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Anxiety and anxious-depression in Parkinson's disease over a 4-year period: a latent transition analysis

Published online by Cambridge University Press:  23 November 2015

S. Landau ,
V. Harris ,
D. J. Burn ,
J. V. Hindle ,
C. S. Hurt ,
M. Samuel ,
K. C. Wilson  and
R. G. Brown
S. Landau
Affiliation:
Department of Biostatistics, Institute of Psychiatry, Psychology and Neuroscience, King's College London, UK
V. Harris
Affiliation:
Department of Biostatistics, Institute of Psychiatry, Psychology and Neuroscience, King's College London, UK
D. J. Burn
Affiliation:
Institute of Neuroscience, Newcastle University, Newcastle upon Tyne, UK
J. V. Hindle
Affiliation:
Betsi Cadwaladr University Health Board, Department of Care of the Elderly, Llandudno, UK University of Bangor, North Wales Organisation for Randomised Trials in Health (NWORTH), UK
C. S. Hurt
Affiliation:
School of Health Sciences, City University London, London, UK
M. Samuel
Affiliation:
Department of Neurology, King's College Hospital, King's Health Partners, London, UK East Kent Hospitals NHS University Foundation Trust, Ashford, Kent, UK
K. C. Wilson
Affiliation:
EMI Academic Unit, University of Liverpool, St Catherine's Hospital, Wirral, UK
R. G. Brown*
Affiliation:
Department of Psychology, Institute of Psychiatry, Psychology and Neuroscience, King's College London, UK
*
*Address for correspondence: Professor R. G. Brown, Institute of Psychiatry, Psychology and Neuroscience (PO77), De Crespigny Park, London SE5 8AF, UK. (Email: richard.g.brown@kcl.ac.uk)
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Abstract

Background

Depression and anxiety in Parkinson's disease are common and frequently co-morbid, with significant impact on health outcome. Nevertheless, management is complex and often suboptimal. The existence of clinical subtypes would support stratified approaches in both research and treatment.

Method

Five hundred and thirteen patients with Parkinson's disease were assessed annually for up to 4 years. Latent transition analysis (LTA) was used to identify classes that may conform to clinically meaningful subgroups, transitions between those classes over time, and baseline clinical and demographic features that predict common trajectories.

Results

In total, 64.1% of the sample remained in the study at year 4. LTA identified four classes, a ‘Psychologically healthy’ class (approximately 50%), and three classes associated with psychological distress: one with moderate anxiety alone (approximately 20%), and two with moderate levels of depression plus moderate or severe anxiety. Class membership tended to be stable across years, with only about 15% of individuals transitioning between the healthy class and one of the distress classes. Stable distress was predicted by higher baseline depression and psychiatric history and younger age of onset of Parkinson's disease. Those with younger age of onset were also more likely to become distressed over the course of the study.

Conclusions

Psychopathology was characterized by relatively stable anxiety or anxious-depression over the 4-year period. Anxiety, with or without depression, appears to be the prominent psychopathological phenotype in Parkinson's disease suggesting a pressing need to understanding its mechanisms and improve management.

Keywords

Anxietydepressionlatent transition analysisParkinson's diseasesubtypes
Type
Original Articles
Information
Psychological Medicine , Volume 46 , Issue 3 , February 2016 , pp. 657 - 667
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © Cambridge University Press 2015

Introduction

Depression and anxiety are common in Parkinson's disease (PD) (Reijnders et al. Reference Reijnders, Ehrt, Weber, Aarsland and Leentjens2008; Dissanayaka et al. Reference Dissanayaka, Sellbach, Matheson, O'Sullivan, Silburn, Byrne, Marsh and Mellick2010), frequently co-occur (Nuti et al. Reference Nuti, Ceravolo, Piccinni, Dell'Agnello, Bellini, Gambaccini, Rossi, Logi, Dell'Osso and Bonuccelli2004; Negre-Pages et al. Reference Negre-Pages, Grandjean, Lapeyre-Mestre, Montastruc, Fourrier, Lepine and Rascol2010) and are associated with care dependency, poor work and social function, and reduced health-related quality of life (Schrag et al. Reference Schrag, Jahanshahi and Quinn2000; Riedel et al. Reference Riedel, Dodel, Deuschl, Klotsche, Forstl, Heuser, Oertel, Reichmann, Riederer, Trenkwalder and Wittchen2012; Armstrong et al. Reference Armstrong, Gruber-Baldini, Reich, Fishman, Lachner and Shulman2014; Chen & Marsh, Reference Chen and Marsh2014; Duncan et al. Reference Duncan, Khoo, Yarnall, O'Brien, Coleman, Brooks, Barker and Burn2014). Depression is further associated with faster rate of physical and cognitive decline (Starkstein et al. Reference Starkstein, Mayberg, Leiguarda, Preziosi and Robinson1992), increased dementia risk (Tandberg et al. Reference Tandberg, Larsen, Aarsland and Cummings1996) and higher mortality (Hughes et al. Reference Hughes, Ross, Mindham and Spokes2004). Despite these facts, good quality evidence for the management of depression is only recently emerging (Dobkin et al. Reference Dobkin, Menza, Allen, Gara, Mark, Tiu, Bienfait and Friedman2011; Richard et al. Reference Richard, McDermott, Kurlan, Lyness, Como, Pearson, Factor, Juncos, Serrano, Brodsky, Manning, Marsh, Shulman, Fernandez, Black, Panisset, Christine, Jiang, Singer, Horn, Pfeiffer, Rottenberg, Slevin, Elmer, Press, Hyson and McDonald2012) with a recognized paucity of evidence to guide the treatment of anxiety (Seppi et al. Reference Seppi, Weintraub, Coelho, Perez-Lloret, Fox, Katzenschlager, Hametner, Poewe, Rascol, Goetz and Sampaio2011; Deane et al. Reference Deane, Flaherty, Daley, Pascoe, Penhale, Clarke, Sackley and Storey2014).

PD is heterogeneous in symptoms and clinical course, suggesting possible pathophysiological disease subtypes and the opportunity to apply stratified treatment approaches to improve outcome (Seppi et al. Reference Seppi, Weintraub, Coelho, Perez-Lloret, Fox, Katzenschlager, Hametner, Poewe, Rascol, Goetz and Sampaio2011; Berg et al. Reference Berg, Lang, Postuma, Maetzler, Deuschl, Gasser, Siderowf, Schapira, Oertel, Obeso, Olanow, Poewe and Stern2013, Reference Berg, Postuma, Bloem, Chan, Dubois, Gasser, Goetz, Halliday, Hardy, Lang, Litvan, Marek, Obeso, Oertel, Olanow, Poewe, Stern and Deuschl2014). We previously reported a comprehensive cross-sectional assessment of mood and mood-related symptoms in a cohort of 513 patients (Prospective Study of Mood State in Parkinson's disease: PROMS-PD;  Brown et al. Reference Brown, Landau, Hindle, Playfer, Samuel, Wilson, Hurt, Anderson, Carnell, Dickinson, Gibson, van, Sellwood, Thomas and Burn2011). Latent class analysis (LCA) identified four classes interpreted as: psychologically healthy with low probability of clinically prominent depression and anxiety related symptoms (‘Psychologically healthy’, 60.4%); one characterized by anxiety-related symptoms (‘Anxious’, 22.0%); one with predominantly depressive symptoms (‘Depressed’, 9.0%) and finally a class with both anxiety and depressive symptoms (‘Anxious depressed’, 8.6%). The latter two classes differed on a range of demographic and clinical variables, suggesting that PD depression may be heterogeneous (Brown et al. Reference Brown, Landau, Hindle, Playfer, Samuel, Wilson, Hurt, Anderson, Carnell, Dickinson, Gibson, van, Sellwood, Thomas and Burn2011; Burn et al. Reference Burn, Landau, Hindle, Samuel, Wilson, Hurt and Brown2012). This paper reports a longitudinal extension of our 2011 study, employing assessment over a 4-year period to permit a more reliable assessment of mood-related subtypes; characterize change in depressive and anxious symptomatology as the disease progresses, and examine associated clinical and demographic features.

Method

Longitudinal PD cohort

PROMS-PD (UKCRN ID 2519) recruited participants over a 14-month period from specialist PD or movement disorder outpatient clinics across the UK (Brown et al. Reference Brown, Landau, Hindle, Playfer, Samuel, Wilson, Hurt, Anderson, Carnell, Dickinson, Gibson, van, Sellwood, Thomas and Burn2011). Eligibility criteria at inclusion were a clinical diagnosis of idiopathic PD, the ability to provide informed consent at entry and living within travelling distance from a study centre. Entry exclusion criteria were sensory loss or communication difficulty sufficient to interfere with assessment. After baseline assessment (year 1) participants were re-contacted 6-monthly and assessed annually. Drop-out at each contact was classified as death; not-assessable or withdrawal from the study due to worsening of physical or mental health or cognitive impairment; withdrawal for other reasons; loss of contact or moved out of area, and change in primary diagnosis.

Baseline clinical and demographic measures

Participants were assessed as described in full elsewhere (Brown et al. Reference Brown, Landau, Hindle, Playfer, Samuel, Wilson, Hurt, Anderson, Carnell, Dickinson, Gibson, van, Sellwood, Thomas and Burn2011; Burn et al. Reference Burn, Landau, Hindle, Samuel, Wilson, Hurt and Brown2012). Demographic information included gender, current age and socio-economic status (Office for National Statistics, 2000). Disease-related variables included age of PD onset, side of PD symptom onset and current antiparkinsonian medication from which a l-dopa equivalent daily dose (LEDD) was calculated (Tomlinson et al. Reference Tomlinson, Stowe, Patel, Rick, Gray and Clarke2010). Motor disability, symptom severity and motor complications were assessed using the Unified Parkinson's Disease Rating Scale (UPDRS; Fahn et al. Reference Fahn, Elton, Fahn, Marsden and Calne1987) parts II-IV, plus the Hoehn and Yahr Scale (Hoehn & Yahr, Reference Hoehn and Yahr1967), and Schwab and England Scale (Schwab & England, Reference Schwab, England, Gillingham and Donaldson1969). Rate of progression of motor symptoms at baseline (Lewis et al. Reference Lewis, Foltynie, Blackwell, Robbins, Owen and Barker2005) and motor phenotype [Postural Instability and Gait (PIGD) or Tremor-Dominant/Indeterminate] were derived from the UPDRS (Jankovic et al. Reference Jankovic, McDermott, Carter, Gauthier, Goetz, Golbe, Huber, Koller, Olanow and Shoulson1990). Cognition was assessed using the Addenbrooke's Cognitive Examination – Revised (ACE-R; Mioshi et al. Reference Mioshi, Dawson, Mitchell, Arnold and Hodges2006), an extended mental status examination assessing a range of neuropsychological processes relevant to PD. Burden of health complaint was assessed using the Duke University Older Americans Resources and Services (OARS) physical health measure (Whitelaw & Liang, Reference Whitelaw and Liang1991), including a checklist of physical health complaints common in older adults.

Assessment of depressive- and anxiety-related symptoms

Each year, depressive, anxiety and related symptoms were assessed using a semi-structured interview based on the Geriatric Mental State (GMS; Copeland et al. Reference Copeland, Kelleher, Kellett, Gourlay, Gurland, Fleiss and Sharpe1976). Symptoms were rated and then recoded as ‘prominent’ (1) or ‘absent/normal’ or ‘present but not prominent’ (0). Analyses were restricted to 26 GMS items reported as prominent in at least 2% of the sample at baseline (see Fig. 1). Depression severity was assessed with the Hamilton Depression Rating Scale (HAMD; Hamilton, Reference Hamilton1960). The Hospital Anxiety and Depression Scale (HADS) was used for self-report (Zigmond & Snaith, Reference Zigmond and Snaith1983). A history of depressive or anxiety disorder was ascertained by interview.

Fig. 1. Observed Geriatric Mental State prominent symptom frequencies by year.

Latent transition analyses (LTAs)

LTA is an extension of LCA which assumes that there exist unobserved (latent) categorical variables (classes) that explain the associations between observed measures. Two sets of parameters are estimated: (i) probabilities describing the marginal distribution of the latent classes at baseline and transition probabilities between latent classes over time and (ii) conditional probabilities, i.e. probabilities that a symptom is present given the participant belongs to a class. LTAs (Graham et al. Reference Graham, Collins, Wugalter, Chung and Hansen1991; Collins & Lanza, Reference Collins and Lanza2010) were carried out to identify depression and anxiety related subtypes in PD, characterize their profiles and describe change over time (transitions). Our LTA approach is similar to that used elsewhere (Lamers et al. Reference Lamers, Rhebergen, Merikangas, de, Beekman and Penninx2012). Specifically, we fit LTA models to a matrix of 513 patients on 26 binary GMS symptom scores at each of four annual time-points. We refer to the probabilities across the GMS items as the class profiles and use them for interpretation and labelling.

We assume that class profiles themselves do not vary over time, although we tested this assumption empirically by comparing the fit to that of a model that allowed all the conditional probabilities to vary (Collins & Lanza, Reference Collins and Lanza2010). As the LTAs carried out here were extensions of an LCA performed on the cross-sectional baseline data (Brown et al. Reference Brown, Landau, Hindle, Playfer, Samuel, Wilson, Hurt, Anderson, Carnell, Dickinson, Gibson, van, Sellwood, Thomas and Burn2011), we planned to fit a four-class model, but also re-assessed the number of classes empirically using several model fit indices.

We wished to employ all the available GMS data in the LTA modelling but without relying on the restrictive assumption that GMS scores were missing completely at random (MCAR). Instead we used survival analysis to identify baseline variables that predicted drop-out from the study and then extended the LTA model to include these variables by allowing them to predict class membership at each time point. The derived parameter estimates are valid under a less restrictive missing at random (MAR) assumption. Drop-out was measured every 6-month interval with time intervals frequently being right-censored. Complementary log-log regression was used to model the effect of a baseline variable on the hazard of dropping out in the next 6-month interval given that a participant is still in the study (Prentice & Gloeckler, Reference Prentice and Gloeckler1978). The approach relies on a proportional hazards assumption. The effect of each putative baseline predictor of drop-out was assessed separately resulting in a largish list of empirically identified predictors. A smaller representative predictor subset was identified for inclusion in the LTA choosing individual predictors that represented subsets of correlated predictors.

Stepwise multinomial logistic regression was used to assess whether baseline variables could predict path memberships of interest. A list of putative baseline predictors representing different constructs was used and a best prediction model established by forward variable selection. The forward variable selection was carried out by initially fitting multinomial logistic regression models with each predictor as a single covariate and selecting the best predictor by comparing the χ 2 goodness-of-fit statistic. At each subsequent stage the effect of adding each of the remaining predictors to the model was assessed using a likelihood ratio test and the next best predictor selected on the basis of statistical significance. The procedure was terminated when the likelihood ratio test was no longer significant for any of the remaining predictors.

Statistical analyses were carried out in Stata v. 11 (StataCorp, Reference StataCorp2009) and Mplus v. 7 (Muthen & Muthen, Reference Muthen and Muthen2007).

Ethical standards

The authors assert that all procedures contributing to this work comply with the ethical standards of the relevant national and institutional committees on human experimentation and with the Helsinki Declaration of 1975, as revised in 2008. (Ethics reference 07/MRE01/9).

Results

Sample characteristics and longitudinal GMS assessments

Of 941 patients invited to participate, 525 consented but 12 withdrew before baseline assessment. The baseline sample (N = 513) has been described previously (Brown et al. Reference Brown, Landau, Hindle, Playfer, Samuel, Wilson, Hurt, Anderson, Carnell, Dickinson, Gibson, van, Sellwood, Thomas and Burn2011; Burn et al. Reference Burn, Landau, Hindle, Samuel, Wilson, Hurt and Brown2012). Briefly, there was a wide range of PD duration and severity, although a majority were Hoehn and Yahr stages II–III with a non-tremor dominant motor profile. Almost all (95%) were taking antiparkinsonian drugs. About a third of the sample showed evidence of cognitive impairment. Analysable data were available from 458 (89.2%) at year 2, 395 (77.0%) at year 3 and 329 (64.1%) at year 4 (see Supplementary Fig. S1). There were 44 (8.6%) deaths; 45 (8.8%) became unassessable or withdrew from the study on health grounds; 48 (9.4%) withdrew for other reasons (e.g. too busy, no longer interested or no reason given), while 42 (8.2%) moved away or were uncontactable. Ten (1.9%) were re-diagnosed with either essential tremor (N = 3), progressive supranuclear palsy (N = 1), multiple system atrophy (N = 4) or had undergone a negative dopamine transporter scan (N = 2). As these numbers were small and all participants met diagnostic criteria at inclusion, they were retained in the analysis to better reflect the reality of the clinical setting.

The observed characteristics of the remaining sample at each time point were not subject to formal statistical comparison, and interpretation is subject to the effects of non-random drop-out. Nevertheless, the data indicated disease progression as evidenced by worsening of observed mean UPDRS scores, Hoehn and Yahr stages and increasing LEDD (see Supplementary Table S1). The overall rate of observed depression (HAMD ⩾10) increased from 20.5% at baseline to 24.1% of those remaining in the study at year 4, while use of antidepressant/anxiolytic medication increased from 23.5% to 30.4% over the same period. Fig. 1 shows the profile of observed frequencies of prominent GMS symptoms at each assessment point. Consistently over time the most common symptoms were worry, subjective tension and restlessness and fatigue with an observed prevalence of ⩾30% followed by poor concentration, irritability, symptoms of general anxiety and panic and loneliness. Other symptoms were observed in ⩽20% of the total sample across the 4 years.

LTA-defined PD subtypes

Table 1 shows fit indices for different numbers of classes based on the binary GMS scores alone. Akaike's Information Criterion (AIC) and sample size adjusted Bayesian Information Criterion (BIC) indicate the best fit for six classes, while the BIC and entropy support a four-class solution. We selected the latter as the most interpretable, for consistency with our previous LCA solution and to avoid small classes containing <5% of participants.

Table 1. Information criteria and entropies for fitted LTA models with different numbers of classes

LTA, Latent transition analysis; AIC, Akaike's Information Criterion; BIC, Bayesian Information Criterion.

For the first three indices (AIC, BIC, sample size adjusted BIC) a lower value indicates a better model fit. Entropy measures how well participants are classified with higher values indicating better classification.

Model fit indices for a model assuming full parameter invariance (AIC 22 834, BIC 23 736, sample size adjusted BIC 23 053) were better than those of a model that allowed class profiles to vary over time (AIC 23 601, BIC 25 271, sample size adjusted BIC 23 599). Thus, we continued to assume that class profiles did not vary and use the estimated conditional probabilities to summarize depressive and anxiety symptoms within classes.

The following baseline variables were associated with earlier drop-out (hazard ratios that differed from 1 (p < 0.05) in the complementary log-log regressions): older age, later age of PD onset, longer PD duration, higher UPDRS-III score, higher HAMD score, higher HADS anxiety and depression scores, lower ACE-R score, worse Schwab and England score, and Hoehn and Yahr stages IV or V. To reflect these correlated concepts in the LTA models, age at baseline, duration of PD, UPDRS-III score, HADS anxiety and depression and ACE-R score were selected for inclusion.

Interpretation of the LTA model was based on examination of the symptom profiles for the four latent classes (see Fig. 2). The first class (open circles) represents a high predicted probability (0.60–1.00) of anxiety symptoms, particularly subjective tension and worry, symptoms of generalized anxiety/panic, autonomic symptoms of anxiety, irritability and poor concentration. Other common symptoms (probability 0.40–0.59) included fatigue, depressed mood, crying, indecisiveness and slowed thinking. This class is labelled ‘High anxiety + depression’. Class 2 (solid circles), shows a similar profile but with lower probabilities of the main anxiety-related symptoms and is labelled ‘Moderate anxiety + depression’. Class 3 (open squares) is characterized mainly by moderate probabilities of anxiety symptoms without evident depression and is labelled ‘Moderate anxiety’. Finally, class 4 (solid squares) was characterized by low probability of any prominent symptoms and labelled ‘Psychologically healthy’.

Fig. 2. Estimated profiles of depression- and anxiety-related Parkinson's disease latent transition analysis classes.

The four-class LCA solution derived using the entire 4 years varies somewhat from our previous LTA solution from the baseline data alone (Brown et al. Reference Brown, Landau, Hindle, Playfer, Samuel, Wilson, Hurt, Anderson, Carnell, Dickinson, Gibson, van, Sellwood, Thomas and Burn2011). A cross-tabulation of the classifications at baseline revealed that the solutions matched for 87% of the sample with high correspondence (93%) for the ‘Psychologically healthy’ in the two analyses. Similarly 87% of those allocated to the LCA ‘Anxiety’ class were allocated to the LTA ‘Moderate anxiety’ class. For the two smaller classes, 59% of those previously labelled by LCA ‘Anxious depressed’ were now allocated to the ‘High anxiety + depression’ LTA class and 38% to ‘Moderate anxiety + depression’. Similarly, 64% of those in the original LCA class ‘Depressed’ ended up in the new ‘Moderate anxiety + depression’ LTA class, while 23% were labelled ‘Moderate anxiety’.

Because of the association between higher levels of depression and anxiety at baseline and subsequent loss to follow-up we would expect different drop-out rates across the four classes. However, the inclusion of predictors of drop-out in the LTA model means that such differential drop-out would not affect the analysis or interpretation of the results.

Transitions between PD subtypes and trajectory paths

Fig. 3 shows the estimated marginal proportions of the four classes at each time-point. The ‘Psychologically healthy’ class was most common, followed by the ‘Moderate anxiety’ class, and two anxious and depressed classes. There was a trend towards an increase in the combined depression-related classes, from 15.1% at baseline to 19.5–21.1% in subsequent years, while the ‘Moderate anxiety’ class showed a corresponding decrease.

Fig. 3. Estimated proportions (%) of latent transition analysis class membership at each time-point.

We used the fitted LTA model to classify every patient at each time-point according to their maximum posterior estimated class probability. Observed trajectories are represented graphically in Fig. 4 (see also Supplementary Table S3). The most common paths were those with membership of the same class over adjacent years. Overall, an estimated 51.1% [95% confidence interval (CI) 46.7–55.6] remained in the ‘Psychologically healthy’ class throughout the 4 years (which we call the ‘Remaining healthy’ path) while 33.7% (95% CI 29.5–38.0) stayed in one or other of the remaining classes (‘Remaining distressed’ path). Only 8.6% (95% CI 6.1–11.1) initially healthy were reclassified into one of the other classes (‘Becoming distressed’ path), while 6.5% (95% CI 4.3–9.7), of those initially ‘distressed’ were later reclassified as ‘Psychologically healthy’ (‘Becoming well’ path).

Fig. 4. Estimated frequencies of class transitions. The thickness of each black connecting bar (or dashed line) is proportional to the estimated transition frequency. Numerical frequencies are shown where >40%. Dashed lines indicate frequencies of 5–10%. For clarity, class transition frequencies of <5% are not shown (see Supplementary Table S3 for full numerical data).

Baseline predictors of trajectory paths

What predicts membership of these paths? Because we were modelling longitudinal patterns of change in the context of a chronic and progressive condition we limited the analysis to the ‘Remaining distressed’ and ‘Becoming distressed’ paths with ‘Remaining healthy’ as the reference path. Additionally, it was assumed that ‘Becoming well’ might reflect successful management of the depression and/or anxiety rather than reflecting particular baseline characteristics.

The following list of baseline demographic and clinical variables were considered a priori as potential predictors of trajectory paths: gender, age, age of onset of PD, LEDD, UPDRS-III, PD motor phenotype, estimated rate of progression of motor symptoms, presence of motor fluctuations, depression severity (HAMD), cognitive function (ACE-R), burden of physical health conditions (OARS), socio-economic status (NS-SEC) and history of psychiatric illness. The final model included HAMD score, age of PD onset and history of past mental illness as predictors of trajectory paths [model fit likelihood ratio χ 2(6) = 194.33, p < 0.0001, pseudo-r 2 = 0.238]. Younger age of onset predicted being on the ‘Becoming distressed’ path relative to ‘Remaining healthy’ [odds ratio (OR) per extra year = 0.95, 95% CI 0.93–0.98, z = −3.29, p < 0.001] (i.e. for every year older at PD onset there was a 5% lower risk of becoming distressed having been psychologically healthy initially). ‘Remaining distressed’ was predicted by higher baseline HAMD (OR per extra point on scale = 1.35, 95% CI 1.27–1.44, z = 9.28, p < 0.001), younger age of PD onset (OR 0.97, 95% CI 0.95–0.99, z = −2.75, p = 0.01) and history of past psychiatric illness (OR 2.17, 95% CI 1.23–3.83, z = 2.68, p = 0.01).

It should be noted that this analysis is limited to baseline predictors of broadly defined paths. We did not consider the large number of potential individual transitions, nor factors that may have changed in the preceding 12 months before each assessment. Thus changes in medication and health status, life events, etc. may have additionally explained some of the individual transitions observed.

Discussion

We consider here the present findings in relation to our previous cross-sectional analysis and subtype classification (Brown et al. Reference Brown, Landau, Hindle, Playfer, Samuel, Wilson, Hurt, Anderson, Carnell, Dickinson, Gibson, van, Sellwood, Thomas and Burn2011) before discussing the results in the context of other longitudinal studies of depression and anxiety in PD. We then consider the implications for our conceptualization of depression and anxiety, its clinical management and directions for future research.

The LTA enhances our previous work investigating latent classes at a single time point (Brown et al. Reference Brown, Landau, Hindle, Playfer, Samuel, Wilson, Hurt, Anderson, Carnell, Dickinson, Gibson, van, Sellwood, Thomas and Burn2011) as it makes use of all available data over an extended period of cohort observation incorporating baseline predictors of missingness. The profiles of the four-class solutions from the present LTAs were broadly similar to those from the previous, but more restricted, LCA with close agreement in class membership. They differed in that the ‘Depressed’ class profile was better characterized as ‘Moderate anxiety + depression’. This differed from the ‘High anxiety + depression’ class profile mainly in the prominence of anxiety symptoms (Fig. 2). The existence of two anxious-depressed classes (comprising almost 20% of our sample by year 4) and a further 20% anxious patients (class 3), points strongly to anxiety being the most prevalent and prominent mood-related non-motor feature of PD (Fig. 3), co-occurring 50% of the time with depressive symptoms.

It is notable that the rates of anxiety-related symptom profiles over the years (40–45%) was higher than the prevalence of anxiety indicated by the HADS (Anxiety score ⩾11) of 20–25% (Supplementary Table S2). This may reflect differences in the nature of the assessment (clinician rated using semi-structured interview for the GMS and self-report for the HADS) or a lower sensitivity to detect clinically meaningful symptomatology from the HADS. However, the results indicate that evidence derived from the HADS, and potentially other self-report scales, may underestimate the burden of prominent anxiety-related symptomatology in PD.

The close association between depression and anxiety observed here is consistent with previous findings that two-thirds of PD patients with a depressive disorder had a co-morbid anxiety disorder (Menza et al. Reference Menza, Robertson and Bonapace1993), and that the presence of depression was associated with a five-fold increased risk of co-morbid anxiety (Qureshi et al. Reference Qureshi, Amspoker, Calleo, Kunik and Marsh2012). Importantly, our current data-driven methods failed to identify a class with a profile characterized by predominantly depressive symptoms. As such, the present results do not support the existence of depression subtypes with potentially different aetiologies and mechanisms and so requiring different treatments. Rather, the empirically defined PD subgroups are better characterized by the severity of anxiety symptoms and the presence or absence of co-occurring depression. However, the lack of a non-anxious depressed class in the LTA does not imply that depression without anxiety is absent in PD. The LTA classes are defined on the basis of a profile of symptom probabilities and do not indicate the absolute presence of absence of a symptom. Additionally, constraining the model to four classes may have masked smaller groupings that would have emerged if the model had allowed for a larger number of classes.

The validity of this LTA depends upon the assumption that the data are missing at random, i.e. that the probability of being missing is dependent only on variables which are incorporated by the model. This assumption is reasonable as the additional variables included as predictors of latent classes capture reasons for drop-out, in particular worsening health or death. Other reasons for drop-out, such as having moved out of the area, may be viewed as chance occurrences. It is acknowledged that additional factors influencing drop-out may have been missed, which would introduced bias. We have assumed that any such bias will be relatively small and as such will be more than compensated for by the gains made from using all the available data.

Although not the primary aim, the present report provides novel prospective data on the natural history of depression and anxiety in a large, well characterized cohort. The observed symptoms showed a remarkably consistent profile over the four time-points (Fig. 1). There was relatively little change in individual symptom prevalence, and observed overall mean depression and anxiety severity as indicated by the mean HADS and HAMD scores remained relatively stable (see Supplementary Table S1). However categorically defined depression (HAMD ⩾10) did increase slightly from 20.5% of the sample at baseline to 24.1% of those remaining in the study after 4 years. In one of the few previously published longitudinal studies (DATATOP), 795 newly diagnosed PD patients were followed for up to 7 years, by which time an estimated 24% scored ⩾10 on the HAMD (Vu et al. Reference Vu, Nutt and Holford2012). Depression was also relatively stable in an earlier 12-month longitudinal study (Starkstein et al. Reference Starkstein, Mayberg, Leiguarda, Preziosi and Robinson1992).

An important contribution of this study is the characterization of change over time in terms of transitions between mood-related classes. Examination of the data and analyses revealed a predominant tendency for stability rather than change (Fig. 4 and Supplementary Table S3). In particular over 50% of the cohort remained in the psychologically healthy class over the entire 4 years of study, despite facing the likely challenge of a progressive condition and prospect of future worsening. A proportion (13.7% in year 1, to 23.5% in year 4) were taking antidepressant/anxiolytics and so, for some, psychological health may indicate successful treatment outcome. For the remainder, however, it is likely to reflect other factors. Resilience is a multidimensional construct that allows individuals to navigate and respond to the challenges of a chronic stressor such as disease to protect life-satisfaction and well-being. Social and lifestyle factors such as social networks and physical activity may play a role, while adaptive illness beliefs and coping style can play an important role in buffering the effects of disease, either the greater active use of problem-orientated coping, or lesser reliance on strategies involving avoidance or emotion (Evans & Norman, Reference Evans and Norman2009; Hurt et al. Reference Hurt, Thomas, Burn, Hindle, Landau, Samuel, Wilson and Brown2011, Reference Hurt, Landau, Burn, Hindle, Samuel, Wilson and Brown2012). Complex biologically and environmentally determined dispositional characteristics (traits) may also play a protective role including optimism (Hurt et al. Reference Hurt, Burn, Hindle, Samuel, Wilson and Brown2013; Gison et al. Reference Gison, Dall'Armi, Donati and Rizza2014) or a lifelong low tendency to engage in worry or rumination in response to stressors and threats (Michl et al. Reference Michl, McLaughlin, Shepherd and Nolen-Hoeksema2013). At a more fundamental level there is growing interest in how low biological sensitivity of the hypothalamic-pituitary-adrenal axis and sympathetic nervous system to stressors may be protective, and amenable to behavioural interventions such as physical exercise (Silverman & Deuster, Reference Silverman and Deuster2014).

Just as psychologically healthy individuals tended to remain so over the course of the 4 years, we showed that those with prominent symptoms of anxiety and/or depression at baseline tended to remain psychologically distressed. Antidepressant/anxiolytic use, although higher than in the psychologically healthy class, was still less than might be expected (see Supplementary Table S3) suggesting possible under-recognition or under-treatment by clinicians as reported elsewhere (Shulman et al. Reference Shulman, Taback, Rabinstein and Weiner2002; Weintraub et al. Reference Weintraub, Moberg, Duda, Katz and Stern2003), or patient reluctance to take more medication (Dobkin et al. Reference Dobkin, Rubino, Friedman, Allen, Gara and Menza2013). Prolonged distress might also indicate the presence of vulnerability factors opposite to those associated with resilience. Although not a comprehensive assessment, our analysis identified only younger age of onset, higher baseline depression levels and a prior history of depressive illness as the main predictors of persistent psychological morbidity relative to continued health. Other demographic and PD-related factors such as higher LEDD, the presence of motor fluctuations, cognitive impairment and motor phenotype were not predictive once the effect of the above three variables was accounted for. Few participants became distressed, having been well initially and only younger age of onset predicted this trajectory. However, this reinforces the vulnerability of this group and the need for clinical vigilance.

Consistent with evidence that anxiety increases the risk of depression onset or relapse in older adults (Andreescu et al. Reference Andreescu, Lenze, Dew, Begley, Mulsant, Dombrovski, Pollock, Stack, Miller and Reynolds2007) 25.7% (n = 29) of those in our ‘Moderate anxiety’ class in year 1 transitioned into one of the two anxiety + depression classes in year 2 (Supplementary Table S3). At the same time 36.1% (n = 31) transitioned in the opposite direction, suggesting a remission of depression but with significant residual anxiety.

It should be noted that the reported evidence on stability and transitions needs to be interpreted in the context of the 12-month assessment intervals. This means that shorter term transitions (e.g. from psychologically healthy to distressed and back to healthy) would not have been detected.

What are the implications of these findings for treatment and the design of clinical trials? Good quality evidence for the efficacy of pharmacotherapy for depression remains limited, inconsistent and indicates only low to moderate effect sizes (Weintraub et al. Reference Weintraub, Morales, Moberg, Bilker, Balderston, Duda, Katz and Stern2005; Menza et al. Reference Menza, Dobkin, Marin, Mark, Gara, Buyske, Bienfait and Dicke2009). In the largest trial to date (SAD-PD), significant effects were observed for mean depression severity change at 12 weeks treatment with paroxetine and venlafaxine XR. However, response and remission rates did not differ from placebo (Richard et al. Reference Richard, McDermott, Kurlan, Lyness, Como, Pearson, Factor, Juncos, Serrano, Brodsky, Manning, Marsh, Shulman, Fernandez, Black, Panisset, Christine, Jiang, Singer, Horn, Pfeiffer, Rottenberg, Slevin, Elmer, Press, Hyson and McDonald2012). However a third or more of those receiving active treatment failed to show a clinical response (⩾50% decrease in HAM-D) (32% paroxetine, 47% venlafaxine), while the majority failed to remit (defined as HAMD ⩽7) (56% paroxetine and 63% venlafaxine). These results are consistent with other depression RCTs in older adults. Low remission and response rates are typical and associated with factors including co-morbid physical health conditions and cognitive change, particularly executive dysfunction (Alexopoulos et al. Reference Alexopoulos, Buckwalter, Olin, Martinez, Wainscott and Krishnan2002), both very relevant to PD. A further predictor of poor treatment outcome is co-morbid anxiety. In the SAD-PD trial, high anxiety predicted worse antidepressant response (Moonen et al. Reference Moonen, Wijers, Leentjens, Christine, Factor, Juncos, Lyness, Marsh, Panisset, Pfeiffer, Rottenberg, Serrano, Shulman, Singer, Slevin, McDonald, Auinger and Richard2014), a finding shown in RCTs of non-PD depression (Fava et al. Reference Fava, Rush, Alpert, Balasubramani, Wisniewski, Carmin, Biggs, Zisook, Leuchter, Howland, Warden and Trivedi2008; Penninx et al. Reference Penninx, Nolen, Lamers, Zitman, Smit, Spinhoven, Cuijpers, de Jong, van Marwijk, van der Meer, Verhaak, Laurant, de, Hoogendijk, van der Wee, Ormel, van and Beekman2011) including in late-life depression (Andreescu et al. Reference Andreescu, Lenze, Dew, Begley, Mulsant, Dombrovski, Pollock, Stack, Miller and Reynolds2007; Cohen et al. Reference Cohen, Gilman, Houck, Szanto and Reynolds2009). Relapse rates tend to be high in such cases, perhaps because of a larger burden of side effects and lower compliance with maintenance therapy. While future antidepressant trials might seek to exclude patients with significant anxiety to evaluate their effectiveness in ‘pure’ depression, such evidence may be of limited value to guide the treatment of depression in PD where current evidence suggests that anxiety is such a prominent accompaniment.

Clinically, we need to be vigilant not just for the presence of depression, but the symptoms of anxiety and associated risk factors. As well as being a source of distress and disability, evident anxiety may indicate the possible presence of unrecognized depression, an increased risk of future depression and poor treatment outcome. For research, we need a far better understanding of the factors associated with onset, maintenance and outcome of anxiety if it is a characteristic component of the mood phenotypes in PD. Currently, our understanding of anxiety and its treatment lags far behind that of depression (Seppi et al. Reference Seppi, Weintraub, Coelho, Perez-Lloret, Fox, Katzenschlager, Hametner, Poewe, Rascol, Goetz and Sampaio2011), with no clinical trials to date with anxiety as the target and none in progress (ClinicalTrials.gov). This evidential gap was powerfully illustrated in the results of a recent systematic exercise to identify current gaps in clinical management commissioned by Parkinson's UK (Deane et al. Reference Deane, Flaherty, Daley, Pascoe, Penhale, Clarke, Sackley and Storey2014). Involving patients, carers, family members and health and social care professionals, it ranked ‘reducing stress and anxiety’ second in terms of evidential uncertainty below the management of balance and falls and above a wide range of other motor and non-motor symptoms. What form such treatment might take remains unclear without the underpinning research, but might best encompass a broad based, stepped-care approach with a combination of targeted psychological and pharmacological interventions.

Conclusions

The present study highlights the prevalence and potential clinical significance of anxiety-related symptoms in PD psychopathology, either in relative isolation or in the presence of depressive symptoms. A high level of stability is observed over time, both good psychological health pointing to resilience in some patients, but also in sustained psychological distress in many others extending over periods of years despite the best efforts of healthcare professionals. The need for better management of anxiety symptoms is becoming recognized and may be key to improving patient outcome. Primary trials of pharmacological and psychological treatments for anxiety are urgently needed, in addition to research into risk, aetiological and maintaining factors.

Supplementary material

For supplementary material accompanying this paper visit http://dx.doi.org/10.1017/S0033291715002196.

Acknowledgements

This research was supported by a grant from Parkinson's UK (Grant reference J-0601). Authors S.L. and R.G.B. received salary support from the National Institute for Health Research (NIHR) Mental Health Biomedical Research Centre and Dementia Unit at South London and Maudsley NHS Foundation Trust and King's College London. Author D.J.B. received salary support from the Newcastle National Institute for Health Research (NIHR) Biomedical Research Unit in Lewy Body Dementia. The views expressed are those of the authors and not necessarily those of the NHS, the NIHR or the Department of Health. In addition to the listed authors, we thank the following members of the PROMS-PD Study Group who all made a significant contribution to the work reported in this paper. London: K. R. Chaudhuri, King's College Hospital NHS Foundation Trust, London (participant recruitment); C. Clough, King's College Hospital NHS Foundation Trust, London (participant recruitment); B. Gorelick, Parkinson's UK, London (member of the study management group); A. Simpson, Institute of Psychiatry, King's College London, London (data collection); R. Weeks, King's College Hospital NHS Foundation Trust, London (participant recruitment). Liverpool and North Wales: M. Bracewell, Ysbyty Gwynedd, Bangor (participant recruitment, data collection); M. Jones, University of Wales Bangor, Bangor (participant recruitment, data collection); L. Moss, Wythenshawe Hospital, Manchester (participant recruitment, data collection); P. Ohri, Eryri Hospital, Caernarfon (participant recruitment); L. Owen, Wythenshawe Hospital, Manchester (participant recruitment, data collection); G. Scott, Royal Liverpool University Hospital, Liverpool (participant recruitment); C. Turnbull, Wirral Hospitals NHS Trust, Wirral (participant recruitment). Newcastle: S. Dodd, Institute for Ageing and Health, Newcastle University, Newcastle upon Tyne (participant recruitment, data collection); R. Lawson, Institute for Ageing and Health, Newcastle University, Newcastle upon Tyne (participant recruitment, data collection). We acknowledge F. Jichi, Biostatistics Group, Joint Research Office, University College London for help with the survival analyses. Support is acknowledged from the NIHR Dementias and Neurodegenerative Diseases Research Network (DeNDRoN); Wales Dementias and Neurodegenerative Diseases Research Network (NEURODEM Cymru); NIHR Mental Health Research Network (MHRN); and British Geriatric Society.

Declaration of Interest

None.

References

Alexopoulos, GS, Buckwalter, K, Olin, J, Martinez, R, Wainscott, C, Krishnan, KR (2002). Comorbidity of late life depression: an opportunity for research on mechanisms and treatment. Biological Psychiatry 52, 543558.CrossRefGoogle ScholarPubMed
Andreescu, C, Lenze, EJ, Dew, MA, Begley, AE, Mulsant, BH, Dombrovski, AY, Pollock, BG, Stack, J, Miller, MD, Reynolds, CF (2007). Effect of comorbid anxiety on treatment response and relapse risk in late-life depression: controlled study. British Journal of Psychiatry 190, 344349.CrossRefGoogle ScholarPubMed
Armstrong, MJ, Gruber-Baldini, AL, Reich, SG, Fishman, PS, Lachner, C, Shulman, LM (2014). Which features of Parkinson's disease predict earlier exit from the workforce? Parkinsonism and Related Disorders 20, 12571259.Google Scholar
Berg, D, Lang, AE, Postuma, RB, Maetzler, W, Deuschl, G, Gasser, T, Siderowf, A, Schapira, AH, Oertel, W, Obeso, JA, Olanow, CW, Poewe, W, Stern, M (2013). Changing the research criteria for the diagnosis of Parkinson's disease: obstacles and opportunities. Lancet Neurology 12, 514524.Google Scholar
Berg, D, Postuma, RB, Bloem, B, Chan, P, Dubois, B, Gasser, T, Goetz, CG, Halliday, GM, Hardy, J, Lang, AE, Litvan, I, Marek, K, Obeso, J, Oertel, W, Olanow, CW, Poewe, W, Stern, M, Deuschl, G (2014). Time to redefine PD? Introductory statement of the MDS Task Force on the definition of Parkinson's disease. Movement Disorders 29, 454462.Google Scholar
Brown, RG, Landau, S, Hindle, JV, Playfer, J, Samuel, M, Wilson, KC, Hurt, CS, Anderson, RJ, Carnell, J, Dickinson, L, Gibson, G, van, SR, Sellwood, K, Thomas, BA, Burn, DJ (2011). Depression and anxiety related subtypes in Parkinson's disease. Journal of Neurology Neurosurgery and Psychiatry 82, 803809.CrossRefGoogle ScholarPubMed
Burn, DJ, Landau, S, Hindle, JV, Samuel, M, Wilson, KC, Hurt, CS, Brown, RG (2012). Parkinson's disease motor subtypes and mood. Movement Disorders 27, 379386.Google Scholar
Chen, JJ, Marsh, L (2014). Anxiety in Parkinson's disease: identification and management. Therapeutic Advances in Neurological Disorders 7, 5259.Google Scholar
Cohen, A, Gilman, SE, Houck, PR, Szanto, K, Reynolds, CF III (2009). Socioeconomic status and anxiety as predictors of antidepressant treatment response and suicidal ideation in older adults. Social Psychiatry and Psychiatric Epidemiology 44, 272277.Google Scholar
Collins, LM, Lanza, ST (2010). Latent Class and Latent Transition Analysis with Applications in the Social, Behavioral and Health Sciences. John Wiley & Sons, Inc.: Hoboken, NJ.Google Scholar
Copeland, JR, Kelleher, MJ, Kellett, JM, Gourlay, AJ, Gurland, BJ, Fleiss, JL, Sharpe, L (1976). A semi-structured clinical interview for the assessment of diagnosis and mental state in the elderly: the Geriatric Mental State Schedule. I. Development and reliability. Psychological Medicine 6, 439449.Google Scholar
Deane, KH, Flaherty, H, Daley, DJ, Pascoe, R, Penhale, B, Clarke, CE, Sackley, C, Storey, S (2014). Priority setting partnership to identify the top 10 research priorities for the management of Parkinson's disease. BMJ Open 4, e006434.Google Scholar
Dissanayaka, NN, Sellbach, A, Matheson, S, O'Sullivan, JD, Silburn, PA, Byrne, GJ, Marsh, R, Mellick, GD (2010). Anxiety disorders in Parkinson's disease: prevalence and risk factors. Movement Disorders 25, 838845.Google Scholar
Dobkin, RD, Menza, M, Allen, LA, Gara, MA, Mark, MH, Tiu, J, Bienfait, KL, Friedman, J (2011). Cognitive-behavioral therapy for depression in Parkinson's disease: a randomized, controlled trial. American Journal of Psychiatry 168, 10661074.Google Scholar
Dobkin, RD, Rubino, JT, Friedman, J, Allen, LA, Gara, MA, Menza, M (2013). Barriers to mental health care utilization in Parkinson's disease. Journal of Geriatric Psychiatry and Neurology 26, 105116.Google Scholar
Duncan, GW, Khoo, TK, Yarnall, AJ, O'Brien, JT, Coleman, SY, Brooks, DJ, Barker, RA, Burn, DJ (2014). Health-related quality of life in early Parkinson's disease: the impact of nonmotor symptoms. Movement Disorders 29, 195202.Google Scholar
Evans, D, Norman, P (2009). Illness representations, coping and psychological adjustment to Parkinson's disease. Psychology and Health 24, 11811196.Google Scholar
Fahn, S, Elton, RL, members of the UPDRS development committee (1987). Unified Parkinson's Disease Rating Scale. In Recent Developments in Parkinson's Disease (ed. Fahn, S., Marsden, C. D. and Calne, D. B.), pp. 153164. Macmillan Health Care Information: Florham Park, NJ.Google Scholar
Fava, M, Rush, AJ, Alpert, JE, Balasubramani, GK, Wisniewski, SR, Carmin, CN, Biggs, MM, Zisook, S, Leuchter, A, Howland, R, Warden, D, Trivedi, MH (2008). Difference in treatment outcome in outpatients with anxious versus nonanxious depression: a STAR*D report. American Journal of Psychiatry 165, 342351.Google Scholar
Gison, A, Dall'Armi, V, Donati, V, Rizza, F, Giaquinto S Irccs San Raffaele Pisana Rome Italy (2014). Dispositional optimism, depression, disability and quality of life in Parkinson's disease. Functional Neurology 29, 113119.Google Scholar
Graham, JW, Collins, LM, Wugalter, SE, Chung, NK, Hansen, WB (1991). Modeling transitions in latent stage-sequential processes: a substance use prevention example. Journal of Consulting and Clinical Psychology 59, 4857.Google Scholar
Hamilton, M (1960). A rating scale for depression. Journal of Neurology Neurosurgery and Psychiatry 23, 5662.Google Scholar
Hoehn, MM, Yahr, MD (1967). Parkinsonism: onset progression and mortality. Neurology 17, 427442.Google Scholar
Hughes, TA, Ross, HF, Mindham, RH, Spokes, EG (2004). Mortality in Parkinson's disease and its association with dementia and depression. Acta Neurologica Scandinavica 110, 118123.Google Scholar
Hurt, CS, Burn, DJ, Hindle, J, Samuel, M, Wilson, K, Brown, RG (2013). Thinking positively about chronic illness: an exploration of optimism, illness perceptions and well-being in patients with Parkinson's disease. British Journal of Health Psychology 19, 363379.Google Scholar
Hurt, CS, Landau, S, Burn, DJ, Hindle, JV, Samuel, M, Wilson, K, Brown, RG (2012). Cognition, coping, and outcome in Parkinson's disease. International Psychogeriatrics 24, 16561663.Google Scholar
Hurt, CS, Thomas, BA, Burn, DJ, Hindle, JV, Landau, S, Samuel, M, Wilson, KC, Brown, RG (2011). Coping in Parkinson's disease: an examination of the coping inventory for stressful situations. International Journal of Geriatric Psychiatry 26, 10301037.Google Scholar
Jankovic, J, McDermott, M, Carter, J, Gauthier, S, Goetz, C, Golbe, L, Huber, S, Koller, W, Olanow, C, Shoulson, I (1990). Variable expression of Parkinson's disease: a base-line analysis of the DATATOP cohort. The Parkinson Study Group. Neurology 40, 15291534.Google Scholar
Lamers, F, Rhebergen, D, Merikangas, KR, de, JP, Beekman, AT, Penninx, BW (2012). Stability and transitions of depressive subtypes over a 2-year follow-up. Psychological Medicine 42, 20832093.Google Scholar
Lewis, SJG, Foltynie, T, Blackwell, AD, Robbins, TW, Owen, AM, Barker, RA (2005). Heterogeneity of Parkinson's disease in the early clinical stages using a data driven approach. Journal of Neurology Neurosurgery and Psychiatry 76, 343348.Google Scholar
Menza, M, Dobkin, RD, Marin, H, Mark, MH, Gara, M, Buyske, S, Bienfait, K, Dicke, A (2009). A controlled trial of antidepressants in patients with Parkinson disease and depression. Neurology 72, 886892.Google Scholar
Menza, MA, Robertson, HD, Bonapace, AS (1993). Parkinson's disease and anxiety: comorbidity with depression. Biological Psychiatry 34, 465470.Google Scholar
Michl, LC, McLaughlin, KA, Shepherd, K, Nolen-Hoeksema, S (2013). Rumination as a mechanism linking stressful life events to symptoms of depression and anxiety: longitudinal evidence in early adolescents and adults. Journal of Abnormal Psychology 122, 339352.Google Scholar
Mioshi, E, Dawson, K, Mitchell, J, Arnold, R, Hodges, JR (2006). The Addenbrooke's Cognitive Examination Revised (ACE-R): a brief cognitive test battery for dementia screening. International Journal of Geriatric Psychiatry 21, 10781085.Google Scholar
Moonen, AJ, Wijers, A, Leentjens, AF, Christine, CW, Factor, SA, Juncos, J, Lyness, JM, Marsh, L, Panisset, M, Pfeiffer, R, Rottenberg, D, Serrano, RC, Shulman, L, Singer, C, Slevin, J, McDonald, W, Auinger, P, Richard, IH (2014). Severity of depression and anxiety are predictors of response to antidepressant treatment in Parkinson's disease. Parkinsonism and Related Disorders 20, 644646.Google Scholar
Muthen, LK, Muthen, BO (2007). Mplus User's Guide. Muthen and Muthen: Los Angeles, CA.Google Scholar
Negre-Pages, L, Grandjean, H, Lapeyre-Mestre, M, Montastruc, JL, Fourrier, A, Lepine, JP, Rascol, O (2010). Anxious and depressive symptoms in Parkinson's disease: the French cross-sectionnal DoPaMiP study. Movement Disorders 25, 157166.Google Scholar
Nuti, A, Ceravolo, R, Piccinni, A, Dell'Agnello, G, Bellini, G, Gambaccini, G, Rossi, C, Logi, C, Dell'Osso, L, Bonuccelli, U (2004). Psychiatric comorbidity in a population of Parkinson's disease patients. European Journal of Neurology 11, 315320.Google Scholar
Office for National Statistics (2000). Standard Occupational Classification 2000. The Stationery Office: London.Google Scholar
Penninx, BW, Nolen, WA, Lamers, F, Zitman, FG, Smit, JH, Spinhoven, P, Cuijpers, P, de Jong, PJ, van Marwijk, HW, van der Meer, K, Verhaak, P, Laurant, MG, de, GR, Hoogendijk, WJ, van der Wee, N, Ormel, J, van, DR, Beekman, AT (2011). Two-year course of depressive and anxiety disorders: results from the Netherlands Study of Depression and Anxiety (NESDA). Journal of Affective Disorders 133, 7685.Google Scholar
Prentice, R, Gloeckler, L (1978). Regression analysis of grouped survival data with application to breast cancer data. Biometrics 34, 5767.Google Scholar
Qureshi, SU, Amspoker, AB, Calleo, JS, Kunik, ME, Marsh, L (2012). Anxiety disorders, physical illnesses, and health care utilization in older male veterans with Parkinson disease and comorbid depression. Journal of Geriatric Psychiatry and Neurology 25, 233239.Google Scholar
Reijnders, JSAM, Ehrt, U, Weber, WEJ, Aarsland, D, Leentjens, AFG (2008). A systematic review of prevalence studies of depression in Parkinson's disease. Movement Disorders 23, 183189.Google Scholar
Richard, IH, McDermott, MP, Kurlan, R, Lyness, JM, Como, PG, Pearson, N, Factor, SA, Juncos, J, Serrano, RC, Brodsky, M, Manning, C, Marsh, L, Shulman, L, Fernandez, HH, Black, KJ, Panisset, M, Christine, CW, Jiang, W, Singer, C, Horn, S, Pfeiffer, R, Rottenberg, D, Slevin, J, Elmer, L, Press, D, Hyson, HC, McDonald, W (2012). A randomized, double-blind, placebo-controlled trial of antidepressants in Parkinson disease. Neurology 78, 12291236.Google Scholar
Riedel, O, Dodel, R, Deuschl, G, Klotsche, J, Forstl, H, Heuser, I, Oertel, W, Reichmann, H, Riederer, P, Trenkwalder, C, Wittchen, HU (2012). Depression and care-dependency in Parkinson's disease: results from a nationwide study of 1449 outpatients. Parkinsonism and Related Disorders 18, 598601.Google Scholar
Schrag, A, Jahanshahi, M, Quinn, N (2000). What contributes to quality of life in patients with Parkinson's disease? J. Neurol. Neurosurg. Psychiatry 69, 308312.Google Scholar
Schwab, RS, England, AC (1969). Projection technique for evaluating surgery for Parkinson's disease. In Third Symposium on Parkinson's Disease (ed. Gillingham, F. J. and Donaldson, M. C.), pp. 152157. E&S Livingstone: Edinburgh.Google Scholar
Seppi, K, Weintraub, D, Coelho, M, Perez-Lloret, S, Fox, SH, Katzenschlager, R, Hametner, EM, Poewe, W, Rascol, O, Goetz, CG, Sampaio, C (2011). The movement disorder society evidence-based medicine review update: treatments for the non-motor symptoms of Parkinson's disease. Movement Disorders 26 (Suppl. 3), S42S80.Google Scholar
Shulman, LM, Taback, RL, Rabinstein, AA, Weiner, WJ (2002). Non-recognition of depression and other non-motor symptoms in Parkinson's disease. Parkinsonism and Related Disorders 8, 193197.Google Scholar
Silverman, MN, Deuster, PA (2014). Biological mechanisms underlying the role of physical fitness in health and resilience. Interface Focus 4, 20140040.Google Scholar
Starkstein, SE, Mayberg, HS, Leiguarda, R, Preziosi, TJ, Robinson, RG (1992). A prospective longitudinal study of depression, cognitive decline, and physical impairments in patients with Parkinson's disease. Journal of Neurology Neurosurgery and Psychiatry 55, 377382.Google Scholar
StataCorp, LP (2009). Stata 11 Base Reference Manual. Stata Press: College Station, TX.Google Scholar
Tandberg, E, Larsen, JP, Aarsland, D, Cummings, JL (1996). The occurrence of depression in Parkinson's disease. A community-based study. Archives of Neurology 53, 175179.CrossRefGoogle ScholarPubMed
Tomlinson, CL, Stowe, R, Patel, S, Rick, C, Gray, R, Clarke, CE (2010). Systematic review of levodopa dose equivalency reporting in Parkinson's disease. Movement Disorders 25, 26492653.Google Scholar
Vu, TC, Nutt, JG, Holford, NH (2012). Progression of motor and nonmotor features of Parkinson's disease and their response to treatment. British Journal of Clinical Pharmacology 74, 267283.Google Scholar
Weintraub, D, Moberg, PJ, Duda, JE, Katz, IR, Stern, MB (2003). Recognition and treatment of depression in Parkinson's disease. Journal of Geriatric Psychiatry and Neurology 16, 178183.Google Scholar
Weintraub, D, Morales, KH, Moberg, PJ, Bilker, WB, Balderston, C, Duda, JE, Katz, IR, Stern, MB (2005). Antidepressant studies in Parkinson's disease: a review and meta-analysis. Movement Disorders 20, 11611169.Google Scholar
Whitelaw, NA, Liang, J (1991). The structure of the OARS physical health measures. Medical Care 29, 332347.Google Scholar
Zigmond, AS, Snaith, RP (1983). The Hospital Anxiety and Depression Scale. Acta Psychiatrica Scandinavica 67, 361370.Google Scholar
Figure 0

Fig. 1. Observed Geriatric Mental State prominent symptom frequencies by year.

Figure 1

Table 1. Information criteria and entropies for fitted LTA models with different numbers of classes

Figure 2

Fig. 2. Estimated profiles of depression- and anxiety-related Parkinson's disease latent transition analysis classes.

Figure 3

Fig. 3. Estimated proportions (%) of latent transition analysis class membership at each time-point.

Figure 4

Fig. 4. Estimated frequencies of class transitions. The thickness of each black connecting bar (or dashed line) is proportional to the estimated transition frequency. Numerical frequencies are shown where >40%. Dashed lines indicate frequencies of 5–10%. For clarity, class transition frequencies of <5% are not shown (see Supplementary Table S3 for full numerical data).

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