Abstract
Objectives
To describe the course of symptoms reported by patients with symptoms attributed to Lyme borreliosis (LB) without being subsequently diagnosed with LB.
Methods
We performed a prospective cohort study with patients presenting at the outpatient clinic of two clinical LB centres. The primary outcome was the prevalence of persistent symptoms, which were defined as clinically relevant fatigue (CIS, subscale fatigue), pain (SF-36, subscale bodily pain), and cognitive impairment (CFQ) for ≥ 6 months and onset < 6 months over the first year of follow-up. Outcomes were compared with a longitudinal cohort of confirmed LB patients and a general population cohort. Prevalences were standardised to the distribution of pre-defined confounders in the confirmed LB cohort.
Results
Participants (n = 123) reported mostly fatigue, arthralgia, myalgia, and paraesthesia as symptoms. The primary outcome could be determined for 74.8% (92/123) of participants. The standardised prevalence of persistent symptoms in our participants was 58.6%, which was higher than in patients with confirmed LB at baseline (27.2%, p < 0.0001) and the population cohort (21.2%, p < 0.0001). Participants reported overall improvement of fatigue (p < 0.0001) and pain (p < 0.0001) but not for cognitive impairment (p = 0.062) during the follow-up, though symptom severity at the end of follow-up remained greater compared to confirmed LB patients (various comparisons p < 0.05).
Conclusion
Patients with symptoms attributed to LB who present at clinical LB centres without physician-confirmed LB more often report persistent symptoms and report more severe symptoms compared to confirmed LB patients and a population cohort.
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Introduction
Even though Lyme borreliosis (LB, also known as Lyme disease/LD) generally has a good prognosis, persistent symptoms are reported by a substantial subset of patients [1]. Persistent symptoms after treatment for LB may be persistent objective signs, such as persistent atrophy of the skin associated with acrodermatitis chronica atrophicans (ACA) or neurological damage after Lyme neuroborreliosis, or may be associated with an ongoing aberrant immune response, as has been described for antibiotic-refractory Lyme arthritis [2]. In rare cases, signs may be indicative of a persistent infection with Borrelia spirochetes [3]. There is also a group of patients who have more general persistent symptoms (e.g., myalgia, arthralgia, and fatigue) following antibiotic treatment and resolution of the original signs of the LB manifestation. These symptoms are generally classified as Post-Treatment Lyme Borreliosis Syndrome (PTLBS, also known as PTLDS), a suspected post-infectious syndrome of which the exact aetiology has not been ascertained [4]. Yet, others suffer from chronic symptoms that lack a clear explanation by current medical standards, but that are attributed to an (unnoticed) LB episode or a tick bite, despite absent LB-specific symptoms or laboratory confirmation. Regardless of the exact aetiology, these symptoms can seriously affect quality of life [5]. Indeed, PTLBS and chronic symptoms attributed to LB are likely to have the greatest impact on disability-adjusted life years of all LB-related disease categories [5].
A large prospective study in the Netherlands recently showed that the prevalence of various persistent symptoms was 6% higher in confirmed LB patients than in the general population [1]. While there is a growing body of knowledge about persistent symptoms after a confirmed LB diagnosis [1, 6], little is known about the development of symptoms and quality of life in patients that present at clinical LB centres with long-lasting symptoms that are attributed to an unconfirmed LB episode. Studies from Europe [7,8,9,10,11,12,13,14] and the United States [15,16,17] suggest that LB diagnoses can often not be confirmed in these cases, despite extensive diagnostic testing. The array of persistent symptoms in these patients is sometimes explained by LB, sometimes by alternative diagnoses, and in many cases not explained at all [7,8,9,10,11,12,13,14,15,16,17]. As far as we are aware, no studies have systematically assessed the evolution of these symptoms over time through validated questionnaires in a cohort of patients presenting at a clinical LB centre without being subsequently diagnosed with LB. It is therefore currently unclear how such patients fare in the months after their consultation.
For these reasons, we describe a prospectively included cohort of patients from two clinical LB centres in the Netherlands, performing various clinical measurements, and a follow-up of 1 year using validated questionnaires.
Methods
Study design
We conducted a prospective observational cohort study, as previously described [18]. All patients who had a first consultation for clinical care at the outpatient clinic of the LB expertise centres of the Radboud University Medical Centre (Nijmegen, the Netherlands) or Amsterdam University Medical Centre (Amsterdam, the Netherlands) between March 2019 and March 2020 were invited to participate in this study in selected periods of time. Exclusion criteria were the inability to give informed consent or insufficient proficiency in the Dutch language.
Clinical and laboratory measurements
Clinical measurements were performed at every patient visit and encompassed patients’ signs and symptoms, characteristics of any current or past LB manifestation, results of previous diagnostic tests for LB, prior antibiotic treatment, concomitant medication, and relevant past medical history. To rule out other diagnoses, patients underwent standardised workup by an internal medicine specialist, and by additional medical specialties if needed. A thorough physical examination, including comprehensive neurological assessments, was conducted.
All patients underwent serological testing for Borrelia. If necessary, we performed an analysis of cerebrospinal fluid, analysis for Lyme neuroborreliosis (LNB), skin biopsies for cutaneous manifestations, or arthrocentesis to assess Lyme arthritis. Exploratory laboratory tests comprised at least a complete blood count; assessment of thyroid, renal, and hepatic function; and evaluation of inflammatory markers. Diagnostic imaging was employed as deemed necessary. Additional tests, such as the exploration of other tick-borne diseases or autoimmune disorders, were conducted if clinically relevant.
For investigational purposes, a baseline sample was obtained for serological and cellular tests from all patients (more details are provided in the supplementary materials).
Questionnaires
Study participants were asked to fill out an online questionnaire at baseline, and were invited to fill out an additional questionnaire every 3 months thereafter up to 1 year (i.e., at 3, 6, 9, and 12 months). Online questionnaires were sent via the Tekenradar.nl platform [19]. Clinical outcomes throughout this year were determined through the Checklist Individual Strength (CIS, subscale fatigue) [20], the RAND SF-36 Health Status Inventory (SF-36, subscale bodily pain) [21], and the Cognitive Failure Questionnaire (CFQ) [22]. We also systematically screened for concomitant diagnoses using a list of diagnoses adapted from the TiC-P questionnaire [23]. Participants were reminded by phone or email when they did not fill out a questionnaire in time. Questionnaire data from this study’s participants were compared to two cohorts: patients with confirmed LB from the LymeProspect study (n = 1084) and persons from the general population (n = 1942) [1]. More details are provided in the supplementary materials.
Classification of patients
Upon completion of the study, patients were classified by FRvdS and MEB (MDs specializing in LB) independently using all available information from their outpatient visits. Disagreements in classification were referred to an expert panel (FRvdS/MEB/BJK/JWH), which then came to a consensus classification. If another diagnosis was identified, a patient was treated appropriately or was referred to appropriate medical care. We classified patients into one of four groups, namely, as having definite or probable LB, as having PTLBS or residual damage after Borrelia infection, as having another apparent diagnosis, or not having a known diagnosis to explain the patient’s symptoms. Patients in the first two groups were classified using established guidelines of the European Society of Clinical Microbiology and Infectious Diseases [24].
Statistical analyses
Questionnaire data were analysed in a similar fashion to those from the LymeProspect study [1, 19] and as described in the supplementary materials. Briefly, we compared the prevalence of persistent symptoms (i.e., for the symptoms of fatigue, cognitive impairment, and pain, a clinically relevant score on ≥ 1 symptom for ≥ 6 months of the year of follow-up) to the confirmed LB and population cohorts from LymeProspect [1]. Missing questionnaire data were substituted; the primary outcome was only determined when questionnaire data from ≥ 2 timepoints were available. Both overall and point prevalences were standardised using the pre-defined confounders’ sex, age, educational level, and self-reported comorbidity. The development of symptom severity over time was investigated using a linear mixed-effects model. Possible predictors for persistent symptoms were assessed with univariate logistic regression analysis. Due to the limited number of events, we then assessed a multivariable model with a backward selection method using at most five predictors, selecting those with the lowest p-values.
For other analyses, we used Fisher’s Exact Test or descriptive statistics. Non-questionnaire data were not imputed. Analyses were performed with R (PBC, version 4.3.2, Boston, MA, USA) and SPSS (IBM Corp, Version 28.0, Armonk, NY, USA). Figures were created in GraphPad Prism (GraphPad Software, Version 9.0, Boston, MA, USA).
Ethics statement
This study was approved by the Medical Ethics Committee of Amsterdam UMC (NL63961.018.18) and conducted according to the principles of the Declaration of Helsinki and applicable Dutch law. Written informed consent was obtained from all study participants before inclusion.
Patient involvement
Patient representatives were involved in the study design (e.g., the selection of cellular tests) and have commented on the final version of this manuscript. Patient representatives were not involved as study participants.
Results
Inclusion
We included 128 patients presenting at the LB outpatient clinic (Figure S1). As patients with definite/probable LB were outside the scope of this study, participants classified as such (n = 5) were excluded, leaving an analytic population of 123 participants. Despite frequent reminders, 31 participants filled out insufficient follow-up questionnaires to determine the prevalence of clinically significant symptoms for ≥ 6 months. Thus, the primary outcome could be determined for 92 participants. Questionnaire non-response was not correlated to LB classification (all comparisons p > 0.05).
Baseline characteristics and classification
General characteristics and classification of all participants are displayed in Table 1 and S1. Patients were mostly referred by general practitioners (96/123, 78.0%) and, to a lesser extent, by medical specialists (25/123, 20.3%) or others (2/123, 1.6%). The majority of patients had symptoms for 2 years or more; fatigue was the most common symptom. Diagnoses which are generally considered contested illnesses [25] such as fibromyalgia (2/123, 1.6%), irritable bowel syndrome (4/123, 3.3%), and chronic fatigue syndrome (0/123, 0%) were infrequently reported in past medical histories.
The majority of patients had received a positive serological test result for LB at some point in the past (77/123, 62.6%). There were 22 patients (17.9%) who had previously sought out a non-recommended diagnostic test for LB, such as cellular tests (n = 8), live-blood analysis (n = 2), CD57 + measurement (n = 2), bioresonance (n = 4), and VEGA tests (n = 3). Table S2 shows the reactivity of serological and cellular tests for this cohort of patients at baseline. Cellular tests had more missing data due to invalid test results or test samples that were not processed because of shipment delays [26].
Twenty-six patients (21.1%) were classified as having PTLBS or residual damage. Another 26 patients (21.1%) were classified as having another diagnosis (e.g., multiple sclerosis, Guillain-Barré Syndrome, type 2 diabetes, HLA-B27-associated spondyloarthritis, or erythema annulare). No diagnosis was made for the remaining 71 patients (57.7%) (Table 1).
Follow-up during first year
Of the 92 participants for whom the primary outcome could be assessed, 66 (71.7%) had persistent symptoms as defined above. This crude prevalence was standardised as described and was then compared to patients with a previous episode of confirmed LB and the population cohort [1]. The standardised prevalence of persistent symptoms in the present study was 58.6% (95%CI, 48.3–68.9), which compared unfavourably to patients with previous confirmed LB (27.2%, p < 0.0001) and to the population cohort (21.2%, p < 0.0001) (Fig. 1). Fatigue was the most prevalent symptom in all groups, followed by cognitive impairment and pain. As shown in Fig. 2A–C and Table S3, the baseline severities of all three symptoms were significantly greater in the study group than in the EM and population cohorts (all comparisons at t = 0 m, p < 0.0001). Compared to patients with disseminated LB, the study participants had a significantly higher symptom severity at baseline for fatigue (p = 0.0036) and cognitive impairment (p < 0.0001) but not for pain (p = 0.92).
Study subjects showed improvement over time when using the population controls as a reference (Fig. 2A–C and Table S3), as had been previously described for the confirmed LB cohorts [1, 27]. The improvement was significant for fatigue (p < 0.0001) but not for cognitive impairment (p = 0.062). For pain, the scores first improved significantly, but this improvement stagnated towards the end of follow-up (Fig. 2C and Table S3). The observed improvements over time in the study group were comparable with the disseminated LB patients from the LB cohort for fatigue and cognitive impairment, but not for pain, because of the stagnation in the improvement of pain in the study group towards the end of follow-up (Fig. 2A–C and Table S3). In spite of these improvements, symptom severity at 12 months was greater in the study subjects than in confirmed LB (Table S3).
The improvements in symptom severity translated into a comparable decrease in the standardised prevalence of clinically relevant symptoms over time (Fig. 3A–D). Those patients who were classified as having persistent symptoms had a consistently high symptom severity throughout the follow-up period (Figure S2A–C). There were no apparent differences between the classification-based subgroups in terms of the prevalence of clinically relevant symptoms (Figure S3A–D) or symptom severity (Figure S4A–C).
Factors related to persistent symptoms
Possible predictors for persistent symptoms were first assessed using univariate logistic regression analyses (Table S4). In the subsequent multivariable model, only lower/vocational education (OR = 3.415; 95%CI, 1.180–9.877; p = 0.023) and duration of symptoms > 2 years (OR = 3.155; 95%CI, 1.131–8.800; p = 0.028) remained significant predictors for persistent symptoms.
Discussion
Our results suggest that symptoms attributed to LB are varied and often clinically relevant. The most common symptoms (fatigue, arthralgia, myalgia, paraesthesia, and neurocognitive symptoms) are frequently reported by patients as being LB-associated. This has previously been described in reports from clinical LB centres [1, 7,8,9,10,11,12,13,14,15,16,17] and in qualitative studies on chronic symptoms attributed to LB [28, 29]. These symptoms are also prevalent in the general population [1, 30, 31]. It is therefore difficult to confirm a relationship between symptoms and a current or past LB episode, in the absence of any specific symptoms or laboratory indication of an active Borrelia infection. However, irrespective of their precise aetiology, these symptoms have a substantial impact on the quality of life. The crude observed prevalence of clinically relevant symptoms for ≥ 6 months in the first year of follow-up in our cohort was 71.7%. In order to compare the rate of persistent symptoms with that of confirmed LB patients and the population cohort, we standardised for pre-defined possible confounders such as age, sex, comorbidity, and education level with patients with previously confirmed LB as a reference. This analysis showed that our participants compare unfavourably to patients with a confirmed LB episode and the general population.
Analyses of point prevalences and mean scores at each time point suggest that there is some improvement in the first year after inclusion for both the patients from the current study and those with confirmed LB. Similar improvement was also observed in a comparable cohort of patients [32]. Any improvement in symptoms is most often observed in the first 3 to 6 months after the first consultation and stagnates thereafter. This might partly be explained by regression towards the mean rather than by any interventions [33], i.e., it could be due to the natural course of these symptoms, as patients may be referred to a clinical LB centre when their symptoms are at a peak. In spite of this mean improvement, symptom severity LB at the end of the 12-month follow-up period remained significantly higher in the patients who participated in the current study than in those with confirmed LB.
No obvious predictors for a favourable outcome related to patient management (e.g., antibiotic treatment) were identified in our cohort, with the caveat that our study was not designed to assess the efficacy of any interventions and we had only a limited number of events with which to assess potential predictors. Our exploratory results do suggest that patients with a longer duration of symptoms before inclusion were less likely to recover in the first year of follow-up. This observation is in line with previous research on Medically Unexplained Symptoms (MUS, also known as Persistent Physical Symptoms or PPS) [34, 35] and previous studies on patients from LB expertise centres [32, 36].
Our results also show that there is currently no place for cellular tests in the diagnostic repertoire of LB expertise centres. While frequently sought out by patients with chronic symptoms that are attributed to LB, we found that such tests are frequently positive in patients who do not have any LB-related classification and are reactive in these patients at a level similar to healthy controls [37].
In line with previous studies [7,8,9,10,11,12,13,14,15,16,17, 32, 36], we also found that only a handful of patients at our LB expertise centres had a confirmed LB diagnosis to explain their symptoms. About 20% had symptoms that met the definitions of PTLBS or residual symptoms after an LB manifestation. Another 20% had another diagnosis that could explain the symptoms. These patients were referred for appropriate medical care for their diagnosis. This leaves almost 60% of patients for whom no diagnosis was apparent. For some of these patients, their symptoms may be explained by an undiagnosed other condition; for others, they may be entirely functional in nature, and for yet others, they could hypothetically be related to a (past) Borrelia infection through some unidentified pathophysiological mechanism. Interestingly, our patients’ heterogeneous symptoms and disease burden frequently permit a differential diagnosis of fibromyalgia, chronic fatigue syndrome, or a general post-infectious syndrome [38,39,40], sometimes all at the same time. We did not systematically assess whether patients met the criteria for these diagnoses because this was outside the scope of the current study. We also feel compelled to point out that these are all syndrome diagnoses, based on clinical presentation but without a known pathophysiological mechanism. These labels frequently overlap; asthenia, for example, can be a symptom of all of the aforementioned diagnoses. A recent paper has suggested the introduction of the term ‘Functional Somatic Disorders’ as an umbrella term for similar symptoms without a known cause [41]. The authors highlight its potential for research and treatment based on shared aetiological mechanisms between syndromes that are currently studied separately and its potential to resolve the historic ‘split’ between a purely organic and purely mental cause of illness [41].
What is abundantly clear is that patients similar to the ones in the current study have the highest disease burden of all patients who are assessed for a potential LB diagnosis, as has been consistently shown in the current and previous research [1, 5, 32, 36]. What many of these patients share is that they explain their illness either entirely or in part through the lens of LB, irrespective of whether current medical science supports that attribution. Healthcare providers should connect with this explanatory model and create common ground with their patients [28]. Thus, they are better suited to provide effective care, through open and frank conversations about the benefits and pitfalls of further LB-related diagnostics and treatments, all with the goal of preventing iatrogenic harm and improving their patients’ health. We encourage continued research on specific treatments for this group, either based on factors specific for a (past) Borrelia infection or based on shared aetiological mechanisms for functional disorders. Until then, we will endeavour to provide appropriate supportive care.
Our study may have several limitations. Due to the COVID-19 pandemic, follow-up visits and samples were not available for a number of patients, even though 75.8% of participants did fill out sufficient questionnaires to assess the primary outcome. Our study also does not answer the question of how our participants fare after the first year. We would argue that additional follow-up studies—including those assessing the effect of interventions—on patients with long-lasting LB-associated symptoms are needed. It is difficult to assess with certainty whether we have a representative spectrum of patients, as patients with the most severe symptoms are more likely to enrol in these kinds of studies, which may lead to an underrepresentation of patients who fare better. On a final note, we point out that we performed a thorough clinical work-up to exclude the most likely differential diagnosis, as we described above. However, we cannot guarantee with absolute certainty that all patients without a known diagnosis did not have an organic cause of their illness.
In summary, our results show that the large majority of patients at LB referral clinics suffer from clinically significant symptoms for ≥ 6 months after their consultation, which are frequently not explained by any recognized LB-related disease entity. Our study highlights the suffering of these patients and the need for improved strategies for diagnosis and treatment of their symptoms.
Data availability
The datasets generated and/or analysed during the current study are not publicly available but are available from the corresponding author upon reasonable request.
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Acknowledgements
The authors acknowledge the patient representatives associated with this project, Els Duba and Kees Niks, together with Gert van Dijk and Koen van Kempen. Their efforts in setting up this study (e.g., design and choice of the tests to be studied) and their perspectives during its execution and analysis are greatly appreciated. The authors additionally acknowledge the following colleagues for their valuable assistance in setting up and performing this study: Ingrid Friesema, Ph.D. (RIVM); Jasmin Ersöz, BASc; Hans Knoop, Ph.D.; Dieuwertje Hoornstra, MD; Bregtje Lemkes, MD, Ph.D.; Amber Vrijlandt, MD; V. Spoorenberg, MD, Ph.D. (Amsterdam UMC); Michelle Brouwer, MSc; Fidel Vos, MD, Ph.D.; Mirjam Tromp, MSc, Ph.D.; and Arjan van Laarhoven, MD, Ph.D. (Radboudumc).
Funding
This study was funded by the Netherlands Organization for Health Research and Development (ZonMw, project number 522050001) and co-funded by the Ministry of Health, Welfare & Sports of the Netherlands and the charitable contributions raised by Rood voor Altijd/Minke Verstrepen, donated through the AMC Foundation (amcfoundation.nl). The cellular tests under study were supplied by the respective manufacturers either free of charge or at a reduced price. The C6-ELISA was supplied by Oxford Immunotec free of charge as well. Neither the funding organizations nor the participating commercial partners had any role in the design of the study or the analysis and interpretation of (un or deblinded) data. JWH’s work on a related project was supported by a grant from the European Union through the European Regional Development Fund and the Interreg North Sea Region Programme 2014–2020 as part of the NorthTick project (reference number J-No: 38–2-7–19).
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Conceptualization: F.R. van de Schoor, M.E. Baarsma, C.C. van den Wijngaard, L.A.B. Joosten, J.W. Hovius, and B.J. Kullberg; methodology F.R. van de Schoor, M.E. Baarsma, and C.C. van den Wijngaard; software: F.R. van de Schoor, M.E. Baarsma, and C.C. van den Wijngaard; formal analysis: F.R. van de Schoor, M.E. Baarsma, and C.C. van den Wijngaard; investigation: F.R. van de Schoor, M.E. Baarsma, Albert Wong, and C.C. van den Wijngaard; resources: S.A. Gauw, J. Ursinus, H.D. Vrijmoeth, H.J.M. ter Hofstede, Anna D. Tulen, M.G. Harms, and A. Wong; writing—original draft: F.R. van de Schoor and M.E. Baarsma; writing—review and editing: F.R. van de Schoor, M.E. Baarsma, S.A. Gauw, J. Ursinus, H.D. Vrijmoeth, H.J.M. ter Hofstede, Anna D. Tulen, M.G. Harms, A. Wong, C.C. van den Wijngaard, L.A.B. Joosten, J.W. Hovius, and B.J. Kullberg; supervision: C.C. van den Wijngaard, L.A.B. Joosten, J.W. Hovius, and B.J. Kullberg; funding acquisition: C.C. van den Wijngaard, L.A.B. Joosten, J.W. Hovius, and B.J. Kullberg.
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Conflict of interest
None of the authors have received any financial compensation from any of the companies participating in the study. MEB and JWH collaborate with Abbott, Bio-Rad Laboratories, and ZEUS Scientific. Moderna and Pfizer on unrelated projects on LB. FvdS and LABJ collaborate with Hycult Biotech on developing novel diagnostic tests for LB. BJK and LABJ are co-inventors of the Spirofind, an experimental in-house assay for LB, which is owned by Radboudumc and was previously licensed for development to Boulder Diagnostics (Boulder, CO, USA) and subsequently Oxford Immunotec (Oxford, UK) until 2018. The other authors report no potential conflicts of interest.
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Trial registration and protocol.
The study is registered under NL7732 (Netherlands Trial Register, trialregister.nl). A more detailed protocol can be found in Van de Schoor and colleagues (2019) (18).
F.R. van de Schoor and M.E. Baarsma are co-first authors.
C.C. van den Wijngaard, L.A.B. Joosten, J.W. Hovius and B.J. Kullberg are co-senior authors.
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van de Schoor, F.R., Baarsma, M.E., Gauw, S.A. et al. Evaluation and 1-year follow-up of patients presenting at a Lyme borreliosis expertise centre: a prospective cohort study with validated questionnaires. Eur J Clin Microbiol Infect Dis 43, 937–946 (2024). https://doi.org/10.1007/s10096-024-04770-6
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DOI: https://doi.org/10.1007/s10096-024-04770-6