Abstract
Objectives
Neurological symptoms associated with Severe Acute Respiratory Syndrome Coronavirus-2 (SARS-CoV-2) vaccination were discovered in the context of billions of administered vaccine doses. The clinical manifestations often resemble post Coronavirus Disease 2019 (post-COVID-19) syndrome (PCS) features and may be considered as post-COVID-19 vaccine syndrome (PVS). Data regarding frequency, severity and pathophysiological mechanisms are scarce.
Methods
We assessed routine clinical examinations in 50 patients reporting new-onset neurological symptoms after SARS-CoV-2 vaccination, including neurological examination, laboratory and electrophysiology tests, as well as self-report questionnaires measuring fatigue, depressive symptoms, anxiety, risk of somatic symptom disorder, and health-related quality of life. Patients were included when symptoms occurred after confirmed COVID-19 vaccination and without prior SARS-CoV-2 infection, and if no alternative diagnosis was found to explain the symptoms.
Results
The most frequently reported symptoms were paraesthesia (56%), fatigue (46%) and cognitive impairment (36%). Neurological, routine laboratory, and electrophysiological examinations did not yield distinct pathological findings. Neuropsychological testing of a subgroup revealed deficits in attention, executive function and memory.
Discussion
The spectrum of clinical manifestations post-vaccination poses a substantial overlap with PCS symptoms. As no pathological findings were obtained in routine diagnostics, uncertainty remains about the underlying pathophysiological mechanisms and requires further investigation beyond routine work-up.
Introduction
Post-COVID-19 syndrome (PCS) is known for its wide range of neurological and psychiatric symptoms, including fatigue, cognitive impairment, headache, depression, and anxiety [3, 4, 19]. Vaccine development has been a major breakthrough not only to reduce the number of deaths and severe cases of Coronavirus Disease 2019 (COVID-19), but also to contain the spread of Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) [6]. Additionally, there is emerging evidence that vaccination decreases the risk of developing PCS after breakthrough infection [1].
Initially, all approved vaccines were found to be safe, with generally mild and transient side effects such as pain on the injection site, fever, or headache [17]. A serious adverse event after vector vaccination is vaccine-induced immune thrombotic thrombocytopenia (VITT) [7], leading to predominant usage of mRNA-based vaccines in Germany. Other severe neurological adverse events following COVID-19 vaccination have been rarely described and involve e.g., Bell’s palsy, Guillain-Barré syndrome, acute disseminated encephalomyelitis, and cerebrovascular events [16]. Data on other symptoms in correlation with COVID-19 vaccination, commonly referred to as “post-COVID-19 vaccine syndrome” (PVS) [10], are scarce.
Here we report of 50 patients who presented to our neurological outpatient clinic due to neurological symptoms in temporal association to COVID-19 vaccination.
Methods
Fifty patients with neurological symptoms following COVID-19 vaccination presented to our outpatient clinic between October 2021 and July 2022. They were interviewed and examined by a neurologist. All patients had received at least one vaccination against SARS-CoV-2 and did not report of a concomitant disease explaining the symptoms. Patients with a confirmed SARS-CoV-2 infection before symptom onset were excluded. Diagnostic evaluation including blood tests was performed according to the guidelines of the German Society of Neurology. Patients filled out self-report questionnaires regarding fatigue (Fatigue Severity Scale, FSS) [11], depression (Beck Depression Inventory Version I, BDI) [2], anxiety (Generalized Anxiety Disorder Scale-7, GAD-7) [18], and risk of somatic symptom disorder (Somatic Symptom Disorder – B Criteria Scale, SSD-12) [21]. Health-related quality of life was assessed using the Short-Form-36 Health Survey (SF-36) [23] and compared with a norm sample (n = 2471) [8]. To screen for cognitive deficits, the Montreal Cognitive Assessment Scale (MoCA) [15] was performed. Neuropsychological examination covered test items regarding learning and memory, complex attention, executive functions, language, and perceptual motor function.
Electrophysiological examination was conducted in patients with paraesthesia and neuropathic pain. Skin biopsy was performed to assess intraepidermal nerve fibre density or pathological amyloid deposits in those patients whose electrophysiological assessment did not show pathological findings.
Results
The mean age of patients was 41 years (21–62 years) and the majority were female (60%). In 50% of patients, symptoms occurred after the first vaccination, in 26% after the second, and in 24% after the third (Table 1). Almost all patients (98%) developed symptoms after administration of an mRNA-based vaccine. Most patients (86%) received a homologous, mRNA-based vaccine regimen (82% BioNTech-Pfizer, 4% Moderna). Heterologous vaccine regimen were used in 14% of patients (10% mRNA-/mRNA-based, 4% vector-/mRNA-based). The median latency between receiving the vaccination and onset of symptoms was three days, ranging from one hour to 30 days. A SARS-CoV-2 infection occurred in 16 patients (32%) after their vaccination and onset of reported symptoms. All 16 had a mild course, but 10 (63%) reported an exacerbation of pre-existing symptoms.
The most frequent self-reported central nervous symptoms were fatigue (n = 23; 46%), cognitive impairment (n = 18; 36%), and headache (n = 15; 30%). Peripheral nervous symptoms included paraesthesia (n = 28; 56%), fasciculations (n = 11; 22%), myalgia (n = 11; 22%), and neuropathic pain (n = 11; 22%). Other symptoms included vertigo (n = 8; 16%) and tinnitus (n = 3; 6%). Overall, 32% presented with central symptoms, 40% with peripheral symptoms and 28% with both central and peripheral symptoms (Table 2). At the point of presentation in our outpatient clinic, none of the patients reported of ameliorated symptoms over time.
Of all 43 patients examined with MoCA, 40% showed pathologic scores (≤ 25/30 points). More comprehensive neuropsychological examination in 8 patients revealed deficits in attention (n = 6, 75%), executive function (n = 4, 50%) and memory (n = 3, 38%).
Brain MR imaging (n = 35) showed unremarkable findings except for unspecific gliosis (n = 3; 9%) and chronic mastoiditis (n = 1; 3%). Electroencephalography (n = 9) revealed no pathological findings. Electrophysiology (n = 27) detected single fasciculation potentials (n = 2; 7%) and bilateral carpal tunnel syndrome (n = 1; 4%). Skin biopsy was performed in four patients, which revealed normal intraepidermal nerve fibre density and no evidence of pathological amyloid deposits [12]. A routine serological examination including full blood count, liver enzymes, renal function, and electrolytes was carried out in all patients without detection of relevant pathological findings.
Substantial impairment due to fatigue quantified by FSS (≥ 4 points) was reported by 73% of patients (Table 3). BDI indicated moderate to severe depressive symptoms in 16% (≥ 20 points), and GAD-7 pointed to symptoms of moderate to severe anxiety in 25% (≥ 10 points) of patients. Evaluation by SSD-12 revealed an increased risk for somatic symptom disorder (≥ 23 points) in 75%. SF-36 scores were significantly worse (p < 0.05) in all domains in the post-vaccination group (physical functioning 59 vs 71%, physical pain 32 vs. 71%, role limitations due to physical health problems 14 vs. 53%, role limitations due to personal or emotional problems 52 vs. 66%, emotional well-being 54 vs. 70%, social functioning 38 vs. 79%, energy/fatigue 28 vs. 52%, general health perception 38 vs. 57%). No significant differences by gender were found in SF-36 results.
Discussion
We report of a comprehensive neurological assessment in 50 patients with persistent neurological symptoms in temporal relation to COVID-19 vaccination including clinical presentation, routine diagnostic, and self-report questionnaires. To date and in contrast to PCS, reliable data and a generally accepted definition of PVS are absent.
Our patients presented with central (cognitive impairment, fatigue, headache) and peripheral (paraesthesia, myalgia, fasciculations, neuropathic pain) neurological symptoms. Our data indicate that the spectrum of symptoms reported by PVS patients is similar to the spectrum we observe in PCS patients [3]. Notably, paraesthesia (56%) as the most common reported symptom in PVS was less frequently observed in PCS, while fatigue (46%) and cognitive impairment (36%) seem to occur more often in PCS [3]. As a limitation, our study did not include follow-up examinations. These are needed to assess the time course of symptom severity, modification and potential recovery of symptoms.
Self-report questionnaires showed an increased risk of somatic symptom disorder as assessed by SSD-12 in 75% of our 50 patients, moderate to severe anxiety measured by GAD-7 was present in 25%, and BDI indicated moderate to severe depressive symptoms in 16% of our patients. SF-36 showed low percentages in all scores, especially regarding physical health, underlining the severe impact on patient’s quality of live. Since standard diagnostic was widely normal, inclusion of psychiatric and psychosomatic assessment should be considered.
Our cohort mainly involved patients vaccinated with mRNA vaccines, which are predominantly administered in Germany. Available literature however accuses vector-based vaccines to be more frequently associated with (severe) neurological side effects [7, 20]. On the other hand, mRNA-COVID‐19 vaccine side‐effects have been attributed to a nocebo component in association with vaccine hesitancy [9].
Our data does not allow conclusions whether the symptoms occurred in temporal relationship to the COVID-19 vaccination, or whether the vaccine may be considered as a triggering factor or a cause of these symptoms. While there is limited data, several pathomechanisms have been suggested to explain the occurrence of diseases following SARS-CoV-2 vaccination, e.g., molecular mimicry, production of cross-reactive (anti-idiotype) autoantibodies, involvement of vaccine adjuvants, and persistence of spike protein [5, 14, 22].
Although neurological symptoms after COVID-19 vaccination have been reported, they appear to be rare considering the total number of vaccines administered. Current recommendations and guidelines favour COVID-19 vaccination as the risk of neurological complications during and after COVID-19 infection overweighs [13, 16]. Nevertheless, in-depth investigation of the individual patient, including diagnostic procedures beyond routine clinical care is needed, while research on pathophysiological mechanisms may provide further insights and might offer therapeutic options.
Data availability
The original contributions presented in the study are included in the article, further inquiries can be directed to the corresponding author.
References
Ayoubkhani D, Bermingham C, Pouwels KB, Glickman M, Nafilyan V, Zaccardi F, Khunti K, Alwan NA, Walker AS (2022) Trajectory of long covid symptoms after covid-19 vaccination: community based cohort study. BMJ 377:e069676
Beck AT, Ward CH, Mendelson M, Mock J, Erbaugh J (1961) An inventory for measuring depression. Arch Gen Psychiatry 4:561–571
Boesl F, Audebert H, Endres M, Prüss H, Franke C (2021) A neurological outpatient clinic for patients with post-COVID-19 syndrome—a report on the clinical presentations of the first 100 patients. Front Neurol 12:738405
Chen C, Haupert SR, Zimmermann L, Shi X, Fritsche LG, Mukherjee B (2022) Global prevalence of post-coronavirus disease 2019 (COVID-19) condition or long COVID: a meta-analysis and systematic review. J Infect Dis 226:1593–1607
Chen Y, Xu Z, Wang P, Li XM, Shuai ZW, Ye DQ, Pan HF (2022) New-onset autoimmune phenomena post-COVID-19 vaccination. Immunology 165:386–401
Francis AI, Ghany S, Gilkes T, Umakanthan S (2022) Review of COVID-19 vaccine subtypes, efficacy and geographical distributions. Postgrad Med J 98:389–394
Greinacher A, Thiele T, Warkentin TE, Weisser K, Kyrle PA, Eichinger S (2021) Thrombotic thrombocytopenia after ChAdOx1 nCov-19 vaccination. N Engl J Med 384:2092–2101
Hays RD, Sherbourne CD, Mazel RM (1993) The RAND 36-item health survey 1.0. Health Econ 2:217–227
Hoffman YSG, Levin Y, Palgi Y, Goodwin R, Ben-Ezra M, Greenblatt-Kimron L (2022) Vaccine hesitancy prospectively predicts nocebo side-effects following COVID-19 vaccination. Sci Rep 12:20018
Jara LJ, Vera-Lastra O, Mahroum N, Pineda C, Shoenfeld Y (2022) Autoimmune post-COVID vaccine syndromes: does the spectrum of autoimmune/inflammatory syndrome expand? Clin Rheumatol 41:1603–1609
Krupp LB, LaRocca NG, Muir-Nash J, Steinberg AD (1989) The fatigue severity scale: application to patients with multiple sclerosis and systemic lupus erythematosus. Arch Neurol 46:1121–1123
Lauria G, Bakkers M, Schmitz C, Lombardi R, Penza P, Devigili G, Smith AG, Hsieh ST, Mellgren SI, Umapathi T, Ziegler D, Faber CG, Merkies IS (2010) Intraepidermal nerve fiber density at the distal leg: a worldwide normative reference study. J Peripher Nerv Syst 15:202–207
Li X, Raventós B, Roel E, Pistillo A, Martinez-Hernandez E, Delmestri A, Reyes C, Strauss V, Prieto-Alhambra D, Burn E, Duarte-Salles T (2022) Association between covid-19 vaccination, SARS-CoV-2 infection, and risk of immune mediated neurological events: population based cohort and self-controlled case series analysis. BMJ 376:e068373
Murphy WJ, Longo DL (2022) A possible role for anti-idiotype antibodies in SARS-CoV-2 infection and vaccination. N Engl J Med 386:394–396
Nasreddine ZS, Phillips NA, Bédirian V, Charbonneau S, Whitehead V, Collin I, Cummings JL, Chertkow H (2005) The montreal cognitive assessment, MoCA: a brief screening tool for mild cognitive impairment. J Am Geriatr Soc 53:695–699
Patone M, Handunnetthi L, Saatci D, Pan J, Katikireddi SV, Razvi S, Hunt D, Mei XW, Dixon S, Zaccardi F, Khunti K, Watkinson P, Coupland CAC, Doidge J, Harrison DA, Ravanan R, Sheikh A, Robertson C, Hippisley-Cox J (2021) Neurological complications after first dose of COVID-19 vaccines and SARS-CoV-2 infection. Nat Med 27:2144–2153
Polack FP, Thomas SJ, Kitchin N, Absalon J, Gurtman A, Lockhart S, Perez JL, Pérez Marc G, Moreira ED, Zerbini C, Bailey R, Swanson KA, Roychoudhury S, Koury K, Li P, Kalina WV, Cooper D, Frenck RW Jr, Hammitt LL, Türeci Ö, Nell H, Schaefer A, Ünal S, Tresnan DB, Mather S, Dormitzer PR, Şahin U, Jansen KU, Gruber WC (2020) Safety and efficacy of the BNT162b2 mRNA Covid-19 vaccine. N Engl J Med 383:2603–2615
Rutter LA, Brown TA (2017) Psychometric properties of the generalized anxiety disorder scale-7 (GAD-7) in outpatients with anxiety and mood disorders. J Psychopathol Behav Assess 39:140–146
Taquet M, Geddes JR, Husain M, Luciano S, Harrison PJ (2021) 6-month neurological and psychiatric outcomes in 236 379 survivors of COVID-19: a retrospective cohort study using electronic health records. Lancet Psychiatry 8:416–427
Tondo G, Virgilio E, Naldi A, Bianchi A, Comi C (2022) Safety of COVID-19 Vaccines: spotlight on neurological complications. Life (Basel) 12:1338. https://doi.org/10.3390/life12091338
Toussaint A, Löwe B, Brähler E, Jordan P (2017) The somatic symptom disorder—B criteria scale (SSD-12): factorial structure, validity and population-based norms. J Psychosom Res 97:9–17
Trougakos IP, Terpos E, Alexopoulos H, Politou M, Paraskevis D, Scorilas A, Kastritis E, Andreakos E, Dimopoulos MA (2022) Adverse effects of COVID-19 mRNA vaccines: the spike hypothesis. Trends Mol Med 28:542–554
Ware JE Jr (2000) SF-36 health survey update. Spine (Phila Pa 1976) 25:3130–3139
Acknowledgements
We thank Prof. Dr. Sabine Gabrysch and Prof. Dr. Peter Berlit for their expertise and critical revision of the manuscript.
Funding
Open Access funding enabled and organized by Projekt DEAL. HP and CF have received funding by the German Research Foundation (DFG). Funding numbers are FR 4479/1-1 and PR 1274/8-1.
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AG and CF conceptualized the project, had a major role in data collection, analysed data and wrote the manuscript. VR collected clinical data, analysed data and wrote the manuscript. FB, HFP and MS collected clinical data. JR analysed data. HP, ME, HA and KH revised and reviewed the data and the manuscript. All authors critically revised the manuscript for important intellectual content and approved the final draft.
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All other authors have no competing interests to declare that are relevant to the content of this article.
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The Institutional Review Board of the Charité approved the study (Institutional Review Board number EA2/102/22). Informed consent was waived by the Institutional Review Board due to the observational design of the study and in accordance with laws and regulations in the Federal State of Berlin that allows the scientific use of data collected within routine care documentation and quality monitoring (§25 Berliner Krankenhausgesetz).
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Gerhard, A., Raeder, V., Pernice, H.F. et al. Neurological symptoms after COVID-19 vaccination: a report on the clinical presentation of the first 50 patients. J Neurol 270, 4673–4677 (2023). https://doi.org/10.1007/s00415-023-11895-9
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DOI: https://doi.org/10.1007/s00415-023-11895-9