, one patient had prominent psychiatric symptoms. The median age of participants in the Boronat et al. (Reference Boronat, Sabater, Saiz, Dalmau and Graus2011) study was 60 years; however, Höftberger et al. (Reference Höftberger, Titulaer, Sabater, Dome, Rozsas, Hegedus, Hoda, Laszlo, Ankersmit, Harms, Boyero, De Felipe, Saiz, Dalmau and Graus2013) noted that individuals without small cell lung cancer were generally younger with a median age of 39 years. Up to a third of patients documented had normal initial MRI findings, and 42% had unremarkable EEG results. In the Höftberger et al. (Reference Höftberger, Titulaer, Sabater, Dome, Rozsas, Hegedus, Hoda, Laszlo, Ankersmit, Harms, Boyero, De Felipe, Saiz, Dalmau and Graus2013) study, 79% of individuals had either complete or partial neurological recovery after immunotherapy and cancer treatment when indicated.

Since this time, additional case series of anti-GABAB receptor encephalitis were reported in Korean (Kim et al., Reference Kim, Lee, Shin, Moon, Lim, Byun, Shin, Lee, Jung, Kim, Park, Chu and Lee2014), European (Dogan Onugoren et al., Reference Dogan Onugoren, Deuretzbacher, Haensch, Hagedorn, Halve, Isenmann, Kramme, Lohner, Melzer, Monotti, Presslauer, Schabitz, Steffanoni, Stoeck, Strittmatter, Stogbauer, Trinka, Von Oertzen, Wiendl, Woermann and Bien2015) and Chinese (Guan et al., Reference Guan, Ren, Yang, Lu, Peng, Zhu, Shao, Hu, Zhou and Cui2015; Chen et al., Reference Chen, Liu, Li, Xie, Wang, Zhou and Shang2017) studies. Another Chinese investigation demonstrated that nearly two-thirds of patients presented with bizarre behaviour and hallucinations (Cui et al., Reference Cui, Bu, He, Zhao, Han, Gao, Li, Li, Guo and Zou2018). Moreover, anti-GABAB receptor encephalitis does not appear to be limited to the adult population as it was also described in a paediatric case of a 3-year-old boy (Kruer et al., Reference Kruer, Hoeftberger, Lim, Coryell, Svoboda, Woltjer and Dalmau2014). Interestingly, one case report describes a patient with no abnormalities on MRI but significant medial temporal hypermetabolism with gross hypometabolism in the rest of the brain on 18F-fluorodeoxyglucose (FDG) positron emission tomography (PET)/computerised tomography (CT) (Su et al., Reference Su, Xu and Tian2015), indicating a possible role for PET in diagnosis.

LGI1 encephalitis

LGI1 is a secreted protein that was first discovered in the study of gliomas. Furthermore, mutations in the LGI1 gene were noted to contribute to autosomal-dominant lateral temporal lobe epilepsy (Kegel et al., Reference Kegel, Aunin, Meijer and Bermingham2013). Although the role of LGI1 is still largely unknown, this protein interacts with the ADAM (A Disintegrin and Metalloprotease) transmembrane protein family and has possible roles in synaptic maturation and function (Kegel et al., Reference Kegel, Aunin, Meijer and Bermingham2013). An important discovery was made in 2010 when it was determined that limbic encephalitis previously attributed to antibodies against voltage-gated potassium channel complexes actually involved antibodies directed against LGI1 rather than potassium channel subunits (Irani et al., Reference Irani, Alexander, Waters, Kleopa, Pettingill, Zuliani, Peles, Buckley, Lang and Vincent2010a; Lai et al., Reference Irani, Alexander, Waters, Kleopa, Pettingill, Zuliani, Peles, Buckley, Lang and Vincent2010).

In a case series of 57 patients with anti-LGI1 encephalitis (Lai et al., Reference Lai, Huijbers, Lancaster, Graus, Bataller, Balice-Gordon, Cowell and Dalmau2010), common presentation included memory loss (100%), seizures (82%), hyponatremia (60%) and myoclonus (40%). Most patients were older (median age of 60) and had a male predominance of 65%. Further investigation revealed that 84% had MRI findings involving medial temporal lobes, 76% had abnormal EEG studies, and 41% had CSF abnormalities. In contrast to anti-AMPA and anti-GABAB receptor encephalitis, only 11% were found to have a malignancy. Out of those who received immunotherapy, 81% had a good clinical outcome and 17% experienced residual moderate disability. Additionally, 18% of patients were noted to have relapses. The tendency of anti-LGI1 encephalitis to be weakly associated with cancer and often presenting with hyponatremia was reinforced in a subsequent case series of 14 patients (Shin et al., Reference Shin, Lee, Shin, Moon, Lim, Byun, Kim, Lee, Kim, Park, Jung, Lee and Chu2013).

Prior to the onset of limbic encephalitis, patients with anti-LGI1 antibodies were noted to present with a variety of neurological and psychiatric symptoms. This included a prodrome of dystonic seizures involving the arm and face (Andrade et al., Reference Andrade, Tai, Dalmau and Wennberg2011; Irani et al., Reference Irani, Michell, Lang, Pettingill, Waters, Johnson, Schott, Armstrong, Zagami, Bleasel, Somerville, Smith and Vincent2011), termed faciobrachial dystonic seizures and chorea (Tofaris et al., Reference Tofaris, Irani, Cheeran, Baker, Cader and Vincent2012). Furthermore, LGI1 encephalitis was reported to present as a brief psychotic disorder in a 25-year-old patient (van Elst et al., Reference Van Elst, Kloppel and Rauer2011). This individual developed a preoccupation with infection and delusions of reference, resulting in subsequent admission to a psychiatric unit. Of note, the neurological exam was unremarkable at the time of admission. Initial psychotic symptoms were followed by the development of aphasia, mutism, akinesia and seizures. This individual made a steady recovery following immunotherapy, eventually achieving full psychiatric and neurological remission.

Anti-dopamine D2 receptor encephalitis

Dopamine D2 receptor encephalitis is a part of the spectrum of basal ganglia encephalitis that includes Sydenham chorea and possibly paediatric autoimmune neuropsychiatric disorder associated with streptococcus (PANDAS) and Tourette syndrome. Studies on the role of anti-D2 receptor antibodies in PANDAS have reported conflicting findings (Brimberg et al., Reference Brimberg, Benhar, Mascaro-Blanco, Alvarez, Lotan, Winter, Klein, Moses, Somnier, Leckman, Swedo, Cunningham and Joel2012; Dale et al., Reference Dale, Merheb, Pillai, Wang, Cantrill, Murphy, Ben-Pazi, Varadkar, Aumann, Horne, Church, Fath and Brilot2012; Dalmau et al., Reference Dalmau, Geis and Graus2017). The onset of D2 receptor encephalitis usually occurs in childhood, affecting both sexes equally (Dale et al., Reference Dale, Merheb, Pillai, Wang, Cantrill, Murphy, Ben-Pazi, Varadkar, Aumann, Horne, Church, Fath and Brilot2012). This condition is mostly seen after infection with β-hemolytic streptococcus, mycoplasma and enterovirus as well as after vaccination. MRI lesions are seen in the basal ganglia in approximately 50% of patients. Clinical presentation involves dystonia and oculogyric crises, features of parkinsonism and chorea. Neuropsychiatric manifestations include emotional lability, difficulty sustaining attention and psychosis (Baizabal-Carvallo & Jankovic, Reference Baizabal-Carvallo and Jankovic2018). D2 receptor encephalitis is not usually associated with tumours.

Investigation and diagnosis

Autoimmune encephalitis can initially present with psychiatric symptoms, but the development and progression of cognitive symptoms, seizures, other neurologic findings, as well as medical instability usually prompt investigation for underlying organic processes (Herken & Pruss, Reference Herken and Pruss2017). Graus et al. (Reference Graus, Titulaer, Balu, Benseler, Bien, Cellucci, Cortese, Dale, Gelfand, Geschwind, Glaser, Honnorat, Hoftberger, Iizuka, Irani, Lancaster, Leypoldt, Pruss, Rae-Grant, Reindl, Rosenfeld, Rostasy, Saiz, Venkatesan, Vincent, Wandinger, Waters and Dalmau2016) outlined a proposed diagnostic algorithm to guide clinicians. CSF is used to investigate other encephalitic causes, obtain cell counts and confirm the presence and type of antibodies. Initial findings suggesting autoimmune encephalitis include mild pleiocytosis and oligoclonal bands. If the clinical presentation and CSF findings support an autoimmune encephalitis, it may be reasonable to start treatment before results confirm antibody subtype. In comparison, serum samples have lower sensitivity and specificity compared to CSF. Furthermore, the presence of serum antibodies does not reliably correlate with the presence or absence of antibodies in the CSF (Lancaster, Reference Lancaster2016).

Other supportive investigations include MRI and EEG; these can be completed prior to antibody confirmation. EEG investigations of autoimmune encephalitis usually show non-specific abnormalities. The presence of an extreme delta brush pattern is not found in most cases, but is specific for NMDA receptor encephalitis (Baysal-Kirac et al., Reference Baysal-Kirac, Tuzun, Altindag, Ekizoglu, Kinay, Bilgic, Tekturk and Baykan2016).

Brain imaging may help rule out other possible diagnoses, and MRI findings can vary depending on the antibody subtype. Limbic encephalitis may present with hyperintensities in the medial temporal structures, while NMDA receptor encephalitis does not consistently present with MRI abnormalities (Lancaster, Reference Lancaster2016). Functional MRI and PET are other imaging modalities of interest; however, they are not currently employed in the routine workup of autoimmune encephalitis (Finke et al., Reference Finke, Kopp, Scheel, Pech, Soemmer, Schlichting, Leypoldt, Brandt, Wuerfel, Probst, Ploner, Pruss and Paul2013; Heine et al., Reference Heine, Pruss, Bartsch, Ploner, Paul and Finke2015; Peer et al., Reference Peer, Pruss, Ben-Dayan, Paul, Arzy and Finke2017). Autoimmune encephalitis can present as metabolic abnormalities on PET scans, and further investigation will delineate if specific patterns are associated with antibody subtypes. Given these findings, PET may become involved in the routine workup of autoimmune encephalitis (Morbelli et al., Reference Morbelli, Djekidel, Hesse, Pagani and Barthel2016). Probasco et al. (Reference Probasco, Solnes, Nalluri, Cohen, Jones, Zan, Javadi and Venkatesan2017) found that 52 out of 62 patients had abnormalities on FDG-PET scans, with hyper- and hypometabolism in various areas. Furthermore, FDG-PET abnormalities were also present in cases where other investigative modalities did not yield significant findings (Probasco et al., Reference Probasco, Solnes, Nalluri, Cohen, Jones, Zan, Javadi and Venkatesan2017; Solnes et al., Reference Solnes, Jones, Rowe, Pattanayak, Nalluri, Venkatesan, Probasco and Javadi2017). Other investigations suggest that PET scan findings may be more sensitive than MRI in autoimmune encephalitis, and patterns may correlate with disease severity and antibody subtype (Lee et al., Reference Lee, Kang, Oh, Kim, Shin and Kim2014; Quartuccio et al., Reference Quartuccio, Caobelli, Evangelista, Alongi, Kirienko, De Biasi and Cocciolillo2015; Solnes et al., Reference Solnes, Jones, Rowe, Pattanayak, Nalluri, Venkatesan, Probasco and Javadi2017). Further research correlating which investigational abnormalities are likely to emerge with disease progression and antibody subtype may clarify the heterogeneity in these findings.

Investigations for tumours are often done concurrent to the autoimmune encephalitis workup given the association with malignancy. Specific investigations are tailored towards the tumours associated with the suspected or confirmed antibody subtype.

Treatment

Treatment usually commences prior to the return of confirmatory antibody results given the association of early treatment with better prognosis (Titulaer et al., Reference Titulaer, Mccracken, Gabilondo, Armangue, Glaser, Iizuka, Honig, Benseler, Kawachi, Martinez-Hernandez, Aguilar, Gresa-Arribas, Ryan-Florance, Torrents, Saiz, Rosenfeld, Balice-Gordon, Graus and Dalmau2013). Limited studies have investigated psychiatric and behavioural symptom management in the context of autoimmune encephalitis. Kuppuswamy et al. (Reference Kuppuswamy, Takala and Sola2014) advise using antipsychotics judiciously given the risk of neuroleptic malignant syndrome. Further, valproic acid may be useful given its role in treating seizures and manic symptoms. Electroconvulsive therapy may have a role in managing catatonic symptoms if patients do not present with any contraindications (Kuppuswamy et al., Reference Kuppuswamy, Takala and Sola2014). Supportive measures regarding associated dysautonomia, hypoventilation and other medical considerations are also important. Immune-based therapies are more definitive treatments and first-line agents usually include steroids, intravenous immunoglobulin (IVIg) and plasmapheresis. These treatments may be used in combination depending on patient presentation and progression of symptoms. Steroids are usually started after ruling out infectious causes given the risk of clinical worsening. Plasmapheresis may present practical challenges in agitated and confused patients. Superiority between first-line treatments is not clear at this time (Titulaer et al. Reference Titulaer, Mccracken, Gabilondo, Armangue, Glaser, Iizuka, Honig, Benseler, Kawachi, Martinez-Hernandez, Aguilar, Gresa-Arribas, Ryan-Florance, Torrents, Saiz, Rosenfeld, Balice-Gordon, Graus and Dalmau2013; Lancaster, Reference Lancaster2016; Shin et al., Reference Shin, Lee, Park, Jung, Jung, Lee and Chu2018).

Second-line therapies are used when patients do not respond to first-line interventions or show clinical worsening. Rituximab is commonly used in patients with limited or suboptimal response with first-line agents, but requires monitoring of cell counts with ongoing use. Cyclophosphamide is used with caution in patients of child-bearing age given the risk of future infertility. Of note, tocilizumab and interleukin-2 use may be useful as treatments in the future (Lee et al., Reference Lee, Lee, Moon, Sunwoo, Byun, Lim, Kim, Shin, Lee, Jun, Lee, Kim, Park, Jung, Jung, Kim, Lee and Chu2016; Lim et al., Reference Lim, Lee, Moon, Jun, Park, Byun, Sunwoo, Park, Jung, Jung, Lee and Chu2016). Patients with recurrent encephalitis may also be treated with other immunomodulatory agents such as methotrexate, mofetil mycophenolate and azathioprine (Shin et al., Reference Shin, Lee, Park, Jung, Jung, Lee and Chu2018). Associated tumours and malignancies are treated concurrently in addition to immunotherapy. Patients with an identified tumour receiving appropriate combined resection and immunotherapy are more likely to respond to treatment and less likely to have relapses than tumour-negative patients (Dalmau et al., Reference Dalmau, Lancaster, Martinez-Hernandez, Rosenfeld and Balice-Gordon2011; Titulaer et al., Reference Titulaer, Mccracken, Gabilondo, Armangue, Glaser, Iizuka, Honig, Benseler, Kawachi, Martinez-Hernandez, Aguilar, Gresa-Arribas, Ryan-Florance, Torrents, Saiz, Rosenfeld, Balice-Gordon, Graus and Dalmau2013).

Relevance to psychosis

The theory of glutamatergic dysregulation in the pathophysiology of schizophrenia has been gaining ground in the past few decades. Support was first noted in the observations that abuse of phencyclidine and ketamine, both non-competitive NMDA receptor antagonists, by healthy individuals can elicit positive, negative and cognitive symptoms similar to that of schizophrenia (Lodge & Mercier, Reference Lodge and Mercier2015). As such, phencyclidine administration was considered as a pharmacological animal model of the disorder (Jones et al., Reference Jones, Watson and Fone2011). Although the mechanism of glutamate dysregulation in schizophrenia is still far from understood and outside the scope of this review, it is thought to possibly involve downstream alterations of the GABA and dopamine neurotransmitter systems. Nonetheless, the clinical presentation of NMDARE supports the notion of NMDA receptor hypofunction as a primary feature of schizophrenia (Coyle et al., Reference Coyle, Tsai and Goff2003; Moghaddam & Javitt, Reference Moghaddam and Javitt2011) and lends credence to the exploration of mechanisms targeting glutamatergic pathways in the development of novel antipsychotic strategies. One such example is the investigation of d-serine, a potent co-agonist at the NMDA receptor, as a potential therapeutic agent in schizophrenia (MacKay et al., Reference Mackay, Kravtsenyuk, Thomas, Mitchell, Dursun and Baker2019). Furthermore, the identification of NMDARE has also led to the consideration of whether the aetiology of psychosis has a possible autoimmune component (Al-Diwani et al., Reference Al-Diwani, Pollak, Irani and Lennox2017).

To date, there have been multiple investigations into the presence of autoimmune antibodies in schizophrenia, mostly with largely conflicting results. Dahm et al. (Reference Dahm, Ott, Steiner, Stepniak, Teegen, Saschenbrecker, Hammer, Borowski, Begemann, Lemke, Rentzsch, Probst, Martens, Wienands, Spalletta, Weissenborn, Stocker and Ehrenreich2014) and Hammer et al. (Reference Hammer, Stepniak, Schneider, Papiol, Tantra, Begemann, Siren, Pardo, Sperling, Mohd Jofrry, Gurvich, Jensen, Ostmeier, Luhder, Probst, Martens, Gillis, Saher, Assogna, Spalletta, Stocker, Schulz, Nave and Ehrenreich2014) reported a 10% prevalence for serum antibodies against the NMDA GluN1 receptor subunit in both healthy control individuals and in patients with a variety of neuropsychiatric disorders, including schizophrenia. However, other investigations were not able to find serum anti-NMDA receptor antibodies in individuals with schizophrenia spectrum disorders (Rhoads et al., Reference Rhoads, Guirgis, Mcknight and Duchemin2011; Masdeu et al., Reference Masdeu, Gonzalez-Pinto, Matute, Ruiz De Azua, Palomino, De Leon, Berman and Dalmau2012; de Witte et al., Reference De Witte, Hoffmann, Van Mierlo, Titulaer, Kahn and Martinez-Martinez2015). Alternatively, when compared to controls, there have been reports of significant elevations in serum anti-NMDA receptor antibodies in schizophrenia (9.9% vs. 0.4%) (Steiner et al., Reference Steiner, Walter, Glanz, Sarnyai, Bernstein, Vielhaber, Kastner, Skalej, Jordan, Schiltz, Klingbeil, Wandinger, Bogerts and Stoecker2013) and in children presenting with first-episode psychosis (14% vs. 0%) (Pathmanandavel et al., Reference Pathmanandavel, Starling, Merheb, Ramanathan, Sinmaz, Dale and Brilot2015). The presence of anti-NMDA antibodies in schizophrenia was also reported by several other authors (Zandi et al., Reference Zandi, Irani, Lang, Waters, Jones, Mckenna, Coles, Vincent and Lennox2011; Tsutsui et al., Reference Tsutsui, Kanbayashi, Tanaka, Boku, Ito, Tokunaga, Mori, Hishikawa, Shimizu and Nishino2012), although no control subjects were used in these investigations. A meta-analysis of five studies and over 3300 participants demonstrated a three-fold increased likelihood of having elevated NMDA receptor serum antibodies in schizophrenia, bipolar disorder or major depressive disorder in comparison to healthy controls (Pearlman & Najjar, Reference Pearlman and Najjar2014).

In a recent study from Finland on serum from patients with first-episode psychosis, those demonstrating only prodromal syndromes and controls were investigated for a multitude of antibodies associated with encephalitis (Mantere et al., Reference Mantere, Saarela, Kieseppa, Raij, Mantyla, Lindgren, Rikandi, Stoecker, Teegen and Suvisaari2018). Only a single patient with a high risk of psychosis demonstrated positive serum antibodies against the NMDA receptor. Of interest, this patient had not experienced an episode of psychosis after 1 year of follow-up and did not require treatment for encephalitis.

In contrast, Jezequel et al. (Reference Jezequel, Johansson, Dupuis, Rogemond, Grea, Kellermayer, Hamdani, Le Guen, Rabu, Lepleux, Spatola, Mathias, Bouchet, Ramsey, Yolken, Tamouza, Dalmau, Honnorat, Leboyer and Groc2017) found that nearly 19% of individuals with a diagnosis of schizophrenia and only 3% of controls had positive serum anti-NMDA receptor antibodies. In the article, the authors comment that the differences in methodology used to establish seropositivity may be a contributor to prior conflicting results – this particular paper used cell-based assays with a novel single-molecule tracking approach. Of specific interest is the finding that anti-NMDA receptor antibodies from schizophrenic patients and healthy controls behaved differently; only the schizophrenia patients’ anti-NMDA receptor antibodies were shown to destabilise synaptic NMDA receptors, decrease NMDA receptor content and impair long-term potentiation. When compared to antibodies from patients with NMDA receptor encephalitis, those with schizophrenia had lower antibody titres, absence of NDMA receptor antibodies in the CSF and no overlap in binding to NMDA receptor targets. These findings suggest that there are some differences between the anti-NMDA receptor antibodies present in the two disorders.

At this time, there is no consensus as to the presence or role of autoimmune antibodies in schizophrenia. Many of the aforementioned studies have been limited to serological testing and have not incorporated CSF levels of antibodies, which is a much more sensitive method for detection. In addition, the finding that seropositivity of antibodies in autoimmune encephalitis can fluctuate in the disease course complicates the interpretation of results in a chronic disease such as schizophrenia. As such, further investigation of immunological factors in schizophrenia is certainly warranted.

Conclusion

The biological mechanisms underlying psychosis and other neuropsychiatric symptoms have been the subject of many investigations. With contributions of the immune system becoming increasingly recognised with autoimmune and primary psychiatric illnesses, novel treatment strategies may be possible. With all the possible antigenic targets available and to be discovered with regard to encephalitis, further research will help delineate biological correlates with behaviour.

Acknowledgements

The authors are grateful to Trudy Valliere for expert secretarial assistance.

Author contributions

All four authors contributed to the literature search and discussions about the design of the review. JEM and DM wrote the first draft. All authors contributed to the editing and approval of the final version of the manuscript.

Financial support

GBB received funding from a TRIP grant from the Faculty of Medicine and Dentistry, University of Alberta.

Conflict of interest

The authors have no conflict of interest to declare.

References

Al-Diwani, AAJ, Pollak, TA, Irani, SR and Lennox, BR (2017) Psychosis: an autoimmune disease? Immunology 152, 388401.CrossRefGoogle ScholarPubMed
Andrade, DM, Tai, P, Dalmau, J and Wennberg, R (2011) Tonic seizures: a diagnostic clue of anti-LGI1 encephalitis? Neurology 76, 13551357.CrossRefGoogle ScholarPubMed
Armangue, T, Leypoldt, F, Malaga, I, Raspall-Chaure, M, Marti, I, Nichter, C, Pugh, J, Vicente-Rasoamalala, M, Lafuente-Hidalgo, M, Macaya, A, Ke, M, Titulaer, MJ, Hoftberger, R, Sheriff, H, Glaser, C and Dalmau, J (2014) Herpes simplex virus encephalitis is a trigger of brain autoimmunity. Annals of Neurology 75, 317323.CrossRefGoogle ScholarPubMed
Armangue, T, Moris, G, Cantarin-Extremera, V, Conde, CE, Rostasy, K, Erro, ME, Portilla-Cuenca, JC, Turon-Vinas, E, Malaga, I, Munoz-Cabello, B, Torres-Torres, C, Llufriu, S, Gonzalez-Gutierrez-Solana, L, Gonzalez, G, Casado-Naranjo, I, Rosenfeld, M, Graus, F and Dalmau, J (2015). Autoimmune post-herpes simplex encephalitis of adults and teenagers. Neurology 85, 17361743.CrossRefGoogle ScholarPubMed
Baizabal-Carvallo, JF and Jankovic, J (2018) Autoimmune and paraneoplastic movement disorders: an update. Journal of the Neurological Sciences 385, 175184.CrossRefGoogle ScholarPubMed
Baysal-Kirac, L, Tuzun, E, Altindag, E, Ekizoglu, E, Kinay, D, Bilgic, B, Tekturk, P and Baykan, B (2016) Are there any specific EEG findings in autoimmune epilepsies? Clinical EEG and Neuroscience 47, 224234.CrossRefGoogle ScholarPubMed
Bernal, F, Graus, F, Pifarre, A, Saiz, A, Benyahia, B and Ribalta, T (2002) Immunohistochemical analysis of anti-Hu-associated paraneoplastic encephalomyelitis. Acta Neuropathologica 103, 509515.CrossRefGoogle ScholarPubMed
Bien, CG, Vincent, A, Barnett, MH, Becker, AJ, Blumcke, I, Graus, F, Jellinger, KA, Reuss, DE, Ribalta, T, Schlegel, J, Sutton, I, Lassmann, H and Bauer, J (2012) Immunopathology of autoantibody-associated encephalitides: clues for pathogenesis. Brain 135(Pt 5), 16221638.CrossRefGoogle ScholarPubMed
Boronat, A, Sabater, L, Saiz, A, Dalmau, J and Graus, F (2011) GABA(B) receptor antibodies in limbic encephalitis and anti-GAD-associated neurologic disorders. Neurology 76, 795800.CrossRefGoogle ScholarPubMed
Brimberg, L, Benhar, I, Mascaro-Blanco, A, Alvarez, K, Lotan, D, Winter, C, Klein, J, Moses, AE, Somnier, FE, Leckman, JF, Swedo, SE, Cunningham, MW and Joel, D (2012) Behavioral, pharmacological, and immunological abnormalities after streptococcal exposure: a novel rat model of Sydenham chorea and related neuropsychiatric disorders. Neuropsychopharmacology 37, 20762087.CrossRefGoogle ScholarPubMed
Chefdeville, A, Treilleux, I, Mayeur, M-E, Couillault, C, Picard, G, Bost, C, Mokhtari, K, Vasiljevic, A, Meyronet, D, Rogemond, V, Psimaras, D, Dubois, B, Honnorat, J and Desestret, V (2019) Immunopathological characterization of ovarian teratomas associated with anti-N-methyl-D-aspartate receptor encephalitis. Acta Neuropathologica Communications 7, 38.CrossRefGoogle ScholarPubMed
Chen, X, Liu, F, Li, JM, Xie, XQ, Wang, Q, Zhou, D and Shang, H (2017) Encephalitis with antibodies against the GABAB receptor: seizures as the most common presentation at admission. Neurological Research 39, 973980.CrossRefGoogle ScholarPubMed
Coyle, JT, Tsai, G and Goff, D (2003) Converging evidence of NMDA receptor hypofunction in the pathophysiology of schizophrenia. Annals of the New York Academy of Sciences 1003, 318327.CrossRefGoogle ScholarPubMed
Cui, J, Bu, H, He, J, Zhao, Z, Han, W, Gao, R, Li, X, Li, Q, Guo, X and Zou, Y (2018) The gamma-aminobutyric acid-B receptor (GABAB) encephalitis: clinical manifestations and response to immunotherapy. International Journal of Neuroscience 128, 627633.CrossRefGoogle ScholarPubMed
Dahm, L, Ott, C, Steiner, J, Stepniak, B, Teegen, B, Saschenbrecker, S, Hammer, C, Borowski, K, Begemann, M, Lemke, S, Rentzsch, K, Probst, C, Martens, H, Wienands, J, Spalletta, G, Weissenborn, K, Stocker, W and Ehrenreich, H (2014) Seroprevalence of autoantibodies against brain antigens in health and disease. Annals of Neurology 76, 8294.CrossRefGoogle ScholarPubMed
Dale, RC, Merheb, V, Pillai, S, Wang, D, Cantrill, L, Murphy, TK, Ben-Pazi, H, Varadkar, S, Aumann, TD, Horne, MK, Church, AJ, Fath, T and Brilot, F (2012) Antibodies to surface dopamine-2 receptor in autoimmune movement and psychiatric disorders. Brain 135(Pt 11), 34533468.CrossRefGoogle ScholarPubMed
Dalmau, J, Geis, C and Graus, F (2017) Autoantibodies to synaptic receptors and neuronal cell surface proteins in autoimmune diseases of the central nervous system. Physiological Reviews 97, 839887.CrossRefGoogle ScholarPubMed
Dalmau, J, Gleichman, AJ, Hughes, EG, Rossi, JE, Peng, X, Lai, M, Dessain, SK, Rosenfeld, MR, Balice-Gordon, R and Lynch, DR (2008) Anti-NMDA-receptor encephalitis: case series and analysis of the effects of antibodies. Lancet Neurology 7, 10911098.CrossRefGoogle ScholarPubMed
Dalmau, J and Graus, F (2018) Antibody-mediated encephalitis. New England Journal of Medicine 378, 840851.CrossRefGoogle ScholarPubMed
Dalmau, J, Graus, F, Villarejo, A, Posner, JB, Blumenthal, D, Thiessen, B, Saiz, A, Meneses, P and Rosenfeld, MR (2004) Clinical analysis of anti-Ma2-associated encephalitis. Brain 127(Pt 8), 18311844.CrossRefGoogle ScholarPubMed
Dalmau, J, Lancaster, E, Martinez-Hernandez, E, Rosenfeld, MR and Balice-Gordon, R (2011) Clinical experience and laboratory investigations in patients with anti-NMDAR encephalitis. Lancet Neurology 10, 6374.CrossRefGoogle ScholarPubMed
Dalmau, J, Tuzun, E, Wu, HY, Masjuan, J, Rossi, JE, Voloschin, A, Baehring, JM, Shimazaki, H, Koide, R, King, D, Mason, W, Sansing, LH, Dichter, MA, Rosenfeld, MR and Lynch, DR (2007) Paraneoplastic anti-N-methyl-D-aspartate receptor encephalitis associated with ovarian teratoma. Annals of Neurology 61, 2536.CrossRefGoogle ScholarPubMed
Darnell, RB and Posner, JB (2003) Paraneoplastic syndromes involving the nervous system. New England Journal of Medicine 349, 15431554.CrossRefGoogle ScholarPubMed
De Witte, LD, Hoffmann, C, Van Mierlo, HC, Titulaer, MJ, Kahn, RS and Martinez-Martinez, P (2015) Absence of N-methyl-D-aspartate receptor IgG autoantibodies in schizophrenia: the importance of cross-validation studies. JAMA Psychiatry 72, 731733.CrossRefGoogle ScholarPubMed
Dogan Onugoren, M, Deuretzbacher, D, Haensch, CA, Hagedorn, HJ, Halve, S, Isenmann, S, Kramme, C, Lohner, H, Melzer, N, Monotti, R, Presslauer, S, Schabitz, WR, Steffanoni, S, Stoeck, K, Strittmatter, M, Stogbauer, F, Trinka, E, Von Oertzen, TJ, Wiendl, H, Woermann, FG and Bien, CG (2015) Limbic encephalitis due to GABAB and AMPA receptor antibodies: a case series. Journal of Neurology, Neurosurgery and Psychiatry 86, 965972.CrossRefGoogle ScholarPubMed
Finke, C, Kopp, UA, Scheel, M, Pech, LM, Soemmer, C, Schlichting, J, Leypoldt, F, Brandt, AU, Wuerfel, J, Probst, C, Ploner, CJ, Pruss, H and Paul, F (2013) Functional and structural brain changes in anti-N-methyl-D-aspartate receptor encephalitis. Annals of Neurology 74(2), 284296.Google ScholarPubMed
Gable, MS, Gavali, S, Radner, A, Tilley, DH, Lee, B, Dyner, L, Collins, A, Dengel, A, Dalmau, J and Glaser, CA (2009) Anti-NMDA receptor encephalitis: report of ten cases and comparison with viral encephalitis. European Journal of Clinical Microbiology and Infectious Diseases 28, 14211429.CrossRefGoogle ScholarPubMed
Gable, MS, Sheriff, H, Dalmau, J, Tilley, DH and Glaser, CA (2012) The frequency of autoimmune N-methyl-D-aspartate receptor encephalitis surpasses that of individual viral etiologies in young individuals enrolled in the California Encephalitis Project. Clinical Infectious Diseases 54, 899904.CrossRefGoogle Scholar
Granerod, J, Ambrose, HE, Davies, NW, Clewley, JP, Walsh, AL, Morgan, D, Cunningham, R, Zuckerman, M, Mutton, KJ, Solomon, T, Ward, KN, Lunn, MP, Irani, SR, Vincent, A, Brown, DW and Crowcroft, NS (2010) Causes of encephalitis and differences in their clinical presentations in England: a multicentre, population-based prospective study. Lancet Infectious Diseases 10, 835844.CrossRefGoogle ScholarPubMed
Graus, F, Boronat, A, Xifro, X, Boix, M, Svigelj, V, Garcia, A, Palomino, A, Sabater, L, Alberch, J and Saiz, A (2010) The expanding clinical profile of anti-AMPA receptor encephalitis. Neurology 74, 857859.CrossRefGoogle ScholarPubMed
Graus, F, Titulaer, MJ, Balu, R, Benseler, S, Bien, CG, Cellucci, T, Cortese, I, Dale, RC, Gelfand, JM, Geschwind, M, Glaser, CA, Honnorat, J, Hoftberger, R, Iizuka, T, Irani, SR, Lancaster, E, Leypoldt, F, Pruss, H, Rae-Grant, A, Reindl, M, Rosenfeld, MR, Rostasy, K, Saiz, A, Venkatesan, A, Vincent, A, Wandinger, KP, Waters, P and Dalmau, J (2016) A clinical approach to diagnosis of autoimmune encephalitis. Lancet Neurology 15, 391404.CrossRefGoogle ScholarPubMed
Gresa-Arribas, N, Titulaer, MJ, Torrents, A, Aguilar, E, Mccracken, L, Leypoldt, F, Gleichman, AJ, Balice-Gordon, R, Rosenfeld, MR, Lynch, D, Graus, F and Dalmau, J (2014) Antibody titres at diagnosis and during follow-up of anti-NMDA receptor encephalitis: a retrospective study. Lancet Neurology 13, 167177.CrossRefGoogle ScholarPubMed
Guan, HZ, Ren, HT, Yang, XZ, Lu, Q, Peng, B, Zhu, YC, Shao, XQ, Hu, YQ, Zhou, D and Cui, LY (2015) Limbic encephalitis associated with anti-gamma-aminobutyric acid B receptor antibodies: a case series from China. Chinese Medical Journal 128, 30233028.CrossRefGoogle ScholarPubMed
Hammer, C, Stepniak, B, Schneider, A, Papiol, S, Tantra, M, Begemann, M, Siren, AL, Pardo, LA, Sperling, S, Mohd Jofrry, S, Gurvich, A, Jensen, N, Ostmeier, K, Luhder, F, Probst, C, Martens, H, Gillis, M, Saher, G, Assogna, F, Spalletta, G, Stocker, W, Schulz, TF, Nave, KA and Ehrenreich, H (2014) Neuropsychiatric disease relevance of circulating anti-NMDA receptor autoantibodies depends on blood-brain barrier integrity. Molecular Psychiatry 19, 11431149.CrossRefGoogle ScholarPubMed
Heine, J, Pruss, H, Bartsch, T, Ploner, CJ, Paul, F and Finke, C (2015) Imaging of autoimmune encephalitis - relevance for clinical practice and hippocampal function. Neuroscience 309, 6883.CrossRefGoogle ScholarPubMed
Herken, J and Pruss, H (2017) Red flags: clinical signs for identifying autoimmune encephalitis in psychiatric patients. Frontiers in Psychiatry 8, 25.CrossRefGoogle ScholarPubMed
Höftberger, R, Titulaer, MJ, Sabater, L, Dome, B, Rozsas, A, Hegedus, B, Hoda, MA, Laszlo, V, Ankersmit, HJ, Harms, L, Boyero, S, De Felipe, A, Saiz, A, Dalmau, J and Graus, F (2013) Encephalitis and GABAB receptor antibodies: novel findings in a new case series of 20 patients. Neurology 81, 15001506.CrossRefGoogle Scholar
Höftberger, R, Van Sonderen, A, Leypoldt, F, Houghton, D, Geschwind, M, Gelfand, J, Paredes, M, Sabater, L, Saiz, A, Titulaer, MJ, Graus, F and Dalmau, J (2015) Encephalitis and AMPA receptor antibodies: novel findings in a case series of 22 patients. Neurology 84, 24032412.CrossRefGoogle Scholar
Irani, SR, Alexander, S, Waters, P, Kleopa, KA, Pettingill, P, Zuliani, L, Peles, E, Buckley, C, Lang, B and Vincent, A (2010a) Antibodies to Kv1 potassium channel-complex proteins leucine-rich, glioma inactivated 1 protein and contactin-associated protein-2 in limbic encephalitis, Morvan’s syndrome and acquired neuromyotonia. Brain 133, 27342748.CrossRefGoogle ScholarPubMed
Irani, SR, Bera, K, Waters, P, Zuliani, L, Maxwell, S, Zandi, MS, Friese, MA, Galea, I, Kullmann, DM, Beeson, D, Lang, B, Bien, CG and Vincent, A (2010b) N-methyl-D-aspartate antibody encephalitis: temporal progression of clinical and paraclinical observations in a predominantly non-paraneoplastic disorder of both sexes. Brain 133(Pt 6), 16551667.CrossRefGoogle Scholar
Irani, SR, Michell, AW, Lang, B, Pettingill, P, Waters, P, Johnson, MR, Schott, JM, Armstrong, RJ, Zagami, AS, Bleasel, A, Somerville, ER, Smith, SM and Vincent, A (2011). Faciobrachial dystonic seizures precede Lgi1 antibody limbic encephalitis. Annals of Neurology 69, 892900.CrossRefGoogle ScholarPubMed
Jezequel, J, Johansson, EM, Dupuis, JP, Rogemond, V, Grea, H, Kellermayer, B, Hamdani, N, Le Guen, E, Rabu, C, Lepleux, M, Spatola, M, Mathias, E, Bouchet, D, Ramsey, AJ, Yolken, RH, Tamouza, R, Dalmau, J, Honnorat, J, Leboyer, M and Groc, L (2017) Dynamic disorganization of synaptic NMDA receptors triggered by autoantibodies from psychotic patients. Nature Communications 8, 1791.CrossRefGoogle ScholarPubMed
Jones, CA, Watson, DJ and Fone, KC (2011) Animal models of schizophrenia. British Journal of Pharmacology 164, 11621194.CrossRefGoogle ScholarPubMed
Kegel, L, Aunin, E, Meijer, D and Bermingham, JR (2013) LGI proteins in the nervous system. ASN Neuro 5, 167181.CrossRefGoogle ScholarPubMed
Kim, TJ, Lee, ST, Shin, JW, Moon, J, Lim, JA, Byun, JI, Shin, YW, Lee, KJ, Jung, KH, Kim, YS, Park, KI, Chu, K and Lee, SK (2014) Clinical manifestations and outcomes of the treatment of patients with GABAB encephalitis. Journal of Neuroimmunology 270, 4550.CrossRefGoogle ScholarPubMed
Kruer, MC, Hoeftberger, R, Lim, KY, Coryell, JC, Svoboda, MD, Woltjer, RL and Dalmau, J (2014) Aggressive course in encephalitis with opsoclonus, ataxia, chorea, and seizures: the first pediatric case of gamma-aminobutyric acid type B receptor autoimmunity. JAMA Neurology 71, 620623.CrossRefGoogle ScholarPubMed
Kuppuswamy, PS, Takala, CR and Sola, CL (2014) Management of psychiatric symptoms in anti-NMDAR encephalitis: a case series, literature review and future directions. General Hospital Psychiatry 36, 388391.CrossRefGoogle ScholarPubMed
Lai, M, Hughes, EG, Peng, X, Zhou, L, Gleichman, AJ, Shu, H, Mata, S, Kremens, D, Vitaliani, R, Geschwind, MD, Bataller, L, Kalb, RG, Davis, R, Graus, F, Lynch, DR, Balice-Gordon, R and Dalmau, J (2009) AMPA receptor antibodies in limbic encephalitis alter synaptic receptor location. Annals of Neurology 65, 424434.CrossRefGoogle ScholarPubMed
Lai, M, Huijbers, MG, Lancaster, E, Graus, F, Bataller, L, Balice-Gordon, R, Cowell, JK and Dalmau, J (2010) Investigation of LGI1 as the antigen in limbic encephalitis previously attributed to potassium channels: a case series. Lancet Neurology 9, 776785.CrossRefGoogle ScholarPubMed
Lancaster, E (2016) The diagnosis and treatment of autoimmune encephalitis. Journal of Clinical Neurology 12, 113.CrossRefGoogle ScholarPubMed
Lancaster, E and Dalmau, J (2012) Neuronal autoantigens – pathogenesis, associated disorders and antibody testing. Nature Reviews Neurology 8, 380390.CrossRefGoogle ScholarPubMed
Lancaster, E, Lai, M, Peng, X, Hughes, E, Constantinescu, R, Raizer, J, Friedman, D, Skeen, MB, Grisold, W, Kimura, A, Ohta, K, Iizuka, T, Guzman, M, Graus, F, Moss, SJ, Balice-Gordon, R and Dalmau, J (2010) Antibodies to the GABA(B) receptor in limbic encephalitis with seizures: case series and characterisation of the antigen. Lancet Neurology 9, 6776.CrossRefGoogle ScholarPubMed
Lee, EM, Kang, JK, Oh, JS, Kim, JS, Shin, YW and Kim, CY (2014) 18F-fluorodeoxyglucose positron-emission tomography findings with anti-N-methyl-D-aspartate receptor encephalitis that showed variable degrees of catatonia: three cases report. Journal of Epilepsy Research 4, 6973.CrossRefGoogle ScholarPubMed
Lee, WJ, Lee, ST, Moon, J, Sunwoo, JS, Byun, JI, Lim, JA, Kim, TJ, Shin, YW, Lee, KJ, Jun, JS, Lee, HS, Kim, S, Park, KI, Jung, KH, Jung, KY, Kim, M, Lee, SK and Chu, K (2016) Tocilizumab in autoimmune encephalitis refractory to rituximab: an institutional cohort study. Neurotherapeutics 13, 824832.CrossRefGoogle Scholar
Lim, JA, Lee, ST, Moon, J, Jun, JS, Park, BS, Byun, JI, Sunwoo, JS, Park, KI, Jung, KH, Jung, KY, Lee, SK and Chu, K (2016) New feasible treatment for refractory autoimmune encephalitis: low-dose interleukin-2. Journal of Neuroimmunology 299, 107111.CrossRefGoogle ScholarPubMed
Linnoila, JJ, Binnicker, MJ, Majed, M, Klein, CJ and Mckeon, A (2016) CSF herpes virus and autoantibody profiles in the evaluation of encephalitis. Neurology: Neuroimmunology & Neuroinflammation 3, e245.Google ScholarPubMed
Lodge, D and Mercier, MS (2015) Ketamine and phencyclidine: the good, the bad and the unexpected. British Journal of Pharmacology 172, 42544276.CrossRefGoogle ScholarPubMed
Mackay, MAB, Kravtsenyuk, M, Thomas, R, Mitchell, ND, Dursun, SM and Baker, GB (2019) D-serine: potential therapeutic agent and/or biomarker in schizophrenia and depression?. Frontiers in Psychiatry 10, 25.CrossRefGoogle ScholarPubMed
Mantere, O, Saarela, M, Kieseppa, T, Raij, T, Mantyla, T, Lindgren, M, Rikandi, E, Stoecker, W, Teegen, B and Suvisaari, J (2018) Anti-neuronal anti-bodies in patients with early psychosis. Schizophrenia Research 192, 404407.CrossRefGoogle ScholarPubMed
Masdeu, JC, Gonzalez-Pinto, A, Matute, C, Ruiz De Azua, S, Palomino, A, De Leon, J, Berman, KF and Dalmau, J (2012). Serum IgG antibodies against the NR1 subunit of the NMDA receptor not detected in schizophrenia. American Journal of Psychiatry 169, 11201121.CrossRefGoogle ScholarPubMed
Moghaddam, B and Javitt, D (2011) From revolution to evolution: the glutamate hypothesis of schizophrenia and its implication for treatment. Neuropsychopharmacology 37, 4.CrossRefGoogle ScholarPubMed
Morbelli, S, Djekidel, M, Hesse, S, Pagani, M and Barthel, H (2016) Role of (18)F-FDG-PET imaging in the diagnosis of autoimmune encephalitis. Lancet Neurology 15, 10091010.CrossRefGoogle Scholar
Nosadini, M, Mohammad, SS, Corazza, F, Ruga, EM, Kothur, K, Perilongo, G, Frigo, AC, Toldo, I, Dale, RC and Sartori, S (2017) Herpes simplex virus-induced anti-N-methyl-D-aspartate receptor encephalitis: a systematic literature review with analysis of 43 cases. Developmental Medicine and Child Neurology 59, 796805.CrossRefGoogle ScholarPubMed
Oldham, M (2017) Autoimmune encephalopathy for psychiatrists: when to suspect autoimmunity and what to do next. Psychosomatics 58, 228244.CrossRefGoogle Scholar
Pathmanandavel, K, Starling, J, Merheb, V, Ramanathan, S, Sinmaz, N, Dale, RC and Brilot, F (2015) Antibodies to surface dopamine-2 receptor and N-methyl-D-aspartate receptor in the first episode of acute psychosis in children. Biological Psychiatry 77, 537547.CrossRefGoogle ScholarPubMed
Pearlman, DM and Najjar, S (2014) Meta-analysis of the association between N-methyl-d-aspartate receptor antibodies and schizophrenia, schizoaffective disorder, bipolar disorder, and major depressive disorder. Schizophrenia Research 157, 249258.CrossRefGoogle ScholarPubMed
Peer, M, Pruss, H, Ben-Dayan, I, Paul, F, Arzy, S and Finke, C (2017) Functional connectivity of large-scale brain networks in patients with anti-NMDA receptor encephalitis: an observational study. Lancet Psychiatry 4, 768774.CrossRefGoogle ScholarPubMed
Peng, X, Hughes, e.g.Moscato, EH, Parsons, TD, Dalmau, J and Balice-Gordon, RJ (2015) Cellular plasticity induced by anti-alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptor encephalitis antibodies. Annals of Neurology 77, 381398.CrossRefGoogle ScholarPubMed
Probasco, JC, Solnes, L, Nalluri, A, Cohen, J, Jones, KM, Zan, E, Javadi, MS and Venkatesan, A (2017) Abnormal brain metabolism on FDG-PET/CT is a common early finding in autoimmune encephalitis. Neurology: Neuroimmunology and NeuroInflammation 4, e352.Google ScholarPubMed
Pruss, H, Finke, C, Holtje, M, Hofmann, J, Klingbeil, C, Probst, C, Borowski, K, Ahnert-Hilger, G, Harms, L, Schwab, JM, Ploner, CJ, Komorowski, L, Stoecker, W, Dalmau, J and Wandinger, KP (2012) N-methyl-D-aspartate receptor antibodies in herpes simplex encephalitis. Annals of Neurology 72, 902911.CrossRefGoogle ScholarPubMed
Quartuccio, N, Caobelli, F, Evangelista, L, Alongi, P, Kirienko, M, De Biasi, V and Cocciolillo, F (2015) The role of PET/CT in the evaluation of patients affected by limbic encephalitis: a systematic review of the literature. Journal of Neuroimmunology 284, 4448.CrossRefGoogle ScholarPubMed
Rhoads, J, Guirgis, H, Mcknight, C and Duchemin, AM (2011) Lack of anti-NMDA receptor autoantibodies in the serum of subjects with schizophrenia. Schizophrenia Research 129, 213214.CrossRefGoogle ScholarPubMed
Riedmuller, R and Muller, S (2017) Ethical implications of the mild encephalitis hypothesis of schizophrenia. Frontiers in Psychiatry 8, 38.CrossRefGoogle ScholarPubMed
Shin, YW, Lee, ST, Park, KI, Jung, KH, Jung, KY, Lee, SK and Chu, K (2018) Treatment strategies for autoimmune encephalitis. Therapeutic Advances in Neurological Disorders 11, 119.CrossRefGoogle ScholarPubMed
Shin, YW, Lee, ST, Shin, JW, Moon, J, Lim, JA, Byun, JI, Kim, TJ, Lee, KJ, Kim, YS, Park, KI, Jung, KH, Lee, SK and Chu, K (2013) VGKC-complex/LGI1-antibody encephalitis: clinical manifestations and response to immunotherapy. Journal of Neuroimmunology 265, 7581.CrossRefGoogle ScholarPubMed
Solimena, M, Folli, F, Aparisi, R, Pozza, G and De Camilli, P (1990) Autoantibodies to GABA-ergic neurons and pancreatic beta cells in stiff-man syndrome. New England Journal of Medicine 322, 15551560.CrossRefGoogle ScholarPubMed
Solnes, LB, Jones, KM, Rowe, SP, Pattanayak, P, Nalluri, A, Venkatesan, A, Probasco, JC and Javadi, MS (2017) Diagnostic value of (18)F-FDG PET/CT versus MRI in the setting of antibody-specific autoimmune encephalitis. Journal of Nuclear Medicine 58, 13071313.CrossRefGoogle ScholarPubMed
Steiner, J, Walter, M, Glanz, W, Sarnyai, Z, Bernstein, HG, Vielhaber, S, Kastner, A, Skalej, M, Jordan, W, Schiltz, K, Klingbeil, C, Wandinger, KP, Bogerts, B and Stoecker, W (2013) Increased prevalence of diverse N-methyl-D-aspartate glutamate receptor antibodies in patients with an initial diagnosis of schizophrenia: specific relevance of IgG NR1a antibodies for distinction from N-methyl-D-aspartate glutamate receptor encephalitis. JAMA Psychiatry 70, 271278.CrossRefGoogle ScholarPubMed
Su, M, Xu, D and Tian, R (2015) 18F-FDG PET/CT and MRI findings in a patient with anti-GABA(B) receptor encephalitis. Clinical Nuclear Medicine 40, 515517.CrossRefGoogle Scholar
Titulaer, MJ, Mccracken, L, Gabilondo, I, Armangue, T, Glaser, C, Iizuka, T, Honig, LS, Benseler, SM, Kawachi, I, Martinez-Hernandez, E, Aguilar, E, Gresa-Arribas, N, Ryan-Florance, N, Torrents, A, Saiz, A, Rosenfeld, MR, Balice-Gordon, R, Graus, F and Dalmau, J (2013) Treatment and prognostic factors for long-term outcome in patients with anti-NMDA receptor encephalitis: an observational cohort study. Lancet Neurology 12, 157165.CrossRefGoogle ScholarPubMed
Tofaris, GK, Irani, SR, Cheeran, BJ, Baker, IW, Cader, ZM and Vincent, A (2012) Immunotherapy-responsive chorea as the presenting feature of LGI1-antibody encephalitis. Neurology 79, 195196.CrossRefGoogle ScholarPubMed
Tsutsui, K, Kanbayashi, T, Tanaka, K, Boku, S, Ito, W, Tokunaga, J, Mori, A, Hishikawa, Y, Shimizu, T and Nishino, S (2012) Anti-NMDA-receptor antibody detected in encephalitis, schizophrenia, and narcolepsy with psychotic features. BMC Psychiatry 12, 37.CrossRefGoogle ScholarPubMed
Tuzun, E and Dalmau, J (2007) Limbic encephalitis and variants: classification, diagnosis and treatment. Neurologist 13, 261271.Google Scholar
Van Elst, LT, Kloppel, S and Rauer, S (2011) Voltage-gated potassium channel/LGI1 antibody-associated encephalopathy may cause brief psychotic disorder. Journal of Clinical Psychiatry 72, 722723.CrossRefGoogle ScholarPubMed
Venkatesan, A and Adatia, K (2017) Anti-NMDA-receptor encephalitis: from bench to clinic. ACS Chemical Neuroscience 8, 25862595.CrossRefGoogle ScholarPubMed
Zandi, MS, Irani, SR, Lang, B, Waters, P, Jones, PB, Mckenna, P, Coles, AJ, Vincent, A and Lennox, BR (2011) Disease-relevant autoantibodies in first episode schizophrenia. Journal of Neurology 258, 686688.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Selected types of antibody-mediated encephalitis and their associated general classification