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November 2021; 8 (6) Views & ReviewsOpen Access

Neuromyelitis Optica Spectrum Disorders in Africa

A Systematic Review

Abdu Kisekka Musubire, Judith Derdelinckx, Tatjana Reynders, David B. Meya, Paul R. Bohjanen, Patrick Cras, Barbara Willekens
First published October 18, 2021, DOI: https://doi.org/10.1212/NXI.0000000000001089
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Abstract

Background and Objectives Neuromyelitis optica (NMO) is a CNS inflammatory disease that predominantly affects the optic nerves and the spinal cord. It is more frequent in Asian and African populations than in European ones. Data on epidemiology, clinical presentation, additional investigations, and treatment in the African continent are scarce. We aim to (1) collect and analyze published data on neuromyelitis optica spectrum disorder (NMOSD), (2) indicate challenges in the diagnosis and management, and (3) discuss opportunities for future research, education, and policy making, specifically on the African continent.

Methods A systematic review was performed in January 2021 with the search terms “Neuromyelitis optica and Africa,” “Devic Disease and Africa,” and “NMOSD and Africa.” We included all study types except case reports, correspondence, or conference abstracts on NMO or NMOSD. Extracted data included study design, country, study period, demographic and clinical characteristics, results of paraclinical investigations, and outcome. Data analysis was performed with descriptive statistics.

Results We retrieved a total of 79 records, of which 19 were included. Ten of 54 African countries reported a total of 410 cases. Almost half of them were from North African countries. The mean age at diagnosis was 33 years (range 7–88 years), and 75% were female. Transverse myelitis followed by optic neuritis were the most frequent symptoms at the time of presentation. One hundred nineteen patients experienced at least 1 previous relapse, and 106 had a relapsing course after diagnosis. Relapses were treated with IV methylprednisolone. Azathioprine and steroids were used most often as maintenance treatments. Outcomes were rarely described.

Discussion The majority of studies on NMOSD from the African continent are retrospective, and most countries do not report any data. Our systemic review shows that data derived from patients living in Africa correspond well to what has been previously published in meta-analyses on patients of African ancestry with NMOSD who live outside of Africa, except for a younger age at onset and a lower proportion of females. We advocate for systematic data collection to adequately capture and monitor the burden of NMOSD, for expansion of research efforts and facilities to perform fundamental and clinical research, and for improved access to health care including diagnostics, treatments, and rehabilitation services for people affected by NMOSD in the African continent.

Glossary

EDSS=
Expanded Disability Status Scale;
IPND=
International Panel for NMO Diagnosis;
IVMP=
IV methylprednisolone;
LETM=
longitudinally extensive transverse myelitis;
LMICs=
low- and middle-income countries;
MOG=
myelin oligodendrocyte glycoprotein;
MS=
multiple sclerosis;
NMO=
neuromyelitis optica;
NMOSD=
neuromyelitis optica spectrum disorder;
PRISMA=
Preferred Reporting Items for Systematic Reviews and Meta-Analyses;
TB=
tuberculosis;
TM=
transverse myelitis;
VEP=
visual evoked potential

Neuromyelitis optica (NMO) is a CNS inflammatory disease that predominantly affects the optic nerves and the spinal cord.1 NMO was first described in 1864 by Eugène Devic and has been regarded as a variant of multiple sclerosis (MS) until aquaporin 4 (AQP4) antibodies were discovered to be associated with some cases of NMO but not MS.2,-,4 The correct diagnosis and distinction of these disorders from MS is important because treatment and prognosis are different.5 Further clinical and fundamental research has led to the improved understanding of this condition as neuromyelitis optica spectrum disorders (NMOSDs) with variable clinical presentations in a disease spectrum rather than a single disease entity.6 In a proportion of patients with AQP4-seronegative NMOSD, anti–myelin oligodendrocyte glycoprotein (MOG) antibodies are present.7,-,10 The diagnostic criteria for NMO and disease spectrum have evolved over the years, and for an overview of these criteria, we refer to a review article on the evolving diagnostic criteria of NMO.11 The most recent international consensus criteria have been defined by the International Panel for NMO diagnosis (IPND) in 2015.6 NMOSDs have been found to predominantly occur in people from Asian or African descent as opposed to MS, which occurs primarily in populations from European ancestry.12 In some studies performed on populations living off the African continent, NMOSD affected more persons of African descent, in comparison to non-Africans living in the same geographical setting.12,-,14 This observation has been confirmed by a recent meta-analysis on the world-wide incidence and prevalence of NMOSD, leading to the conclusion that NMOSD was more frequent in people from Asian and African descent than in those from European descent.15,-,17 However, only 1 report on NMOSD in the African continent from Nigeria was shortly mentioned in 1 of these reviews.17 This is striking, as Africa is the continent harboring the largest population of people from Black origin, a race known to be most affected by NMOSD. Besides an estimate of prevalence in Ghana of 0.12/100,000 and South Africa of 5/100,000 coming from Multiple Sclerosis International Federation query data,18 no data on prevalence of NMOSD in the African continent are available.

There have been a few studies that have investigated transverse myelitis (TM) in Africa as part of nontraumatic myelopathy,19,-,28 with very few studies focusing on NMOSD.21,29 Most of them focus on extrinsic compression and infectious diseases as important causes of myelopathy. In resource-limited areas, such as the low- and middle-income countries (LMICs) in Africa, it is not surprising that infectious diseases have been prioritized above noncommunicable diseases. Recent studies suggest that an increasing presence of noncompressive myelopathy occurs on the African continent.21,30 The increasing prevalence of noncompressive myelopathy requires a comprehensive understanding of the other possible causes of myelopathy in the African continent. The African continent is predicted to be home to over half of the expected global population growth between 2015 and 2050,31 highlighting the importance of addressing health and disease in the entire continent. The African Union, comprising all countries on the African continent, has published a document on the Health Strategy for the entire continent.32 Hence, collecting data from the entire continent may allow evidence-based health care planning and resource allocation. We undertook this review of studies performed in Africa to describe the current knowledge on the epidemiology, clinical presentation, additional investigations, and treatment options available in patients affected by NMOSD on the African continent. The overall aim was to improve the understanding and consequences of this disease in Africa and suggest areas where further research is needed.

Methods

Two reviewers (A.K.M. and B.W.) independently performed a literature search on PubMed with the following search terms “Neuromyelitis optica and Africa,” “Devic Disease and Africa,” and “NMOSD and Africa,” without filters on publication date, article type, or language. The search was performed between January 21 and 28, 2021. Both reviewers independently assessed the abstracts for eligibility according to the following inclusion criteria: (1) population described from the African continent, (2) topic of the article included NMO, NMOSD, or Devic disease, and (3) study design was a prospective or retrospective, case series, cohort studies, and cross-sectional studies. No specific diagnostic criteria for NMO(SD) were used for inclusion. We excluded studies based on the following criteria: (1) studies without African populations and studies describing patients from African ancestry in other countries, (2) case reports, (3) studies without participants with confirmed or suspected NMO, and (4) correspondence, conference abstracts, and commentaries due to limited data. Disagreements on eligibility were solved in consensus. Full-text articles were reviewed, and the reference lists were hand searched for identification of other relevant studies. We extracted the following data from the full-text articles: study characteristics (study design, study location and country, hospital (including type of hospital, teaching, or lower level), or community), demographic data, clinical variables including investigational findings of MRI, CSF, and results of AQP4 or MOG antibody tests, treatments, and outcomes. The Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines for reporting systematic reviews were followed.33 No systematic quality assessment of studies was performed. Descriptive statistics were used to analyze the data. The prevalence was estimated by calculating ratio of the total number of cases to the number of inhabitants per country (in the last year of the study period, most recent year was used in case there were multiple publications from a single country) and expressed as number of cases per 100,000 inhabitants. Population figures were derived from the United Nations.34

Data Availability

All data were derived from resources available in the public domain, as referred to in the reference list.

Results

Search Results

Our search terms provided us with a total of 79 records (“Neuromyelitis optica and Africa”: 34 records, “Devic Disease and Africa”: 35 records, and “NMOSD and Africa”: 10 records). The selection process is depicted in the PRISMA flow diagram in the Figure. After removal of 44 duplicates, 35 records remained. We assessed the abstracts according to inclusion and exclusion criteria and remained with 16 records that were read full text. From these sources, 3 additional records were identified, leading to 19 records that were finally included.

Figure
Figure PRISMA Flow Diagram of the Study Selection Process

Study Characteristics

Of 19 records in this review, 8 were from North Africa (4 countries—Morocco, Tunisia, Egypt, and Algeria), 4 from West Africa (3 countries—Senegal, Niger, and Nigeria), 5 from South Africa (all from South Africa), and 2 from East Africa (2 countries—Sudan and Ethiopia). Although all African regions are represented in the study sample, the data collected come from only 10 countries out of a total of 54 countries (18.5%) on the African continent. Almost all studies (95%) were retrospective, and 100% of the studies were hospital based. Publication dates varied between 1971 and 2020, but 15/19 (79%) articles were published after 2004. The data collection period varied between 1 year and 21 years (Table 1). Many studies documented a diagnosis of NMOSD using the IPND 20156 diagnostic criteria in 9 of 19 records. Earlier diagnostic criteria were used in the remaining studies (1894 Devic NMO case—2/19, 1999 NMO criteria35—5/19, 2006 NMO criteria1 3/19) (Table 1 and Table 3). Other studies had diverse populations with patients with NMOSD included in 4/19 studies on demyelinating diseases of the CNS, 3/19 studies on general inflammatory conditions of the CNS, 2/19 studies on nontraumatic myelopathy, and 1/19 studies on all medical neurologic diseases (Table 1). The total number of patients diagnosed with NMO or NMOSD from 10/54 countries was 410. The majority of cases (48%, N = 196) have been described in North African cohorts, followed by West Africa (29%, N = 120) and South Africa (14%, N = 59), with the lowest number of reported cases (9%, N = 35) coming from East Africa (Table 2). The proportion of NMO cases increased from 2% in nontraumatic myelopathy (4/105 + 2/100 cases21,29), to 5% in cohorts of CNS inflammatory diseases (20/40036 + 8/93837 + 9/170 cases38), and to 58% in cohorts of patients presenting with ON and TM, in whom the clinical suspicion of NMOSD is high (22/39 + 21/42 + 4/7 cases).39,-,41 However, definitions used to diagnose NMO/NMOSD varied between studies and differed according to the year of publication (Table 3). The time to diagnosis from onset of the symptoms ranged from weeks to years, with most studies stating a time to diagnosis of more than 9 months.

View this table:
Table 1

Description of Study Characteristics

View this table:
Table 2

Demographic Characteristics of Patients With Neuromyelitis Optica Spectrum Disorder in Africa

View this table:
Table 3

Clinical Characteristics of Patients Presenting With NMOSD in Africa

Demographic Characteristics

The NMO-to-MS ratio is lower in North African countries (9:67,36 64:503,42 20:330,37 8:87738) and higher in studied populations from sub-Saharan Africa (2:029, 4:341, 95:243). Women are affected most frequently with NMO (82%, 252 women out of total of 309 patients from 16 studies excluding studies without complete data on NMO21,29,43). The mean age at diagnosis of NMO was 33 years, and the mean age by region was highest in East Africa (38 years), followed by North Africa (35 years), West Africa (34 years), and finally South Africa (29 years). In one study from Tunisia36 the authors reported a significantly higher mean age of 51 years, quite different from all the other studies where the range was between 20 and 40 years. The age of those affected ranged from 7 to 88 years (Table 2). Prevalence estimates ranged between 0.004/100,000 in Ethiopia and 0.1/100,000 and 0.17/100,000 in Senegal and Nigeria, respectively (Table 4).

View this table:
Table 4

Prevalence Estimates

Clinical Presentation and Comorbidities

The clinical presentation was variable between the studies (Table 3). After excluding 4 studies without detailed clinical information,21,29,40,43 the remaining 15 studies represented a sample size of 287 subjects. Among these, TM was the most common presenting syndrome (45%), followed by ON (41%), both TM and ON combined (15%), and finally brainstem syndromes (8%). One hundred eleven patients were evaluated and diagnosed after they had experienced a previous attack. One hundred six patients had at least 1 relapse during further follow-up. Seven studies described the presence of comorbid connective tissue diseases either by clinical or laboratory evidence of predominantly antinuclear antibody–related diseases. Some studies specifically investigated the presence of HIV and tuberculosis (TB) in the study population. No definite conclusions on the association of these concurrent infections, that are highly prevalent on the African continent, were drawn.42,44,-,46

MRI, Visual Evoked Potential, and Optical Coherence Tomography Data

Of the studies included, 16 studies reported detailed MRI data, providing a sample size of 309 participants of whom MRI characteristics were reported (Table 5). Brain lesions appeared in 51% (159/309), and longitudinally extensive transverse myelitis (LETM) was reported in 73% (225/309) of the patients. The region most affected in the spinal cord, based on 11 studies36,37,41,42,44,47,-,52 in which detailed MRI results were reported by the spinal region (sample size of 223 participants), was the cervical cord (91/223, 41%). This was followed by the cervicothoracic cord (54/223, 24%) and finally the thoracic cord (25/223, 11%).37,41,42,44,47,48,50,-,52 Visual evoked potentials (VEP) were abnormal in the majority of the patients in whom they were performed.36,38,39,44,48,51,52 Optical coherence tomography was mentioned only in 1 study and was abnormal in a patient with recurrent ON.38

View this table:
Table 5

Results of Paraclinical Investigations in Patients Presenting With Neuromyelitis Optica Spectrum Disorder in Africa

Laboratory Tests

Of the 12 studies that performed an AQP4 antibody assay, 53% (147/276) of cases were positive.36,-,42,45,47,48,51 Most studies used indirect immunofluorescence cell-based assay (Table 5). MOG antibody assay was only reported in 2 studies from North Africa and was positive in 10% (7/73) of the patients.39,48 Oligoclonal bands were present in only 5% (10/221) of patients in the 12 studies in which they were assessed.36,-,42,45,47,50,52

Treatment

The treatment modalities and outcomes are summarized in Table 6. Steroids and azathioprine were the most frequently used therapies. The main treatment modality for acute attacks was IV methylprednisolone (IVMP) for a duration of 3–5 days but in 1 study up to 10 days.41 In 2 studies, oral prednisolone was used.43 Another 2 studies did not present any information about their treatment modalities.36,53 A few cases received treatment with plasmapheresis 3 to 6 sessions every other day in Morocco and Algeria (4%, 16/410) or IV immunoglobulins (less than 1%, 2/410). The maintenance therapy consisted of steroids (52%, 211/410), with a few cases treated with methotrexate (n = 2), mycophenolate mofetil (n = 3), cyclophosphamide (11%, 47/410, only Morocco), and mitoxantrone (n = 4). The second most used maintenance therapy was azathioprine, (28.3%, 116/410), and in a few cases, rituximab was used in Morocco (6.3%, 26/410). The treatments led to a favorable outcome in about 50% of the studies that reported treatment outcomes. However, clinical outcomes were described only in a few studies, and the Expanded Disability Status Scale (EDSS) was reported in only 4 of them.42,47,-,52

View this table:
Table 6

Treatment Options and Outcomes Among Patients Presenting With NMOSD in Africa

Discussion

We have reviewed the epidemiology, clinical presentation, additional investigations, treatment options, and outcomes of patients with NMOSD on the African continent. We found only limited data available in the literature, with only 10 of the 54 countries reporting on patient cohorts, and most data were hospital based. NMOSD occurs in all regions of the continent, suggesting that it is a pan-African occurring disorder. Indeed, a number of case reports, including reports from countries not represented in our review, have been published (Burkina Faso, Ghana, South Africa, Uganda, Nigeria, and Togo).46,54,-,60,e1-e6 Prospective data are scarce, and most studies were retrospective in nature, with inclusion criteria that varied over time in accordance with evolving diagnostic criteria of NMO and NMOSD.11

Two recent reviews have emphasized the high prevalence of NMOSD in populations of African ancestry that may be as high as 10/100,000 in black people.15,e7,e8 All studies cited in these reviews have been performed off the African Continent in French Martinique, the United States, the United Kingdom, Cuba, and New Zealand. The exact incidence and prevalence of NMOSD on the African continent remain unknown to date. The prevalence estimates that resulted from the analysis of the collected data from the published literature likely represent a massive underestimation of the real prevalence. Indeed, the estimated prevalence data from South Africa are lower than those reported in the query data from Multiple Sclerosis International Federation.18 This underscores the need for prospective nationwide or even continent-wide data collection initiatives. Limited human and financial resources, lack of systematic data collection on neurologic disorders, and numerous barriers to health care services may contribute to the lack of knowledge on epidemiologic data on NMOSD in Africa.e9

NMOSD predominantly affects women and young adults in Africa, similar to other parts of the world. However, the female-to-male ratio of 3.5:1 is lower than reported in other review articles, which may be as high as 9:1 in AQP4-IgG–positive NMOSD.e7 The age at diagnosis in our review was younger than the average of 40 years stated in other reviews.15,e7,e8 In comparison to a study that evaluated racial differences, Afro-Americans and Afro-Europeans had a younger age of onset than patients of European descent,e10 which may mean that the African ancestry may predispose to a younger age at onset. Sex, however, did not differ between races in this study, and between 84% and 90% were females.e10 Especially in African countries, the early age of onset and more severe disease course may have a high impact, as comprehensive rehabilitation services are inequitable and inaccessible in Africa.e11 Older patients may not come to the attention of health care services, and the average life expectancy of 62 years for men (range 54–72 years) and 65 years for women (range 59–75 years) may be another explanation for the young age at onset in our review.e12 Women in Africa may be less likely to have access and attend to the hospitalse13 in comparison to men, which may explain the higher proportion of men in our study. However, this hypothesis needs to be validated by community-based studies.

There seems a delay in the diagnosis as most of the studies identified patients after they had relapsed, which may translate into worse outcomes. Others reported that the median time to first relapse was about 5 months,e14 which would mean that most of African patients are diagnosed only after a first relapse, as demonstrated in 8/19 of the studies.36,-,39,47,49,-,51 This calls for early and accurate diagnosis with adequate relapse treatment and institution of a maintenance therapy to prevent subsequent relapses and disability. Indeed, it is well known that more relapses before and after treatment are independent predictors of severe motor disability.e10 Outcomes were only rarely reported with variable measures, including general terms, modified Rankin Scale score, or EDSS score. The data collected in our review were insufficient to describe outcomes in patients reliably.

The NMO:MS ratio increases when moving from the northern parts of Africa toward the south. This is not unexpected as it is known that the prevalence of MS increases with increasing latitude and lower levels of vitamin D.e15,e16

The co-occurrence of HIV infection with NMOSD has been rarely described. However, the disease course does not differ from HIV-negative patients with NMOSD.e17 Causality has not been proven yet, and potential pathophysiologic mechanisms need further investigation. Conflicting evidence exists also for TB and NMOSD.e18-e20 A strong association of NMOSD with other autoimmune diseases, especially SLE and Sjogren syndrome, is well known and has also been found in some of the studies reviewed here.e21-e23

NMOSD can present with several clinical syndromes, which include TM, ON, and area postrema syndrome.6,e24-e26 In our review, TM and ON were the most frequent presenting symptoms, whereas a combined opticospinal presentation and brainstem symptoms were less frequent. Whether other presentations occur less or are merely underreported in the African population is unknown and an area open to further research.

Most studies in our review have been published recently and used established diagnostic criteria with additional investigations including at least an MRI and serology.6 There was a high frequency of LETM on spinal cord MRI and atypical MS-like brain lesions in most of these studies.1,e27-e29 AQP4-IgG seropositivity was around 55%, which is slightly lower than has been reported in other studies,e30-e32 probably due to the various inclusion criteria and assays used.e33,e34 VEPs in NMO are useful in longitudinal follow-up of patients with NMO.e35,e36 The frequency of an abnormal VEP was high in our review, which may be due to late presentation with residual deficits from previous relapses.

Relapse treatment in NMOSD consists of high-dose IVMP and/or plasmapheresis.e37,e38 The latter is not readily available in most African countries and therefore hardly ever used according to our review in contrast to high-dose IVMP. Maintenance or preventive treatment recommendations for NMOSD include rituximab and mycophenolate as first-line agents, which are both not readily available in most African countries. Second-line agents include azathioprine, methotrexate, ciclosporin, mitoxantrone, and cyclophosphamide.e37,e38 The most common preventive treatments used were steroids and azathioprine.

Both severe and mild cases may be missed, as many patients do not receive medical care in many parts of Africa. Both access to health care and universal health coverage are strikingly low compared to Europe and the United States and worst in sub-Saharan Africa.e39,e40 Although the WHO recommends a ratio of 1 neurologist per 100,000 inhabitants, there is only a median number of 0.043 neurologist per 100,000 inhabitants in the WHO African region.e41 Most of them (97%) practice in the capital city, and only 3% are based in rural areas.e41 Some African countries have no neurologists at all.e42 This problem starts at the level of (post)graduate education, with limited options for neurologic training and scarce neurologic faculty available for teaching.e43 Moreover, access to MRI, which is crucial in making a correct diagnosis, is not available in many regions of Africa. Although there has been an increase in availability of MRI in the past few years on the African continent, in West sub-Saharan Africa, there is still a very low number of facilities (0.30–0.48/million inhabitants,e44) compared with Europe or the United States (4.91–40 per million in 2019,e45). No access to AQP4 or MOG antibody tests has been reported by approximately half (48%, 13/27) of African and Eastern Mediterranean countries.e46 This study also highlighted that patients with NMO in LMICs cannot afford immunomodulatory treatment, despite local availability of the treatments.e46 The same problem likely applies to the diagnostic tests and facilities: despite improving availability, they may remain unaffordable for many patients. International and political efforts are ongoing to improve health care coverage in LMICs, like on the African continent (e.g., UHC2030—accelerating progress toward Universal Health Coverage).

Because of limited resources, applicability of the 2015 IPND NMOSD criteria in the African setting remains challenging. Furthermore, possible relations between HIV, TB, and NMOSD need further research, and as these diseases are highly prevalent and incident on the African continent, this could lead to novel insights. Immunogenetic studies could aid in confirming or finding new genetic risk factors, such as HLA associations in the African population. In Afro-Caribbeans, an association with HLA class II allele DRB1 03 has been reported before.e47 Efforts toward development of a global neuroscientific community such as TreND in Africae48 may help to build educational and scientific capacity.

We have to address several limitations of our systematic review: most included studies were retrospective, provided incomplete data, described different populations, and used different NMO criteria over time. We also acknowledge the differences in race, genetic background,e49 cultures, and access to medical care on the vast geographical African continent. Research on risk factors and outcomes in LMICs may benefit from these variability and lead to optimization of the diagnostic and treatment pathway taking into account the limited resources. All these aspects may affect the quality of the data in a significant way. However, a major strength of our review is that it captures all available data on NMOSD, excluding single case reports, from the literature from the African continent.

Clearly, prospective data registries from the African continent would help to solve some issues raised in this article. Initiatives such as NMOBase and MOGBase, both as part of the MSBase international registry, may serve as easy-to-use data collection platforms. This registry is an international collaboration dedicated to sharing, documenting, and evaluating outcomes data in MS and other neuroimmunologic diseases, including NMO and MOG. The only 2 African countries currently actively participating in MSBase are Egypt and Tunisia. Efforts to increase awareness and knowledge on NMOSD in Africa have included dedicated conferences and support to perform AQP4 antibody assays, in which The Guthy-Jackson Charitable Foundation has played an important role. The CIRCLES initiative is collecting biospecimens and clinical data, currently only in North American sites, including the United States and Canada.e50 An NMOSD African network could be envisaged in the future. The recently inaugurated African Stroke Organization may serve as an example to establish within Africa collaborations and to strengthen the African continent on its mission to reduce the burden of neurologic diseases.

There is a clear need for prospective data collection on NMOSD in the African continent to assess the real prevalence, incidence, and burden of this disease, which may turn out not to be ultra-rare in this continent at all (ultra-rare disease affects <1 per 50 ,000 persons). The lower proportion of women and younger age at onset need further investigation. Without increasing the number of neurologists per capita, educating the population, improving accessibility and affordability of diagnostics (AQP4 and MOG antibody tests and MRI) and acute and preventive treatments, cases will continue to be missed, patients will remain undertreated and their functional outcomes will not improve. We hope that our article serves as a call to action to direct research efforts and resources toward NMOSD in Africa, as the knowledge we gain in this way may benefit all people affected by NMOSD throughout the world.

Study Funding

A.K.M. holds a grant from NIH (FIC K43TW010718,2017-2022) and this work was supported by NIH Fogarty R25, TW009345-04 (fellow, 2012-2013). B.W. is supported by a Horlait-Dapsens Medical Foundation Grant, awarded in 2020.

Disclosure

The authors report no disclosures relevant to the manuscript. Go to Neurology.org/NN for full disclosures.

Appendix Authors

Table

Footnotes

  • Go to Neurology.org/NN for full disclosures. Funding information is provided at the end of the article.

  • The Article Processing Charge was funded by the authors.

  • Received March 21, 2021.
  • Accepted in final form September 1, 2021.

This is an open access article distributed under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives License 4.0 (CC BY-NC-ND), which permits downloading and sharing the work provided it is properly cited. The work cannot be changed in any way or used commercially without permission from the journal.

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