Introducing the DizzyQuest: an app-based diary for vestibular disorders

Patients with various vestibular disorders were recruited at the vestibular department of Maastricht University Medical Center, Apeldoorn Dizziness Center, Haga Hospital and the ‘Hoormij’ foundation, all in the Netherlands. Inclusion criteria comprised: (1) age 18 years or older; (2) diagnosed with a vestibular disorder by an otorhinolaryngologist with an expertise in vestibular disorders, according to the Barany Society diagnostic criteria [43‐46] (if applicable); (3) good understanding of the Dutch language (reading and listening); (4) in possession of a smartphone or tablet; (5) being capable to install and use the DizzyQuest (see below for explanation of the application). Patients were excluded if they did not feel comfortable to answer questions from the DizzyQuest, for example, concerning their psychological status.

The DizzyQuest is an app-based electronic diary that is implemented on the “UM ESM” (v2.04) platform. This is an experimental version of the PsyMate™ app (http://​www.​psymate.​eu) used for research at Maastricht University. The app allows implementation of ESM based protocols with multiple questionnaires and sampling schemes [47]. It is available as a download for smartphones running on iOS and Android. The DizzyQuest consists of four questionnaires. The “within-day-questionnaire” assesses the current situation at semi-random intervals throughout the day in the tradition of the ESM method for 10 times a day. The other three questionnaires are retrospective, in principle reflecting an aggregated situation of the previous night (morning questionnaire), or previous day (evening questionnaire). The attack questionnaire is event based and filled in after the occurrence of an attack of vertigo or dizziness (Table 1). It can be completed at any time after an attack, even after more than 1 day (Online Resource 1). Each questionnaire has its own specific set of questions, although considerable overlap exists between some of them (e.g. the within-day-questionnaire and the evening-questionnaire, see Online Resource 1 for the translated version). All four questionnaires combined, not only measure vestibular symptoms, but also emotion, cognition, context and stressful events. All questions about symptoms use the seven-point Likert scale, ranging from 1 (not at all) to 7 (very). It should be noted that the questionnaires were provided in Dutch. In this language, “dizziness” and “vertigo” are often used interchangeably in contrast to the English language, in which “dizziness” and “vertigo” are considered two different entities [48].

These different strategies (momentary versus retrospective) and different questionnaires, provide the opportunity to measure multiple aspects of neuro-otological symptoms and their psychosocial context. Table 2 provides possible outcome measures that can be obtained by the DizzyQuest on an individual level.

Before start of the DizzyQuest study, patients were contacted by two of the authors (SvdW, AE) and instructed on how to use the app. An online video was used for instructing the patients how to use the DizzyQuest (Online Resource 2). After that, the DizzyQuest was used for four sequential weeks. In this study, not all questionnaires were applied in the same frequency and for the same duration (Table 1). In the first week, each day contained one morning-questionnaire, 10 within-day-questionnaires and one evening-questionnaire. Subjects received the within-day-questionnaires 10 times a day, between 07:30 a.m. and 22:30 p.m., at semi-random moments (a day consisted of ten 90-min blocks and at a random moment in each block, a questionnaire was sent to the patient). The morning-, day- and evening-questionnaires were activated at 04:00 a.m. and 07:30 p.m. respectively, with a reminder on the smartphone or tablet at 9:00 a.m. and 8:00 p.m. respectively. They could be answered for a period of 8 and 8.5 h, respectively. The within-day-questionnaires were activated after a signalling beep/notification on the device. The subject was able to fill in the questionnaire within a time window of 15 min. When the opportunity to fill in the questionnaire closed, the questionnaires disappeared from the home screen and data were archived as “negative response”. The attack-questionnaire could be used at any given moment, as many times a day as needed. Subjects were instructed on the first day and debriefed on day 28. After the first week, only the evening- and attack-questionnaires remained. Therefore, in the last 3 weeks, patients only had to fill in one questionnaire a day (the evening-questionnaire), and optionally the attack-questionnaire in case of an attack of vertigo or dizziness, to reduce the burden for subjects.

The ESM UM Reporting Tool provides the opportunity for online monitoring of results. It was used to remotely monitor compliance of patients by two of the authors (SvdW, AE). In case a patient did not start the DizzyQuest at the predetermined day, or when sequentially multiple questionnaires were not answered, patients were contacted by phone or e-mail to provide any help if necessary (e.g., technical help).

Patients that started in the first week and continued the use of the DizzyQuest up to and including the fourth week, were included in the analysis. No minimum threshold of response rates was required. DizzyQuest data were extracted from the ESM UM database and transferred to IBM SPSS Statistics Version 25 (IBM Corporation, New York, United States of America). Data from the first day (briefing) was incomplete and skipped from the analysis, leaving only within-day-questionnaire data from day two until seven. The morning questionnaire was available from day two until eight, resulting in 7 days of data to be used for analysis. The evening- and attack-questionnaires were available for the whole 28 days period. Descriptive statistics were used. Furthermore, a Mann–Whitney U test, Fisher’s Exact test and a Fisher-Freeman-Halton exact test of independence were used to calculate differences in age, gender and diagnosis respectively, between the study group and drop-out group. The average response rate of each patient for each questionnaire was calculated by dividing the amount of fully completed questionnaires by the number of scheduled questionnaires. Only fully completed questionnaires were considered as valid. It was hypothesized that not all administered questionnaires would be completed. A desired response rate of > 50% was used, since reported response rates in current literature about momentary assessments are often higher than 50% [49, 50]. To calculate whether response rates of the DizzyQuest questionnaires were significantly different from the > 50% desired response rate [47, 51], a one-sample T test was performed.

Regarding presence of neuro-otological symptoms, they were considered “reported” and present, when they were selected in the question: ‘Now I suffer from’ (Online Resource 1). The reported frequency (%) of neuro-otological symptoms obtained with the within-day questionnaire, was first calculated for each symptom per patient. This was done by dividing the amount of times a specific symptom was reported, by the amount of times the individual patient completed the within-day questionnaire. This resulted in a patient-specific percentage. This patient-specific percentage was used to determine the mean reported frequency (%) of all patients, divided in three subgroups of vestibular disorders: Menière’s disease (MD), bilateral vestibulopathy (BV), and other vestibular disorders.

Marginal logistic regression analysis based on the generalized estimated equations analysis (GEE) method for binary outcomes was used to test significant differences in reported symptoms between subgroups of vestibular disorders and the outcomes were Bonferroni corrected. An exchangeable covariance structure was applied, since time interval between within-day questionnaires was not constant.

To investigate the effect of neuro-otological symptoms on questions regarding positive affect and negative affect, linear mixed-effects regression analysis was performed. The independent variables in the models were one of the neuro-otological symptoms (“imbalance”, “tinnitus” and “visual problems when moving”). The score on one of the questions regarding positive affect (“I generally feel well at the moment”) and negative affect (“I’m worrying about things”) was the dependent variable. In case of a significant interaction was found between the diagnosis group and the neuro-otological symptom, the analysis was performed for each diagnosis group separately.

This study was in accordance with the legislation and ethical standards on human experimentation in the Netherlands and in accordance with the Declaration of Helsinki (amended version 2013). The medical ethical committee of Maastricht UMC+ approved this study (2018-0809) and written informed consent was obtained from all patients, prior to participation.

Sixty-three patients were included in this study. Twelve patients dropped out of the study for a variety of reasons (e.g., technical problems or personal circumstances) as described in Table 3. Fifty-one patients completed the 4-week study period. This group consisted mostly of females (n = 33) and had a mean age of 56 years old (range 27–80 years). Etiologies comprised Menière’s disease (n = 19), vestibular migraine (n = 3), vestibulopathy (n = 1 unilateral, n = 23 bilateral) and overlap syndrome between Menière’s disease and vestibular migraine (n = 5). There were no significant differences between the patients who completed the study period and the patients who dropped out, regarding age (p = 0.475), gender (p = 0.309) and vestibular diagnosis (p = 0.367).

Figure 1 presents the average response rates of fully completed questionnaires of the DizzyQuest. The response rates were 90% for the morning-questionnaire, 62% for the within-day-questionnaire and 87% for the evening-questionnaire. The response rates of the morning, day and evening questionnaires were significantly different from the desired a priori defined response rate of > 50% (p < 0.001) respectively.

The DizzyQuest enables the opportunity to give additional insights in fluctuation of symptoms during a specific time period (e.g., day or week), and to investigate the appearance of symptoms in relation to psychosocial context (Table 2). Figure 2a, b present examples of the association of imbalance and general well-being during a day (Fig. 2a) and a month (Fig. 2b) in a patient with Menière’s disease, as a representative sample of results obtained in this study. Figure 3 presents the average scores of all 10 administered within-day-questionnaires during six consecutive days regarding imbalance and general well-being in the same patient. These figures show that with the DizzyQuest, it is possible to calculate correlations between the appearance of symptoms and their context, on an individual and group level (see below “Appearance of neuro-otological symptoms in relation to psychosocial context”).

A subset of the study population was loss-to-follow-up. This implies that results are only a reflection of the patients that completed the whole 4-week study period. Whether this has induced any selection bias, cannot be ruled out. Furthermore, completing the questionnaires might take some time, especially in the beginning. However, bothersome time consumption was not measured in this study. After familiarization with the questionnaires, time to complete each questionnaire dropped to on average 2 min, according to the patients’ feedback.

In this first article about the DizzyQuest, it would have been preferred to also report on its content and construct validity. However, since the development of the DizzyQuest was a very long and thorough process according to the COSMIN guidelines [60], it was decided to report this separately in an article fully devoted to the validity of the DizzyQuest (manuscript in preparation).

To fully capture symptoms of patients and their psychosocial context, focus groups were recently conducted, in which the questionnaires were discussed in a standardized way [56, 61]. Patients and doctors got the opportunity to include, exclude and rephrase questionnaire items. These results will be implemented in the updated version of the DizzyQuest. Furthermore, the DizzyQuest should also be validated, including comparison to currently used questionnaires like the DHI and HADS (concurrent validity), and it should be translated into multiple languages. Preliminary observations showed in some cases discrepancies between reported symptoms in the within-day-questionnaire and the evening-questionnaire (data not shown). This is probably due to the different nature of the questionnaires (momentary versus retrospective design) and their timing (multiple times a day versus only one time during the evening).

Moreover, recent technological innovations resulted in portable hearing tests [62], video-oculography goggles for home use [63] and wearable movement sensors [64]. Simultaneous data-acquisition of these devices in combination with the DizzyQuest during daily life, might result in clinically useful insights regarding the correlation between subjective symptoms and objective measurements in patients with vestibular disorders. Finally, it should be noted that the frequency of administering the DizzyQuest questionnaires is not fixed. For example, in this study the within-day-questionnaire was administered 10 times a day for 1 week. However, this could be changed to e.g., 6 times a day for 2 weeks. Currently, two versions of the DizzyQuest are being developed for use in the near future: an updated extensive version for research including all questionnaires mentioned in this study, and a short DizzyQuest including only the evening- and attack-questionnaire. This latter should be able to serve as a standardized vestibular diary with relatively little retrospectivity, but without the burden of the within-day-questionnaire. However, it should be noted that not using momentary assessments might decrease the sensitivity and the ability to investigate symptom appearance in relation to psychosocial context [65].