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Pre-Surgery Depression and Confidence to Manage Problems Predict Recovery Trajectories of Health and Wellbeing in the First Two Years following Colorectal Cancer: Results from the CREW Cohort Study

  • Claire Foster ,

    C.L.Foster@soton.ac.uk

    Affiliations Macmillan Survivorship Research Group, Faculty of Health Sciences, University of Southampton, Southampton, SO17 1BJ, United Kingdom, Faculty of Health Sciences, University of Southampton, Southampton, SO17 1BJ, United Kingdom

  • Joanne Haviland,

    Affiliations Macmillan Survivorship Research Group, Faculty of Health Sciences, University of Southampton, Southampton, SO17 1BJ, United Kingdom, Faculty of Health Sciences, University of Southampton, Southampton, SO17 1BJ, United Kingdom

  • Jane Winter,

    Affiliations Faculty of Health Sciences, University of Southampton, Southampton, SO17 1BJ, United Kingdom, University Hospital Southampton NHS Foundation Trust, Southampton, SO16 6YD, United Kingdom

  • Chloe Grimmett,

    Affiliations Macmillan Survivorship Research Group, Faculty of Health Sciences, University of Southampton, Southampton, SO17 1BJ, United Kingdom, Faculty of Health Sciences, University of Southampton, Southampton, SO17 1BJ, United Kingdom

  • Kim Chivers Seymour,

    Affiliation Faculty of Health Sciences, University of Southampton, Southampton, SO17 1BJ, United Kingdom

  • Lynn Batehup,

    Affiliation Faculty of Health Sciences, University of Southampton, Southampton, SO17 1BJ, United Kingdom

  • Lynn Calman,

    Affiliations Macmillan Survivorship Research Group, Faculty of Health Sciences, University of Southampton, Southampton, SO17 1BJ, United Kingdom, Faculty of Health Sciences, University of Southampton, Southampton, SO17 1BJ, United Kingdom

  • Jessica Corner,

    Affiliation Executive Office, University of Nottingham, Nottingham, NG7 2RD, United Kingdom

  • Amy Din,

    Affiliations Macmillan Survivorship Research Group, Faculty of Health Sciences, University of Southampton, Southampton, SO17 1BJ, United Kingdom, Faculty of Health Sciences, University of Southampton, Southampton, SO17 1BJ, United Kingdom

  • Deborah Fenlon,

    Affiliation Faculty of Health Sciences, University of Southampton, Southampton, SO17 1BJ, United Kingdom

  • Christine M. May,

    Affiliations Macmillan Survivorship Research Group, Faculty of Health Sciences, University of Southampton, Southampton, SO17 1BJ, United Kingdom, Faculty of Health Sciences, University of Southampton, Southampton, SO17 1BJ, United Kingdom

  • Alison Richardson,

    Affiliations Faculty of Health Sciences, University of Southampton, Southampton, SO17 1BJ, United Kingdom, University Hospital Southampton NHS Foundation Trust, Southampton, SO16 6YD, United Kingdom

  • Peter W. Smith,

    Affiliation Social Statistics and Demography, Social Sciences, University of Southampton, Southampton, SO17 1BJ, United Kingdom

  • Members of the Study Advisory Committee

    Membership of the Study Advisory Committee is listed in the Acknowledgments.

Abstract

Purpose

This paper identifies predictors of recovery trajectories of quality of life (QoL), health status and personal wellbeing in the two years following colorectal cancer surgery.

Methods

872 adults receiving curative intent surgery during November 2010 to March 2012. Questionnaires at baseline, 3, 9, 15, 24 months post-surgery assessed QoL, health status, wellbeing, confidence to manage illness-related problems (self-efficacy), social support, co-morbidities, socio-demographic, clinical and treatment characteristics. Group-based trajectory analyses identified distinct trajectories and predictors for QoL, health status and wellbeing.

Results

Four recovery trajectories were identified for each outcome. Groups 1 and 2 fared consistently well (scores above/within normal range); 70.5% of participants for QoL, 33.3% health status, 77.6% wellbeing. Group 3 had some problems (24.2% QoL, 59.3% health, 18.2% wellbeing); Group 4 fared consistently poorly (5.3% QoL, 7.4% health, 4.2% wellbeing). Higher pre-surgery depression and lower self-efficacy were significantly associated with poorer trajectories for all three outcomes after adjusting for other important predictors including disease characteristics, stoma, anxiety and social support.

Conclusions

Psychosocial factors including self-efficacy and depression before surgery predict recovery trajectories in QoL, health status and wellbeing following colorectal cancer treatment independent of treatment or disease characteristics. This has significant implications for colorectal cancer management as appropriate support may be improved by early intervention resulting in more positive recovery experiences.

Introduction

Worldwide 17 million people are living with or beyond cancer. This figure is expected to triple by 2050. If patients are not adequately supported their recovery may be impaired at a cost to patients, those close to them, health and social care [1].

Cancer care is changing to tailored care according to need rather than a single approach for all. There is an increasing emphasis on supported self-management yet little is known about how equipped cancer survivors are for this [2]. Foster and Fenlon developed a conceptual framework of recovery from cancer in which confidence to manage problems and symptoms (self-efficacy: belief in one’s ability to manage illness-related problems) is hypothesised to be central to recovery [3]. A positive association between self-efficacy and quality of life (QoL) has been reported in cross-sectional studies [46], however, prospective studies are lacking [7].

While studies have explored QoL following colorectal cancer, most are cross-sectional and few include pre-treatment assessments [8]. Studies typically focus on specific outcomes, such as physical [9] and psychological symptoms [10], comorbidities [9], and presence of a stoma [11] which are associated with poorer QoL. Whilst these studies are important they are limited in describing the impact of cancer treatment on individuals and the process of recovery, or how individuals at risk of poor recovery can be identified or supported.

Previous literature suggests that QoL in the first years following colorectal cancer treatment are similar or better than population norms [7]. However these data report overall means and do not explore distinct groups of patients who may fare better or worse. Studies have begun to examine this by identifying trajectories of recovery for different populations and outcomes. For example, Dunn et al [12] identified 4 trajectories of psychological distress following colorectal cancer with baseline assessment at 5 months; 19% had consistently low levels of distress however the majority (39%) experienced a moderate level of distress which increased rather than decreased over time. Being younger, male, with late stage disease, low education and limited social support was associated with worse distress over time. In a further paper, Dunn and colleagues [13] described trajectories of health-related QoL (HRQoL) and life satisfaction over 5 years among colorectal cancer survivors (no pre-treatment assessment); 4 distinct trajectories were identified for HRQoL (measured by FACT-C), and 19% of respondents reported poor HRQoL throughout the 5 years. Factors associated with poorest recovery included being younger, having low social support, negative cognitive appraisal and low optimism. These findings have begun to enhance our understanding of the nature of longer-term recovery from cancer, however they do not include self-efficacy or assessments before treatment begins.

This paper presents data from CREW, the first large-scale cohort study of a representative group of colorectal cancer patients recruited before surgery and followed up at regular intervals that has a focus on recovery of health and wellbeing. We examine the impact of curative intent treatment on the processes of recovery of health and wellbeing, the role of factors hypothesised to be associated with recovery and implications for how patients can best be supported. The objectives of this paper are to: 1) describe recovery trajectories after colorectal cancer surgery in the first 2 years; and 2) find predictors for these, including self-efficacy.

Methods

Study design and participants

A prospective cohort study of colorectal cancer patients recruited from 29 UK hospitals between November 2010 and March 2012 [14, 15]. Eligible patients: a) diagnosis of colorectal cancer (Duke’s A-C, where A = T1/2, B = T3/4 N0 and C = T1-4 N1 or 2, with an R0 resection), b) awaiting initial curative intent surgery, c) ≥ 18 years, d) ability to complete questionnaires. Exclusions: metastatic disease at diagnosis or prior diagnosis of cancer (exceptions: non-melanomatous skin cancer; in situ carcinoma cervix). Written consent obtained and baseline questionnaires were completed prior to surgery wherever possible; follow-up questionnaires were completed at 3, 9, 15 and 24 months post-surgery (longer-term assessments ongoing). Socio-demographic information was collected at consent, including postcode, which was used to calculate the Index of Multiple Deprivation, a measure of neighbourhood deprivation [16]. Clinical and treatment details were collected from medical notes. Ethical approval was granted by the UK NHS Health Research Authority NRES Committee South Central—Oxford B (REC ref: 10/H0605/31).

Measures

Areas of assessment were informed by our recovery framework [3]. Validated measures were repeated at every time point unless otherwise indicated.

Quality of life, health status and personal wellbeing.

Quality of Life in Adult Cancer Survivors (QLACS [17]). Part 1 generic domains: negative feelings, positive feelings, cognitive problems, pain, sexual interest/function, energy/fatigue, social avoidance. Summing these domains (reverse-scoring positive feelings) yields Generic Summary Score (GSS). Part 2 (assessed ≥9 months) cancer-specific domains: appearance concerns, financial problems, distress from fear of recurrence, distress from family risk of cancer, benefits of cancer. Summing these domains (excluding benefits of cancer) yields Cancer-specific Summary Score (CSS). Higher scores represent poorer QoL (except positive feelings; benefits of cancer).

The EQ-5D and EQ Visual Analogue Scale (VAS) measure health status [18, 19]. Scores from each of 5 domains are combined and converted into a summary utility index; higher scores indicate better health. A score of 1 for the utility index indicates “full health” (no problems on any of the 5 domains).

The Personal Wellbeing Index–Adult (PWI-A [20]) contains 8 items of satisfaction corresponding to: standard of living, health, achieving in life, relationships, safety, community-connectedness, future security, and spirituality/religion. An overall score of subjective wellbeing is calculated, with higher scores denoting better wellbeing (< 70 represents reduced wellbeing).

Psychosocial factors.

State-Trait Anxiety Inventory (STAI [21]) consists of 20 items (state only), with a higher total score indicating greater state-anxiety; ≥ 40 has been suggested to indicate clinically significant anxiety [22].

Centre for Epidemiologic Studies Depression Scale (CES-D [23]) consists of 20 items, with a higher total score indicating greater depression; ≥ 20 has been suggested to indicate clinical depression (major and minor) for cancer patients [24].

Positive and Negative Affect Schedule Short Form (PANAS [25]) consists of two 5-item mood scales measuring positive and negative affect. Higher scores represent stronger positive or negative emotions.

Self-Efficacy for Managing Chronic Disease Scale [26] consists of 6 items (S1 Fig). Higher scores indicate greater confidence to manage illness-related problems.

Medical Outcomes Study (MOS [27]) consists of 19 items, 18 of which comprise 4 subscales representing emotional/informational, tangible, affectionate support and positive social interaction. An overall support index is calculated as the mean of all individual items; higher scores denote greater social support.

Statistical methods

Target sample size was 1000, based on ability to detect a difference of 0.5 of a standard deviation (SD) in the QLACS-GSS (assuming mean 71.2, SD 25.6) [17], with 80% power and 5% significance. This allowed for 30% drop-out and an intra-cluster correlation of 0.05 to take into account cluster effects within sites.

Subscale scores were calculated according to published guidelines where available; otherwise if ≥75% items within a subscale had been completed mean scores were imputed from completed items. Participants with missing questionnaires were included in analyses for time-points for which they provided data; no imputation of missing questionnaires. Many subscale scores were not normally distributed; means and standard deviations are presented, to enable comparison with other studies. The Index of Multiple Deprivation was categorised into quintiles.

Group-based trajectory analyses [28] were used to investigate whether distinct trajectories of outcomes could be identified for QLACS-GSS, EQ-5D utility index and PWI. These are discrete mixture models, which model the outcomes as censored normal data following a polynomial time curve. The optimal number of distinct trajectories for each outcome was determined using the Bayesian information criterion (BIC) [29, 30] to compare model fit (a change in BIC >10 supports the more complex model), while aiming to avoid trajectories containing very few individuals. The shape of each trajectory was assessed to determine whether it was best described by a linear, quadratic or cubic function according to the significance of each term. Statistical significance of model parameters was assessed by the Wald test. Estimated proportions of participants within each trajectory were obtained from the models, with 95% confidence intervals (CI). Date of surgery was taken as time zero and follow-up time calculated using date of questionnaire completion; timing of baseline questionnaire (pre/post-surgery) was adjusted for in all trajectory models.

Multinomial logistic regression was used to determine statistically significant predictors of trajectory group membership from the following domains measured at baseline: (i) pre-existing factors (sociodemographic, clinical, treatment) and (ii) psychosocial factors (anxiety, depression, positive/negative affect, self-efficacy, social support). Factors found to be significant or borderline significant (p<0.1) from univariate analyses were modelled together, and only those which remained statistically significant were retained in the final prediction models. Odds ratios (OR), with 95% CI for each predictor were obtained from the regression models.

Results

A total of 1,056 participants consented to the study (910 to all aspects of data collection and 146 to collection of medical details only) out of 1,234 invited. Post-surgery, 38/910 were deemed ineligible due to benign or advanced disease, leaving 872 participants for follow-up, of whom 15 withdrew consent prior to baseline data collection (Fig 1). The final denominator for collection of questionnaire data was 857 participants. The sample is representative of eligible patients treated in the recruitment period and includes: 64.6% colon and 35.4% rectal patients (Table 1). 18.4% received neoadjuvant, 34.7% adjuvant therapy and 35.4% had a stoma (most temporary). A total of 39 participants reported having ever used mental health services (5.4% of the 723 who responded to this item on the baseline questionnaire). By 24 months, 79 participants (9.3%) had experienced a recurrence (median 13 months), 65 (7%) had died, and 105 (12%) had withdrawn (Fig 1). Response rates were high at each time point; 809 (94.4%) completed at least one questionnaire from baseline to 2 years and were included in longitudinal analyses. Most participants (592/857, 69%) were consented and completed their baseline questionnaire prior to surgery but due to logistical issues (e.g. those receiving emergency surgery or surgical dates altered without notifying the research nurse) some were enrolled soon after surgery. Overall scores for QLACS, EQ-5D and PWI at each time-point show participants were coping reasonably well up to 2 years post-surgery, with mean scores on QLACS-GSS comparable with other cancer survivors at 15 months [31], with over 40% reporting “full” health on the EQ-5D (compared with 35% reported by Downing et al [32]) at 15 and 24 months, and 65–70% above the cut-off for reduced wellbeing throughout follow-up (Table 2).

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Fig 1. Participant status and questionnaire return rates up to 24 months of follow-up.

Number of questionnaires sent and returned at each time-point up to 24 months, with details of deaths and withdrawals throughout the study.

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Table 1. Socio-demographic, clinical and treatment characteristics of CREW participants.

https://doi.org/10.1371/journal.pone.0155434.t001

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Table 2. Quality of life, health status and personal wellbeing up to 2 years following surgery.

https://doi.org/10.1371/journal.pone.0155434.t002

Trajectories of quality of life, health status and personal wellbeing

Four trajectories of recovery from surgery to 2 years (Groups 1–4) were identified for each of the 3 outcome measures representing QoL (QLACS-GSS), health status (EQ-5D) and personal wellbeing (PWI) (S1 Table), and the estimated proportion of the CREW sample in each trajectory was obtained. For QLACS-GSS (similar pattern for all QLACS Part 2 subscales), where low scores indicate better QoL, Group 1 had consistently good QoL (below median baseline score for the whole CREW sample), (31.3%, 95% CI 26.8–35.8%); Group 2 had consistently average QoL (39.2%, 95% CI 34.4–43.9%); Group 3 had worsened QoL in the short-term (≤9 months) which then improved from 15 months, (24.2%, 95% CI 20.1–28.4%); Group 4 had consistently poor QoL, with scores well above the median baseline score (5.3%, 95% CI 3.4–7.3%); (Fig 2A).

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Fig 2.

Estimated trajectories for (a) QLACS-GSS (Generic Summary Score), (b) EQ-5D utility index and (c) Personal Wellbeing Index.

https://doi.org/10.1371/journal.pone.0155434.g002

For the EQ-5D utility index (Fig 2B), Group 1 began with some (mild) problems but improved by 15 months, reaching a mean score of 1 indicating “full” health (20.9%, 95% CI 16.5–25.3%); Group 2 had consistently good health status which declined slightly from 15 months (12.4%, 95% CI 8.7–16.1%); Group 3 showed consistent health problems over the 2 years (59.3%, 95% CI 54.9–63.6%); and Group 4 displayed fluctuating and the poorest health of the CREW participants (7.4% of CREW sample, 95% CI 4.8–10.0%). For some of the trajectories the change in EQ-5D utility score over time was greater than a published cut-off of 0.08 for a minimally important difference [33].

For the PWI (Fig 2C), Group 1 reported consistently good wellbeing throughout, with scores well above the 70–80 normal range (44.9%, 95% CI 39.1–50.7%); Group 2 had a mean PWI around 80 at baseline which declined to around 70 by 2 years (32.7%, 95% CI 27.5–37.8%); Group 3 showed declining levels of wellbeing which were consistently below the threshold of 70 for reduced wellbeing (18.2%, 95% CI 14.0–22.4%); and Group 4 had the poorest levels of wellbeing consistently <70 and which declined over the 2 years (4.2%, 95% CI 2.3–6.2%).

Across the three outcomes, 56.1% (454/809) were in the best trajectory (Group 1) and 10.7% (87/809) in the poorest trajectory (Group 4) for at least one of the outcome measures.

Baseline predictors of group membership

Frequencies of sociodemographic, clinical, treatment and psychosocial characteristics according to estimated trajectories for QoL, health status and wellbeing are shown in S2 Table. Lower self-efficacy and a higher level of depression before surgery were statistically significantly associated with poorer trajectories for all three outcome measures adjusting for other significant predictors (Table 3). For example, adjusted OR for QLACS-GSS Group 4 (poorest QoL) versus Group 1 (best QoL) for self-efficacy was 0.32 (95%CI 0.24–0.44, p<0.001), indicating a 68% reduced odds of being in Group 4 versus Group 1 with every unit increase in the score for self-efficacy. Adjusted ORs for self-efficacy for EQ-5D and PWI Group 4 versus Group 1 were 0.60 (0.45–0.81, p = 0.001) and 0.43 (0.31–0.59, p<0.001) respectively, indicating similarly large reductions in odds of being the poorest trajectory with increased self-efficacy. Similarly for depression, adjusted ORs for Group 4 versus Group 1 were 1.20 (1.12–1.28, p<0.001) for QLACS-GSS (indicating a 20% increased odds of being in Group 4 versus Group 1 for every unit increase in the score for depression), 1.13 (1.06–1.20, p<0.001) for EQ-5D and 1.14 (1.07–1.22, p<0.001) for PWI, all indicating a higher risk of being in the poorest trajectories for those with greater depression. The prevalence of clinically significant depression (CESD score ≥ 20) in Group 4 was 77.1% for QLACS-GSS, 66.0% for EQ-5D and 81.5% for PWI, although absolute numbers in this group were small.

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Table 3. Predictors of trajectory group membership for QLACS-GSS, EQ-5D and PWI: characteristics statistically significant in final multiple regression models for each outcome.

https://doi.org/10.1371/journal.pone.0155434.t003

Other factors found in the multiple regression to be statistically significantly associated with poorer trajectories for at least one of the outcomes were higher levels of anxiety, and presence of stoma (both QLACS-GSS and EQ-5D), lower social support (QLACS-GSS and PWI), female gender, greater deprivation, more co-morbidities, adjuvant treatment (EQ-5D), younger age, living alone, neo-adjuvant treatment (PWI); (Table 3). There were no statistically significant associations between trajectory group membership and tumour site, Duke’s stage, and positive and negative affect. Recurrence was examined and made only minor differences to the results of the trajectory analyses.

Discussion

This paper reveals for the first time that pre-surgery level of self-efficacy, i.e. confidence to manage illness-related problems, and depression predict recovery trajectories in all three outcomes of QoL, health status and wellbeing, independent of treatment or disease characteristics. This has significant implications for cancer management as self-efficacy can be enhanced by intervention, and depression may be better supported during the treatment phase to improve the recovery experiences of a significant proportion of colorectal cancer patients. Other important predictors of poor recovery include higher pre-surgery levels of anxiety, lower social support and stoma, which were each significant for two of the outcome domains. Older age was significantly associated with higher levels of wellbeing. This paper identifies who is most in need of intensive support from the point of surgery so resources can be directed accordingly.

Previous research has described the consequences of treatment for colorectal cancer [32] and attention is often focused on supporting recovery once treatment has finished. Self-efficacy has emerged as an independent predictor of recovery of QoL, health status and wellbeing, which suggests health and social care professionals should assess levels of self-efficacy from the point of diagnosis to identify those at risk of poorer recovery. Individuals reporting clinically significant levels of depression also need to receive adequate support to enhance their recovery experiences. The prevalence of depression at cancer diagnosis and its impact on recovery from cancer treatment is not well described. Most patients with depression do not receive potentially effective treatment for their depression [34]. Despite guidance (NICE, 2004 [35], NCCN 2015 [36], NHMRC 2003 [37]) that structured psychological assessment should be undertaken at key points in the individual’s pathway, there is little evidence that this is routinely carried out at diagnosis. Benefit has been demonstrated in managing anxiety and depression using formalised screening [38] and early identification of pre-disposing factors will be key to managing the impact of a cancer diagnosis. Early assessment and intervention to support those experiencing anxiety, depression and low self-efficacy may significantly improve the recovery experiences of those in the worst trajectories. Given that future services will be tailored to meet people’s needs following their treatment it is important that we consider how low self-efficacy and depression will be supported in practice and where barriers to support exist as the longer-term consequences for recovery may be compromised by poor support.

Interventions designed to enhance self-efficacy have been shown to be effective for people living with cancer and treatment-related problems [39]. Dunn and colleagues [12] describe the importance of social support, cancer threat appraisal and optimism in relation to long-term QoL and suggest interventions that target self-efficacy, although they did not measure self-efficacy in their study. Data from CREW provides the first prospective longitudinal data relating to the association between self-efficacy and QoL, health status and wellbeing in colorectal cancer and supports this suggestion. Failing to provide appropriate support to enable people to self-manage the consequences of cancer and its treatment may leave them feeling overburdened, lead to less self-management, greater inequalities, reduced access to services and poorer health and wellbeing [1].

In clinical practice, treatment- and disease-specific factors are frequently used as predictors of outcome, for example; co-morbidities [9, 4042] having a stoma [43] and symptoms experienced as a consequence of treatment [32]. We found no evidence for independent predictive effects of clinical factors including tumour site and disease stage, nor of personal affect. Assessment of outcomes representing QoL, health status and personal wellbeing in CREW provides a more detailed picture of overall recovery not captured by previous longitudinal studies [12, 32]. This paper demonstrates that it is important to assess psychosocial characteristics including self-efficacy, anxiety, depression and social support, and to do this early in the treatment pathway so that additional support can be offered.

Results of physical symptoms and functioning data that were collected in CREW from 3 months onwards (using EORTC QLQ-C30 [44] and QLQ-CR29 [45] questionnaires) will be presented separately, including the effect of these on overall quality of life. Additional analyses of other clinical outcomes in CREW including recurrence and survival will also be reported separately.

Study limitations

We set out to recruit all eligible colorectal cancer patients treated with curative intent surgery in 29 cancer centres over a specific period; 91% of all eligible participants were approached. Older patients and the very frail are underrepresented in the sample although there were a number of participants > 80 years. For a number of reasons, some baseline questionnaires were completed after surgery; whilst this maximises the proportion of eligible participants able to be included in CREW, this introduced some variation in baseline responses, and so all analyses were adjusted for time of response to baseline questionnaire. Whilst response rates were high at each time point there has been attrition as would be expected: 10% of the sample has actively withdrawn, 7% have had a recurrence and a similar proportion has died. Incomplete follow-up may have introduced some bias into the longitudinal analyses, although a sensitivity analysis including only the participants with all five completed questionnaires from baseline to 2 years produced similar results for the trajectories. One challenge for research of this type is continuing to engage those who no longer wish to be reminded about their cancer.

Implications / indications

Novel findings from this study raise important questions for transforming cancer management to identify those at risk of poor recovery before treatment begins and direct services to those most in need. Internationally, cancer care is rapidly changing with the aim of supporting individuals to self-manage. Integral to this are holistic needs assessments, care planning, treatment summaries, cancer care reviews and health and wellbeing events. These assessments and reviews generally focus on physical symptoms, treatment and clinical factors. Where psychological or social domains are examined a problem or need is often quantified, but a person’s capacity to manage is often not considered. The trajectories identified offer a clear opportunity to develop a stepped approach to care offering self-management support to enhance self-efficacy and those identified as having clinical depression, and likely to fare least well, being referred to specialist psychological services. One of the next steps in the research process will be to develop a screening tool based on the risk factors reported here, to identify those individuals at greatest risk of falling into the lower trajectories, irrespective of disease-specific parameters, and use this information to intervene to support them at an early stage in the pathway i.e. soon after diagnosis. This has the potential to revolutionise patient assessment and care-planning and enhance patient care.

Supporting Information

S1 Fig. Self-efficacy for Managing Chronic Disease 6-item Scale (Lorig et al 2001).

https://doi.org/10.1371/journal.pone.0155434.s001

(PDF)

S1 Table. Further results from trajectory models: criteria used to determine appropriate number of trajectories for each outcome.

https://doi.org/10.1371/journal.pone.0155434.s002

(PDF)

S2 Table. Frequencies of baseline socio-demographic, clinical, treatment and psycho-social characteristics according to estimated trajectories for QLACS-GSS, EQ-5D and PWI.

https://doi.org/10.1371/journal.pone.0155434.s003

(PDF)

Acknowledgments

We thank all CREW study participants, Carol Hill, Kerry Coleman and Bjoern Schukowsky (study administrators); Matthew Breckons, Cassandra Powers, Alex Recio-Saucedo, Bina Nausheen, Ikumi Okamoto (researchers); Jo Clough, Alison Farmer and Gaye Orr (research partners). Members of Study Advisory Committee: Jo Armes, Janis Baird, Andrew Bateman, Nick Beck, Graham Moon, Claire Hulme, Karen Poole, Susan Restorick-Banks, Paul Roderick, Claire Taylor, Jocelyn Walters, Fran Williams. The study was funded by Macmillan Cancer Support as part of the Macmillan Survivorship Research Group programme (Chief Investigator: CF). CF, KCS, JH, AD, CMM and LC were funded by the Macmillan Survivorship Research Group. DF was funded by the Macmillan Survivorship Research Group during recruitment for CREW and subsequently by University of Southampton. AR and PWS are funded by University of Southampton. JW is funded by University Hospital Southampton NHS Foundation Trust. JC is funded by University of Nottingham.

Recruiting centres (with Principal Investigators)

University Hospital of Wales, Cardiff (Rachel Hargest); Charing Cross Hospital, London (Penny Rogers); Croydon University Hospital, London (Muti Abulafi); Russells Hall Hospital, Dudley (Karen Kanyi); Ninewells Hospital, Dundee (Carol Baird); Royal Surrey County Hospital, Guildford (Angela Bates); Harrogate and District NHS Trust, Harrogate (Margaret Jennings); Hinchingbrooke Hospital, Huntingdon (Dr Cheryl Palmer); The Queen Elizabeth Hospital, Kings Lynn (Dr Athar Ahmad); Kingston Hospital, Kingston (Dr Sheela Rao); Macclesfield Hospital, Macclesfield (Catherine McBain); Borders General Hospital NHS Trust, Melrose (Melanie Tolson); Pinderfields Hospital, Wakefield (Rebecca Foster); Cumberland Infirmary, Cumbria (Jonathan Nicoll); The Royal Oldham Hospital, Oldham (Joanne Reed); North Manchester General Hospital, Pennine (Joanne Reed); The Shrewsbury and Telford Hospital NHS Trust, Shrewsbury (Marion Adams); Southampton General Hospital, Southampton (Dr Jane Winter); St Georges Hospital, London (Dr Fiona Lofts); (St Mark’s Hospital, Middlesex (Samia Sakuma); St Mary’s Hospital, London (Paula Studd); Tameside General Hospital, Ashton-Under-Lyne (Kamran Siddiqui); Royal Cornwall Hospital, Truro (Clare Ferris); University College London, London (Adoracion Jayme); West Middlesex University Hospital, Middlesex (Dr Rizvana Ahmad); New Cross Hospital, Wolverhampton (Vanda Carter); Worcester Royal Hospital, Worcester (Jayne Tyler); Wrexham Maelor Hospital, Wrexham (Alison Roberts); Yeovil Hospital, Yeovil (Sue Bulley).

Author Contributions

Conceived and designed the experiments: CF DF JC AR. Performed the experiments: CF KCS JW JH CMM PWS AD. Analyzed the data: JH. Wrote the paper: CF JH JW CG. Contributed to interpretation of data: JH PWS JW CG CF. Reviewed manuscript: CF JH JW CG KCS LB LC JC AD DF CMM AR PWS, Members of Study Advisory Committee.

References

  1. 1. Shippee ND, Shah ND, May CR, Mair FS, Montori VM. Cumulative complexity: a functional, patient-centered model of patient complexity can improve research and practice. J Clin Epidemiol. 2012;65:1041–51. pmid:22910536
  2. 2. Foster C, Breckons M, Cotterell P, Barbosa D, Calman L, Corner J, et al. Cancer survivors' self-efficacy to self-manage in the year following primary treatment. J Cancer Surviv. 2015;9(1):9–11.
  3. 3. Foster C, Fenlon D. Recovery and self-management support following primary cancer treatment. Br J Cancer. 2011;105:S21–S28. pmid:22048029
  4. 4. Howsepian BA, Merluzzi TV. Religious beliefs, social support, self-efficacy and adjustment to cancer. Psychooncology. 2009;18(10):1069–79. pmid:19189320
  5. 5. Mosher CE, Duhamel KN, Egert J, Smith MY. Self-efficacy for coping with cancer in a multiethnic sample of breast cancer patients: associations with barriers to pain management and distress. Clin J Pain. 2010;26(3):227–34. pmid:20173437
  6. 6. Shelby RA, Edmond SN, Wren AA, Keefe FJ, Peppercorn JM, Marcom PK, et al. Self-efficacy for coping with symptoms moderates the relationship between physical symptoms and well-being in breast cancer survivors taking adjuvant endocrine therapy. Support Care Cancer. 2014;22(10):2851–9. pmid:24821365
  7. 7. Jansen L, Herrmann A, Stegmaier C, Singer S, Brenner H, Arndt V. Health-related quality of life during the 10 years after diagnosis of colorectal cancer: a population-based study. J Clin Oncol. 2011;29(24):3263–9. pmid:21768465
  8. 8. Carlsson E, Berndtsson I, Hallén A-M, Lindholm E, Persson E. Concerns and quality of life before surgery and during the recovery period in patients with rectal cancer and an ostomy. J Wound Ostomy Continence Nurs. 2010;37(6):654–61. pmid:21052026
  9. 9. Gray NM, Hall SJ, Browne S, Macleod U, Mitchell E, Lee AJ, et al. Modifiable and fixed factors predicting quality of life in people with colorectal cancer. Br J Cancer. 2011;104:1697–703. pmid:21559017
  10. 10. Siassi M, Weiss M, Hohenberger W, Losel F, Matzel K. Personality rather than clinical variables determines quality of life after major colorectal surgery. Dis Colon Rectum. 2009;52:662–8. pmid:19404072
  11. 11. Pachler J, Wille-Jørgensen P. Quality of life after rectal resection for cancer, with or without permanent colostomy. (Review). The Cochrane Collaboration. 2012;12:1–54.
  12. 12. Dunn J, Ng SK, Holland J, Aitken J, Youl P, Baade PD, et al. Trajectories of psychological distress after colorectal cancer. Psychooncology. 2013;22:1759–65. pmid:23125004
  13. 13. Dunn J, Ng SK, Breitbart W, Aitken J, Youl P, Baade PD, et al. Health-related quality of life and life satisfaction in colorectal cancer survivors: trajectories of adjustment. Health Qual Life Outcomes. 2013;11:46. pmid:23497387
  14. 14. Fenlon D, Richardson A, Addington-Hall J, Smith P, Corner J, Winter J, et al. A cohort study of the recovery of health and wellbeing following colorectal cancer (CREW study): protocol paper. BMC Health Serv Res. 2012;12(90):1–8.
  15. 15. Fenlon D, Seymour KC, Okamoto I, Winter J, Richardson A, Addington-Hall J, et al. Lessons learnt recruiting to a multi-site UK cohort study to explore recovery of health and well-being after colorectal cancer (CREW study). BMC Med Res Methodol. 2013;13(153):1–13.
  16. 16. Office for National Statistics. Personal Well-being in the UK, 2013/2014. UK. (http://www.ons.gov.uk/ons/rel/wellbeing/measuring-national-well-being/personal-well-being-in-the-uk—2013-14/sb-personal-well-being-in-the-uk—2013-14.html)
  17. 17. Avis NE, Smith KW, McGraw S, Smith RG, Petronis VM, Carver CS. Assessing Quality of Life in Adult Cancer Survivors (QLACS). Qual Life Res. 2005;14:1007–23. pmid:16041897
  18. 18. Brooks R. EuroQoL: the current state of play. Health Policy. 1996;37:53–72. pmid:10158943
  19. 19. EuroQol Group. EuroQol—a new facility for the measurement of health-related quality of life. Health Policy. 1990;16(3):199–208. pmid:10109801
  20. 20. The International Wellbeing Group. Personal Wellbeing Index—Adult (PWI-A) 2013. 5th edition. Melbourne: The Australian Centre on Quality of Life, Deakin University. (http://www.deakin.edu.au/research/acqol/instruments/wellbeing-index/index.php)
  21. 21. Spielberger CD, Gorsuch R.L., Lushene R., Vagg P.R., Jacobs G.A. Manual for the State-Trait Anxiety Inventory (STAI). 1983. Palo Alto, CA: Consulting Psychologists Press.
  22. 22. Knight RG, Waalmanning HJ, Spears GF. Some norms and reliability data for the state trait anxiety inventory and the Zung self-rating depression scale. Brit J Clin Psychol. 1983;22(Nov):245–9.
  23. 23. Radloff LS. The CES-D Scale: A self-report depression scale for research in the general population. Appl Psychol Meas. 1977;1(3):385–401.
  24. 24. Katz MR, Kopek N, Waldron J, Devins GM, Tomlinson G. Screening for depression in head and neck cancer. Psychooncology. 2004;13(4):269–80. pmid:15054731
  25. 25. Thompson ER. Development and validation of an internationally reliable short-form of the Positive and Negative Affect Schedule (PANAS). J Cross Cult Psychol. 2007;38(2):227–42.
  26. 26. Lorig K, Sobel DS, Ritter PL, Laurent D, Hobbs M. Effect of a self-management program on patients with chronic disease. Eff Clin Pract. 2001;4(6):256–62. pmid:11769298
  27. 27. Sherbourne CD, Stewart AL. The MOS social support survey. Soc Sci Med. 1991;32(6):705–14. pmid:2035047
  28. 28. Jones BL, Nagin DS, Roeder K. A SAS procedure based on mixed models for estimating developmental trajectories. Sociol Methods Res. 2001;29(3):374–93.
  29. 29. Kass RE, Raftery AE. Bayes Factors. J Am Stat Assoc. 1995;90(430):773–95.
  30. 30. Schwarz G. Estimating the dimension of a model. Ann Stat. 1978;6(2):461–4.
  31. 31. Ashley L, Smith AB, Jones H, Velikova G, Wright P. Traditional and Rasch psychometric analyses of the Quality of Life in Adult Cancer Survivors (QLACS) questionnaire in shorter-term cancer survivors 15 months post-diagnosis. J Psychosom Res. 2014;77(4):322–9. pmid:25190179
  32. 32. Downing A, Morris E, Richards M, Corner J, Wright P, Sebag-Mortefiore D, et al. Health-related quality of life after colorectal cancer in England: A patient-reported outcomes study of individuals 12 to 36 months after diagnosis. J Clin Oncol. 2015;33(6):616–24. pmid:25559806
  33. 33. Pickard AS, Neary MP, Cella D. Estimation of minimally important differences in EQ-5D utility and VAS scores in cancer. Health Qual Life Outcomes. 2007;5:70. pmid:18154669
  34. 34. Walker J, Hansen CH, Martin P, Symeonides S, Ramessur R, Murray G, et al. Prevalence, associations, and adequacy of treatment of major depression in patients with cancer: a cross-sectional analysis of routinely collected clinical data. Lancet Psychiatry. 2014;1(5):343–50. pmid:26360998
  35. 35. National Institute for Health and Care Excellence (NICE) 2004. Improving supportive and palliative care for adults with cancer. London: NICE (https://www.nice.org.uk/guidance/csg4).
  36. 36. National Comprehensive Care Network (NCCN)–Clinical Practice Guidelines in Oncology: Survivorship version 2 2015 (http://www.nccn.org/professionals/physician_gls/pdf/survivorship.pdf).
  37. 37. National Health and Medical Research Council (HMRC)–Clinical practice guidelines for the psychosocial care of adults with cancer, 2003.
  38. 38. Butow P, Price MA, Shaw JM, Turner J, Clayton JM, Grimson P, et al. Clinical Pathway for the screening assessment and management of anxiety and depression in adult cancer patients: Australian guidelines. Psychooncology. 2015;24(0):987–1001.
  39. 39. Lev EL, Daley KM, Conner NE, Reith M, Fernandez C. An intervention to increase quality of life and self-care self-efficacy and decrease symptoms in breast cancer patients. Scholarly Inquiry for Nursing Practice: An International Journal. 2001;15(3):277–94.
  40. 40. Koroukian SM, Xu F, Bakaki PM, Diaz-Insua M, Towe TP, Owus C. Comorbidities, functional limitations, and geriatric syndromes in relation to treatment and survival patterns among elders with colorectal cancer. J Gerontol A Biol Sci Med Sci. 2010;65A(3):322–9.
  41. 41. Steginga SK, Lynch BM, Hawkes A, Dunn J, Aitken J. Antecedents of domain-specific quality of life after colorectal cancer. Psychooncology. 2009;18:216–20. pmid:18618899
  42. 42. Vissers PA, Thong MS, Pouwer F, Zanders MM, Coebergh JW, Poll-Franse LV. The impact of comorbidity on Health-Related Quality of Life among cancer survivors: analyses of data from the PROFILES registry. J Cancer Surviv. 2013;7:602–6013. pmid:23918453
  43. 43. Hornbrook MC, Wendel CS, Coons SJ, Grant M, Herrinton LJ, Mohler JM, et al. Complications among colorectal cancer survivors: SF-36 preference-weighted quality of life scores. Med Care. 2011;49(3):321–6. pmid:21224741
  44. 44. Aaronson NK, Ahmedzai S, Bergman B, Bullinger M, Cull A, Duez NJ, et al. The European Organization for Research and Treatment of Cancer QLQ-C30: a quality-of-life instrument for use in international clinical trials in oncology. J Natl Cancer Inst. 1993;85(5):365–76. pmid:8433390
  45. 45. Whistance RN, Conroy T, Chie W, Costantini A, Sezer O, Koller M, et al. Clinical and psychometric validation of the EORTC QLQ-CR29 questionnaire module to assess health-related quality of life in patients with colorectal cancer. Eur J Cancer. 2009;45(17):3017–26. pmid:19765978