Objectives
The primary objective of this study is to evaluate diagnostic accuracy measures of tear biomarkers to discriminate participants with and without neurodegeneration as determined by hippocampal atrophy. The secondary objective is to determine the level of agreement between Aβ and tau protein levels in tear fluid, blood and CSF or PET. Thirdly, we aim to investigate whether the combination of retinal biomarker with tear biomarkers can aid in determining the presence of neurodegeneration as determined by hippocampal atrophy. The final objective is to analyze how biomarkers in tear fluid alter over the course of the follow-up period.
Study design and setting
This study is an observational longitudinal multicenter study that will be performed at the Maastricht University Medical Center (Maastricht UMC+) and the Amsterdam University Medical Center (Amsterdam UMC) in the Netherlands.
At Maastricht UMC+, people with cognitive complaints who are referred to the memory clinic are asked to participate in ongoing research. If they agreed on being contacted for clinical studies and have the diagnosis SCD, MCI or dementia due to AD they are asked to participate in the present TearAD study. In addition, community-based cognitively healthy controls were recruited through advertisement as part of the GlyM study and later asked to participate in the TearAD study (NL72269.068.19, Glymphatic dysfunction in cognitive impairment: a memory clinic study). Overlapping study procedures will not be repeated, but data will be shared between both studies for which permission granted through the study protocol and informed consent.
At Amsterdam UMC, people with cognitive complaints and a diagnosis of SCD, MCI or AD dementia will be included in the MHIRA study (NL70896.029.19, The diagnostic value of metabolic hyperspectral imaging of the retina in Alzheimer’s disease). These participants originate from the memory clinic based Amsterdam Dementia Cohort (19, 20). Cognitively healthy controls will be recruited from the Innovative Medicine Initiative European Medical Information Framework for AD (EMIF-AD) PreclinAD study (21). Agreements on sharing material and data are covered by a material and data transfer agreement between both parties.
Participants for the TearAD study are included from different cohorts with similar study procedures, but different primary endpoints and available infrastructure. For instance, amyloid PET imaging is available in Amsterdam UMC but not in Maastricht UMC+. For this reason, some of our secondary outcome measures will be analyzed in a sub-cohort of the total study population.
Study population
Based on their clinical diagnosis we aim to include 50 patients with SCD, 50 patients with MCI and 50 patients with AD dementia. Additionally, 50 cognitively healthy controls will be included. Eventually, the total study population (n = 200) will consist of two groups of 100 participants with signs of neurodegeneration and 100 participants without signs of neurodegeneration. The presence of neurodegeneration will be defined as presence of medial temporal lobe atrophy (MTA) (measured by MRI using visual rating scores of the medial temporal lobes using the Scheltens Visual Rating Method abnormal cutoff of ≥ 2 (22)). The inclusion criteria are described in Table 1 and 2.
The clinical diagnosis of dementia will be made based on the Diagnostic and Statistical Manual of Mental Disorders-5 (DSM-5) criteria for major neurocognitive disorders in Maastricht UMC + and the Amsterdam UMC the clinical National Institute on Ageing-Alzheimer’s Association (NIA-AA) criteria (4, 6, 23). Patients with dementia have significant cognitive decline and this results in interference with independence in daily functioning. The clinical diagnosis of MCI will be made according to the clinical NIA-AA criteria; MCI patients have impaired cognitive functioning but preserved functioning in daily living (5). Patients will be classified as SCD when they present to the memory clinic with cognitive complaint initiation, but no impairment in cognitive test performances and activities of daily living can be objectified (7). Participants with absence of cognitive complaints or treatment and who did not seek help for cognitive complaints in the past will be grouped as cognitively healthy controls.
Table 1
Inclusion criteria for all participants
Inclusion criteria for all participants |
Available CSF, PET, CT or MRI data to evaluate the presence/absence of neurodegeneration (preferably within 1 year of inclusion in this study) |
Absence of ocular conditions that could influence tear biochemical parameters (including eye infection, eye inflammation, eye surgery within the last 28 days or other acute eye conditions) |
Absence of neurological or systemic chronic conditions known to interfere with retinal thickness (e.g. glaucoma, diabetes mellitus) |
Absence of ocular conditions interfering with OCT quality/retinal thickness: e.g. severe cataract, age-related macular degeneration, and glaucoma |
Written informed consent obtained and documented |
Age > 50 years |
No indications that follow-up (up to 24 months) is not possible |
Table 2
Additional inclusion criteria
Additional inclusion criteria for cognitively healthy controls only |
MMSE score 26–30 at baseline |
Absence of cognitive complaints or treatment and did not seek help for cognitive complaints in the present moment or the past |
Additional inclusion criteria for patients only (SCD/MCI/AD Dementia) |
Capable of giving informed consent (MMSE score > 17/30) |
Outcome measures
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Relation between tau protein levels in tear fluid and neurodegeneration determined by hippocampal atrophy.
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The level of agreement between Aβ biomarkers in tear fluid and Aβ positivity as determined by PET or CSF.
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The level of agreement between Aβ and tau protein levels in tear fluid, blood and CSF.
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The combination of retinal biomarkers and tear biomarkers as a predictor for neurodegeneration determined by hippocampal atrophy.
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Mean change in tear biomarkers between baseline, 12 months and 24 months.
Study assessments
Table 3 presents an overview and timing of the assessments. Follow-up visits are scheduled after 12 and 24 months.
Table 3
Overview and timing of study assessments
Assessment | Baseline | 12 months | 24 months |
In-/exclusion criteria | X | | |
Informed consent | X | | |
Medical history and medication | X | X | X |
Routine neuropsychological testsa | X | X | X |
CT or MRI scanb | X | | |
PET scan or CSF sampling c | X | | |
Blood sampling d | X | | X |
Routine ophthalmic examinatione | X | X | X |
Tear samplingf | X | X | X |
Fundus imagingg | X | X | X |
OCT imagingh | X | X | X |
a Neuropsychological assessment will be performed according to local routine protocol of memory clinic, as described elsewhere (19). Covering the cognitive domains of global cognition, memory, attention, executive functioning and language.
b Images will be acquired with a 3 Tesla MRI-scan and 7 Tesla MRI for a small sub-cohort. The Scheltens MTA visual rating scale will be used to score each hemisphere (range 0–4) (22). A summed score of both hemispheres will be defined abnormal with a cutoff of ≥ 2 (24).
c CSF fluid will be available from a subset of participants and will be analyzed for Aβ 42, t-tau and p-tau-181 using an immunoassay, local cut-off values for each clinic will be used (20, 25). A PET scan will also be available from a subset of participants, from which standard uptake value ratio (SUVr) images will be generated and visually read by an experienced nuclear physician. Images will be classified as positive or negative rating for Aβ according to criteria defined by the manufacturer (GE Healthcare) (26).
d Participants will undergo venipuncture for blood sampling and subsequent analysis of Aβ42/40, t-tau and p-tau AD biomarker levels using immunoassays.
e The presence of potential ocular pathologies or unexpected findings will be assessed during the standard ophthalmic examination during which we will analyze visual acuity (using the Early Treatment Diabetic Retinopathy Study (ETDRS) chart (27)), (auto-) refraction, intraocular pressure (using non-contact tonometry), axial length (IOLMaster™, Carl Zeiss Meditec AG, Jena, Germany) and general eye health (using slit lamp biomicroscopy and funduscopy).
f Tear sampling will be performed by absorption of tear fluid in a paper Schirmer’s strip (TEAR strips, Contacare Ophthalmics and diagnostics, Gujarat, India). The Schirmer’s strip will be placed in de lower eyelid of both eyes. After 5 minutes, the Schirmer’s strip will be gently removed using tweezers and stored at -80°C. Tear fluid will be extracted from Schirmer’s strips (28), and analyzed with targeted immuno-assays for Aβ 42/40, t-tau and p-tau.
g Fundus imaging captures images of the retina, optic nerve head, macula, retinal blood vessels, choroid, and the vitreous. We will use a the Clarus 700 fundus camera (Carl Zeiss Meditec AG, Jena, Germany) to capture images of the central retina. Color and autofluorescence ultra-wide field images of 200 degrees of the peripheral retina will be acquired using the Californiarg fundus camera (Optos, Dunfermline, United Kingdom). Additionally, hyperspectral retinal imaging will be performed using the hyperspectral camera Optina-4C (Optina Diagnostics, Quebec, Canada). Optina-4C is a non-CE marked mydriatic camera combined with a tunable filter, thereby only permitting selected wavelengths (energy spectrum between 450 and 900 nm) (29). In a subset of participants the macular pigment optical density will be determined in the right eye with the macular pigment reflectometer (30).
h Optical coherence tomography (OCT) imaging will generate cross sectional retinal images from the (papillary) retinal nerve fiber layer thickness (RNFL) along with other parameters will be extracted. For each eye the following scans will be made, (i) fast enhanced depth imaging retina macula scan, (ii) dense macular scans, (iii) axonal ring scan around the optic nerve head (ONH), and (iv) an ONH scan using spectral domain OCT. Additionally, an OCT angiography (OCTA) will be done in a subset of the study population (Heidelberg Engineering, Heidelberg, Germany).
Sample size
Sample size is based on our main outcome measure, which is estimating the diagnostic accuracy of biomarkers in tear fluid to discriminate between participants with and without neurodegeneration as determined by hippocampal atrophy. The calculation of sample size is based on the width of the 95% confidence intervals of sensitivity and specificity, as well as recent pilot data from our group (16). To obtain a margin of error of maximally 10% for sensitivity as well as specificity, 97 individuals with neurodegeneration and 97 without neurodegeneration will be required. This calculation is performed using an online calculator (http://statulator.com/SampleSize/ss1P.html), where an expected proportion (sensitivity and specificity) of 50% was used as this yields the largest sample size. The diagnostic accuracy will be based on baseline parameters. To correct for potential dropout during follow-up, we increased the total number of participants to 200. Within these groups, participants will be divided into subgroups based on the clinical diagnosis. We aim to include a 50 participants per clinical diagnosis in order to obtain sufficient data to study secondary outcomes.
Statistical analysis
All data will be stored in the online database Castor EDC with restricted access (31). The final data will be exported to IBM SPSS Statistics (IBM, Armonk, NY, USA) for statistical analysis. Data from participants with missing data or data from withdrawn participants will be included in the statistical analysis. Threshold of statistical significance will be assumed equal to p < 0.05.
Receiver operating characteristic (ROC) analyses will be performed to estimate the capability of tear biomarkers to differentiate between individuals with neurodegeneration and those without neurodegeneration as determined by hippocampal atrophy. The area under the curve and diagnostic accuracy measures such as sensitivity, specificity, predictive values and likelihood rations (with the corresponding 95% confidence intervals) will be calculated to assess the discriminative capability of a biomarker. To study the correlation of biomarker levels in tears, blood, CSF and PET will be performed using Pearson or Spearman correlation. Each biomarker will be separately compared across three body fluids, and the Aβ region of interest SUVr from PET. Based on our pilot results, we expect negative correlations between tears and CSF (similar to blood and CSF) (17). Diagnostic accuracy will also be determined for the combination of tear and retinal biomarkers. Linear scores will be derived from the total area or partial area under the ROC curve. Lastly, we will study the mean change of tear biomarkers over time and how this correlates with disease progression (based on neuropsychological evaluation, imaging and fluid biomarkers) with the use of (generalized) linear mixed models or repeated measures ANOVA. Post hoc analysis will reveal which groups and time points differ significantly from each other.
Data management and monitoring
The personal data from participants will be handled confidentially, according to Good Clinical Practice guidelines (GCP). Medical history and associated data will be extracted from the electronic patient record. Data will be pseudonymized and stored in a certified online case report form tool (Castor EDC). Personal data that connects the patient to the participant number will be stored by the principal investigator for 15 year according to national guidelines. The study is monitored by the Clinical Trial Center Maastricht (CTCM) in order to assure patient rights and the accuracy of the reported data.