ARTICLE

Quality of Life and Trial Adherence Among Participants in the Prostate, Lung, Colorectal, and Ovarian Cancer Screening Trial

Kathryn L. Taylor, Rebecca Shelby, Edward Gelmann, Colleen McGuire

Affiliation of authors: Lombardi Comprehensive Cancer Center, Georgetown University School of Medicine, Washington, DC

Correspondence to: Kathryn L. Taylor, PhD, Cancer Control Program, Lombardi Comprehensive Cancer Center, Georgetown University, 2233 Wisconsin Ave., NW, Ste. 317, Washington, DC 20007 (e-mail: taylorkl{at}georgetown.edu)


    ABSTRACT
 Top
 Notes
 Abstract
 Introduction
 Subjects and Methods
 Results
 Discussion
 References
 
Background: The National Cancer Institute's Prostate, Lung, Colorectal, and Ovarian (PLCO) Cancer Screening Trial was designed to examine whether annual screening tests for these four tumor sites result in reduced disease-related mortality. We assessed the impact of trial participation on both health-related quality of life (HRQL) and trial adherence. Methods: Participants (N = 432; 217 in the control arm and 215 in screening arm) were accrued from the Georgetown University PLCO site from May through December 1998. Screening-arm participants were interviewed by telephone at baseline (prescreening), shortly after notification of screening results (short-term follow-up), and 9 months after notification of screening results (intermediate-term follow up). Control-arm participants completed a baseline and 1-year follow-up assessment. Logistic regression analyses were conducted. Results: Participants reported high levels of HRQL and satisfaction with their decision to participate. Screening-arm participants with abnormal screening results had a higher level of intrusive thoughts about cancer than those with all normal results (odds ratio [OR] = 2.9, 95% confidence interval [CI] = 1.3 to 6.3) at the short-term follow-up but not at the intermediate-term follow-up (when abnormal test results were known to be false positive; OR = 1.9, 95% CI = 0.89 to 4.2). Trial adherence was statistically significantly better among participants who had received all normal results in the previous year's screening tests (93.7% versus 78.7%; OR = 3.7, CI = 1.1 to 12.0) than in those who received at least one abnormal result. In the control arm, adherence (defined as returning annual questionnaires) was positively associated with education (OR = 3.4, 95% CI = 1.4 to 8.4) and sex, with women being more likely to return questionnaires than men (OR = 2.1, 95% CI = 1.05 to 4.4). Conclusions: It is feasible to collect HRQL measures as part of a large cancer screening trial. Prior abnormal screening results were related to short-term HRQL but not to intermediate-term HRQL. Trial adherence was poorer among those who had received previous false-positive results. These results suggest several methods for improving adherence in this and other subgroups.



    INTRODUCTION
 Top
 Notes
 Abstract
 Introduction
 Subjects and Methods
 Results
 Discussion
 References
 
Health-related quality of life (HRQL), defined as physical, psychological, and social functioning, is recognized as an important outcome in randomized trials (15), particularly in clinical trials involving cancer patients (610) and in cancer prevention trials (1113). However, little is known about the outcomes of participants in cancer screening trials, particularly the impact of receiving false-positive results on both HRQL and trial adherence. We are aware of only one study that has examined HRQL in the context of a cancer screening trial (14), the European Randomized Screening for Prostate Cancer trial (ERSPC) (15). In this study, screening did not substantially raise general anxiety, nor was a false-positive screening result associated with an immediate reduction in general HRQL (14).

Outside the context of randomized trials, there is a large body of literature concerning the psychological impact of clinically based cancer screening, particularly the impact of false-positive results from mammography or cervical cancer screening (1625). Findings regarding the psychological impact of false-positive results have varied depending on the length of follow-up: cross-sectional studies have reported a negative psychological impact (22,26), whereas several longitudinal studies have reported no lasting adverse effects of false positives (20,23,25,2732). Additional longitudinal studies are needed to evaluate the HRQL benefits and limitations of cancer screening trials because the vast majority of individuals undergoing screening will never develop cancer yet are exposed to the potential risk of false-positive results.

Although there is a large body of literature on the demographic, medical, and psychological predictors of adherence to various clinical cancer screening regimens (3339), limited information is available about adherence outcomes within randomized screening studies. Two studies (40,41) have assessed demographic and medical predictors of adherence within the U.S. National Cancer Institute's (NCI) Prostate, Lung, Colorectal, and Ovarian (PLCO) Cancer Screening Trial, a large multisite trial designed to examine whether annual screening tests for these four cancers can reduce disease-related mortality (42). Nonadherence to lung screening was associated with false-positive screening results at the previous screening, current smoking, being African American, being female, and having a high school education or less (40). Nonadherence to flexible sigmoidoscopy screening for colorectal cancer was associated with being female, having had a prior technically inadequate flexible sigmoidoscopy result, and, among men, an abnormal (noncancerous) prior result (41). Thus, false-positive results have been associated with poorer adherence in the PLCO. This association may be related to the fact that many people who seek cancer screening are doing so to obtain peace of mind or reassurance about cancer (43), and receipt of a false-positive result does not immediately provide this outcome. Thus, concern over a false-positive result could affect trial adherence if participants opt to seek follow-up screening with their own physicians rather than remaining in the trial.

In contrast to the screening trial studies, clinically based breast screening studies have not reported an adverse impact of false positives on adherence (24,44) or on intentions to undergo screening (20,22). In fact, two studies reported improved adherence among women with a false-positive mammogram result (45,46). One possible explanation for this difference in the association between false positives and screening adherence in the PLCO versus in clinical settings may be that screening guidelines explicitly recommend breast and cervical cancer screening, compared with the uncertainty surrounding the PLCO cancer screening tests. Furthermore, it is possible that, in the clinical setting, physician recommendation plays a role in adherence, whereas physician recommendation is unlikely to play a role in continued PLCO participation.

In sum, few studies have assessed HRQL or screening adherence within the context of a randomized screening trial, and the findings from those that have differ from those from studies conducted within a clinical screening context. To address these issues, we conducted an ancillary study in the PLCO to assess the impact of trial participation, specifically the impact of abnormal results, on both HRQL and trial adherence among participants during their initial year of participation. Our study was intended to extend the literature in several ways. We have 1) conducted a longitudinal study that includes both general and cancer-specific measures of HRQL; 2) included both men and women, in contrast to previous studies; 3) assessed these variables in the context of screening for four different cancers; and 4) measured both HRQL and adherence within the same study, which allows for an evaluation of the impact of HRQL on trial adherence. We used a conceptual framework (47) developed to test HRQL and cost-effectiveness questions within the PLCO and ERSPC screening trials. This framework, which was designed to facilitate health policy decisions regarding screening, outlines the events that trial participants may experience, including randomization, screening, receipt of screening results, diagnostic workup, diagnosis, treatment, illness, and death. In this study, we assessed the impact of several of these events on HRQL and adherence and whether HRQL had a direct impact on trial adherence.

This study had three goals. First, we sought to determine the feasibility of collecting HRQL data within a large U.S. screening trial and of documenting the level of HRQL over the course of the initial year of participation. Second, we sought to assess HRQL with the Miller (47) framework, in terms of the impact of random assignment, and of the short-term (shortly after notification of results) and intermediate-term (approximately 9 months after notification of results) impact of receiving screening results (normal or abnormal). We predicted that having an abnormal screening result would be associated with poorer short- and intermediate-term quality-of-life outcomes. Third, we sought to assess predictors of adherence to the second round of screening exams in the screening arm and questionnaire completion in the control arm. In particular, we evaluated whether demographic-, HRQL-, or trial-related events predicted trial adherence at 1 year after enrollment. On the basis of the two previous studies of screening adherence within the PLCO (40,41), we predicted that having a false-positive result from the initial screening would be associated with poorer adherence at the second round of screening.


    SUBJECTS AND METHODS
 Top
 Notes
 Abstract
 Introduction
 Subjects and Methods
 Results
 Discussion
 References
 
Overview of the PLCO Cancer Screening Trial

The PLCO trial has been described elsewhere (48). Briefly, the PLCO is being conducted at 10 sites nationwide and includes 75 000 men and 75 000 women between the ages of 55 and 74. Study accrual began in 1993 and ended in 2001. Participants are being monitored for mortality outcomes and health information, and trial results are expected in approximately 5 years. PLCO exclusion criteria were as follows: having a history of prostate, lung, colon, rectum, or ovarian cancer; currently undergoing treatment for any cancer; having undergone surgical removal of the prostate, lung, ovary, or any part of the colon or rectum; currently taking finasteride or tamoxifen; having had a colonoscopy, flexible sigmoidoscopy, or barium enema within the past 3 years; current enrollment in another cancer screening or prevention study; being unwilling or unable to sign the consent form; and (for males) having had more than one prostate-specific antigen (PSA) test within the past 3 years. Eligible participants were randomly assigned to the control arm (and instructed to follow their normal health care routine) or to the intervention arm (and instructed to obtain annual digital rectal exam and PSA test for prostate cancer [men]; annual CA-125 blood test and transvaginal ultrasound for ovarian cancer [women]; chest x-ray for lung cancer in year 0 (baseline) through year 2 for nonsmokers and year 0 through year 3 for smokers; and flexible sigmoidoscopy for colorectal cancer in year 0 and year 5 [both sexes]).

After randomization, participants at the Georgetown University PLCO site were sent an informational packet containing group assignment (i.e., to control or intervention) and baseline questionnaires that assessed demographic and screening history variables. Participants in the intervention arm also received screening instructions and were instructed to complete the PLCO year 0 screening exams. Four to six weeks after their screening exams, participants were mailed the results along with any recommendations to seek necessary diagnostic exams. Participants in the control arm were instructed to complete the mailed annual study update, which assessed health status and new cancer diagnoses.

Procedure for the HRQL Study

Between May and December 1998, all PLCO participants who were randomized at the Georgetown University site (N = 483 of a total of 8111 patients randomized at this site over the entire recruitment period) were invited to participate in the HRQL ancillary study. Potential HRQL participants were mailed an introductory letter and a consent form; subsequently, trained interviewers attempted to contact all persons by telephone and completed a 15-minute baseline telephone assessment with those who agreed to participate. Signed consent forms were returned by mail. The Georgetown University Institutional Review Board and the PLCO Ancillary Studies Subcommittee provided study approval.

Figure 1 presents the points of assessment, the number of participants, and the number eligible at each assessment. We conducted two HRQL assessments with control-arm participants (baseline and 1-year follow-up) and three with the screening-arm participants (baseline, after notification of results, and 1-year post-baseline [which is 9 months post-results] follow-up). The baseline and post-results HRQL assessments were conducted via telephone interviews, and the 1-year assessment was done via mailed questionnaire. The baseline assessment was completed before the year 0 screening exams. The post-results assessment was completed an average of 17.9 days (standard deviation [SD] = 11.3 days) after the results were mailed from the Georgetown University PLCO office. All post-results HRQL assessments were conducted before the diagnostic workup, meaning that this assessment evaluated participants’ responses to having an abnormal screening result as opposed to a known false-positive result. The 1-year HRQL assessment was completed within 1.5 months (SD = 2.0) of the expected date of the year 1 screening exams and approximately 9 months after receipt of the year 0 screening results; thus, we refer to it as an intermediate-term HRQL assessment. Participants diagnosed with cancer were excluded from this HRQL assessment; consequently, it evaluated participants’ responses to having received a normal or abnormal (and known false positive) screening result 9 months earlier.



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Fig. 1. Assessments and response rates for the health-related quality of life (HRQL) study of the Georgetown University Prostate, Lung, Colorectal, and Ovarian (PLCO) ancillary HRQL study. At the year 1 assessment, we excluded those persons who had explicitly dropped out of the PLCO trial for the HRQL analyses but included them in the adherence analyses, resulting in different sample sizes for the HRQL and adherence analyses.

 
Measures

Demographic and medical information. In the baseline HRQL assessment, participants provided information about age, marital status, educational level, ethnicity, employment status, and personal and family history of cancer, including the number of first-degree relatives with cancer.

HRQL. We used the SF-12 Physical and Mental Component Scales (49) to determine participants’ HRQL at each assessment. The SF-12 scale is a generic measure of health status that was designed to be a shorter alternative to the SF-36 (50). The test–retest reliability coefficient is 0.89 for the Physical Component Scale (PCS) and 0.76 for the Mental Component Scale (MCS) (49). Alpha reliability cannot be calculated for the SF-12 due to the heterogeneity of the items (49). Scores on the SF-12 are standardized (i.e., mean = 50 and SD = 10) (50), with a higher score indicating better HRQL.

Cancer-specific distress. We included four items from the seven-item Intrusion Subscale of the Impact of Events Scale (IES) to assess cancer-specific distress ("your thoughts about cancer") at each assessment (51). To reduce respondent burden, we selected the four items with the highest item–total correlation (51). The items were: 1) "I thought about cancer when I did not mean to"; 2) "I had waves of strong feelings about cancer"; 3) "Other things kept making me think about cancer"; and 4) "Any reminder brought up feelings about cancer." The internal consistency of these four items was 0.85 at the baseline assessment. Respondents indicated how frequently each was true over the past 7 days, using a four-point Likert scale ("not at all" to "often"). Because the Intrusion Subscale was highly skewed in this sample, it was dichotomized at the median (the median subscale score was 1.0).

Satisfaction with the decision to participate in the PLCO trial. The Satisfaction with Decision (SWD) scale (52) is a widely used six-item scale in which the particular decision under investigation is modified, depending on the study. We used the SWD to measure participants’ satisfaction with their decision to enroll in the PLCO trial. This scale had very good reliability (Cronbach's {alpha} = 0.88 at baseline). Items were rated on a five-point scale (1 = strongly disagree to 5 = strongly agree) and were scored so that a higher score indicates greater satisfaction with the decision to participate in the PLCO trial. Satisfaction was measured at each assessment.

Screening result at the baseline screening exam. For each of the four cancers, the PLCO classified the year 0 (baseline) screening result as follows: normal; abnormal, not suspicious for cancer; abnormal, suspicious for cancer; or inadequate screen. Because we were interested in the impact of an abnormal result on HRQL and adherence, we dichotomized the result categories into "abnormal, suspicious for cancer" versus the other three categories combined. There were no statistically significant HRQL or adherence differences between the normal and the abnormal, not suspicious for cancer categories (data not shown). Participants were divided into two groups: those who received an abnormal result on one or more of the exams and those whose exams were all normal.

Trial adherence. Participants were considered adherent 1 year following enrollment (year 1) if they had completed all three of the required screening exams (blood test, chest x-ray, and prostate or ovarian exam, for participants in the intervention arm) or if they returned the completed annual questionnaire (for participants in the control arm). Because adherence was therefore defined differently in the two study arms, adherence could not be compared directly within the same analysis.

Statistical Analysis

The data analyses were conducted in five steps. First, we conducted descriptive analyses of the medical and demographic characteristics and of the HRQL outcome variables. Second, for the short-term and intermediate-term HRQL outcomes (SF-12 and IES) in the screening arm, we conducted chi-square analyses to identify the bivariate associations between the demographic variables and the outcome variables. We did not include marital status, ethnicity, or personal history of cancer in the bivariate or multivariate analyses because the cell sizes became prohibitively small once the variables were stratified by trial arm and result status. Third, we included all potential predictor variables (age, educational level, gender, first-degree relative with cancer, screening result status) in a series of hierarchical logistic regression analyses to identify the independent predictors of HRQL within the screening arm. (Logistic regression was used in the HRQL analyses because the outcome variables were not normally distributed.) Fourth, we conducted chi-square analyses to determine the bivariate associations between demographic variables and trial adherence within each arm. Finally, we conducted logistic regression analyses predicting adherence at year 1 for each trial arm separately and included all of the possible predictor variables in the model. All tests of statistical significance were two-sided, and a P value of less than .05 was used to establish statistical significance.

For tests of the impact of screening results on psychosocial variables (IES, PCS, MCS), our screening sample size at short-term follow-up (n = 166) and intermediate-term follow-up (n = 149) had 80% power with a two-tailed {alpha} of .05 to detect a response probability yielding an odds ratio of 1.6. For tests examining predictors of adherence, our sample size of screening participants (N = 171) had 80% power with a two-tailed {alpha} of .05 to detect a response probability yielding an odds ratio of 1.8, and our sample size of control participants (n = 210) had 80% power with a two-tailed {alpha} of .05 to detect the response probability yielding an odds ratio of 1.6.


    RESULTS
 Top
 Notes
 Abstract
 Introduction
 Subjects and Methods
 Results
 Discussion
 References
 
Baseline Participation Rate

Of the 483 PLCO participants we invited to participate in the HRQL study, 20 were ineligible (five did not speak English, 14 dropped out of the PLCO trial, and one died before the baseline assessment). Of the remaining 463 participants, 11 (2.4%) declined to participate, seven (1.5%) completed the baseline screening exams before being contacted for the HRQL study, and 13 (2.8%) could not be reached (even after ≥10 call attempts). The remaining 432 (93.3% participation rate) completed the baseline assessment (n = 215 screening, n = 217 control).

Follow-up Participation Rates

Of the 215 screening-arm participants, 27 (12.6%) did not complete any of the baseline screening exams, and five (2.3%) dropped out of the PLCO trial due to illness or because they moved from the area. Participants who dropped out of the PLCO trial could not be included in the analyses involving HRQL outcomes because the relevant data could not be collected, although they were included in the calculation of year 1 adherence rates. These exclusions left 183 (85.1%) participants who completed the baseline screening exams and were thus eligible to continue in the HRQL study. Of these, 176 (96.2%) completed both the baseline and short-term assessments, and of those, 10 (5.7%) were subsequently excluded due to a cancer diagnosis. Thus, 166 (90.7%) of 183 screening-arm participants were eligible for analyses involving the short-term HRQL outcomes. Of these 166 participants, 149 (89.8%) completed all three assessments and were therefore included in the intermediate-term HRQL analyses.

In the control arm, of the 217 participants who completed a baseline HRQL assessment, six were diagnosed with cancer by the 1-year assessment, leaving 211 participants who were eligible for the adherence analyses. An additional eight had dropped out of the PLCO trial by the 1-year assessment, leaving 203 participants who were eligible for the HRQL analyses. The 1-year assessment in the HRQL ancillary study was completed by 179 of 203 participants (88.2%).

We compared the HRQL dropout rates between the two trial arms at the 1-year HRQL assessment (Fig. 1). The 88.2% (179 of 203) control-arm participation rate at 1 year did not differ statistically from the 90.1% (163 of 181) screening-arm participation rate at 1 year ({chi}2 [1, N = 384] = 0.39, P = .53). (The N value for the screening arm includes those who completed the 1-year HRQL assessment, regardless of their participation in the other two assessments; the analyses that required complete data at all three assessments therefore include a smaller number of screening-arm participants.)

Screening Results at Year 0

Of the 166 screening-arm participants who were eligible for analyses of the short-term HRQL outcomes, 61 (36.7%) had normal screening results on all exams, and 105 (63.3%) had at least one abnormal screening result. Of the 149 participants who were eligible for the analyses involving the intermediate-term HRQL outcomes, 58 (38.9%) had normal screening results on all year 0 exams, and 91 (61.1%) had at least one abnormal screening result at year 0. The majority of the abnormal results were due to abnormal flexible sigmoidoscopy results. For example, of the 105 participants with an abnormal exam who were included in the short-term HRQL analyses, 79 (75.2%) of 105 had an abnormal flexible sigmoidoscopy exam, 17 (16.2%) of 105 had an abnormal flexible sigmoidoscopy exam in addition to one or two other abnormal exams, and nine (8.6%) of 105 had an abnormal exam other than flexible sigmoidoscopy.

Demographic and Medical Characteristics

Overall, the population included in this study was well educated and largely white, with a high percentage reporting a family history of cancer (Table 1). Compared with the women, the men reported a higher educational level, were more likely to be married, and were less likely to have a personal or family history of cancer. There were no differences between the screening arm and control arm for any medical or demographic variables.


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Table 1. Demographic and medical characteristics of participants in the Georgetown University PLCO Ancillary HRQL Study Stratified by Sex*

 
Impact of Random Assignment

Random assignment did not have a substantial negative impact on control participants’ baseline HRQL. The only difference between trial arms was a higher baseline HRQL on the SF-12 MCS among control participants [t(398) = –2.7; P = .01]. There were no other differences between arms on the other HRQL variables (i.e., the PCS, the IES scale, or the SWD scale [i.e., about the decision to participate in the PLCO trial]).

Quality of Life and Satisfaction During the Initial Year of PLCO Participation

Table 2 presents descriptive information for the HRQL and satisfaction measures. Participants reported statistically significantly higher baseline levels of mental and physical functioning compared with age-matched SF-12 US general population norms (49). We computed a series of unequal-variance two-sample t tests (Welch's t test), using the mean, standard deviation, and sample size from the SF-12 manual (49); in each case, the current sample reported better quality of life than the general population. For example, 55- to 64-year-olds in the screening arm reported statistically significantly higher scores on the SF-12 MCS [t(229.5) = 2.5; P = .01] and on the PCS [t(262.4) = 5.8; P<.001] compared with the same age group in the general population standardization sample. In addition, participants reported a low level of intrusive thoughts about cancer and high satisfaction with the decision to participate in the PLCO (Table 2).


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Table 2. Means and standard deviations of HRQL and satisfaction measures of participants in the Georgetown University PLCO Ancillary HRQL Study by screening test result status*

 
Impact of the Screening Result on the HRQL Outcomes

Short-term outcomes. We assessed the short-term impact of the year 0 screening results (all normal versus one or more abnormal) with the scores on the IES and the SF-12 PCS and MCS as the outcome variables. We first conducted chi-square analyses to assess the relationship between the predictor variables and the outcome variables (Table 3). For the IES outcome, bivariate analyses revealed that women ({chi}2 [1, N = 166] = 4.2; P = .04), participants with a first-degree relative with cancer ({chi}2 [1, N = 166] = 6.7; P = .01), and participants with an abnormal screening result ({chi}2 [1, N = 166] = 7.3; P = .007) all reported a higher level of intrusive thoughts about cancer than men, participants without a first-degree relative with cancer, and participants with normal screening results, respectively. For the MCS outcome, bivariate analyses revealed poorer mental functioning among women ({chi}2 [1, N = 166] = 4.2; P = .041) than among men. The differences in mental functioning in younger participants compared with that of older participants ({chi}2 [1, N = 166] = 2.9; P = .09) and in participants with all normal results as compared with participants with at least one abnormal result ({chi}2 [1, N = 166] = 2.8; P = .09) were not statistically significant by conventional hypothesis testing. No statistically significant relationships between the predictor variables and the PCS outcome emerged from the bivariate analyses (Table 3).


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Table 3. Bivariate analyses for HRQL outcomes within the screening arm of the Georgetown University PLCO Ancillary HRQL Study*

 
Next, we used logistic regression to identify independent predictors of the IES score. Controlling for baseline IES and potential confounding variables (Table 4), we found that participants who received an abnormal screening result reported a higher level of intrusive thoughts about cancer on the IES than those who received all normal results (odds ratio [OR] = 2.9, 95% confidence interval [CI] = 1.3 to 6.3). There were no statistically significant interactions between result status and the other variables in the model (all P>.10). Result status was not statistically significantly associated with the MCS and PCS outcomes in the logistic regression model (Table 4).


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Table 4. Logistic regression analysis predicting short-term HRQL in the screening arm of the Georgetown University PLCO Ancillary HRQL Study (n = 166)*

 
Intermediate-term outcomes. For the IES outcome, bivariate analyses (Table 3) revealed an association with result status, such that participants with a false-positive result on a screening test reported a higher level of intrusive thoughts ({chi}2 [1, N = 149] = 4.6; P = .03) than those with all normal results. Poorer quality of life (i.e., lower score on the MCS) was associated with younger age ({chi}2 [1, N = 146] = 7.9; P = .005) and with having a first-degree relative with cancer ({chi}2 [1, N = 146] = 5.7; P = .02). There were no statistically significant bivariate associations between any predictor variables and the intermediate-term PCS outcome (Table 3).

In the logistic regression model for the IES score (Table 5), result status was not a statistically significant predictor (P = .096; OR = 1.9, 95% CI = 0.89 to 4.2), indicating that the effect of result status on the IES had dissipated since the short-term assessment. In the logistic models for intermediate-term MCS and PCS outcomes, result status was not associated with either of the outcomes (Table 5). As shown in Table 5, older persons reported better HRQL on the MCS than younger persons, and those with a first-degree relative with cancer reported better HRQL on the PCS compared with those without a first-degree relative without cancer.


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Table 5. Logistic regression analysis predicting intermediate-term HRQL in the screening arm of the Georgetown University PLCO Ancillary HRQL Study*

 
Trial Adherence at Year 1

For the adherence analyses, we excluded participants who had been diagnosed with cancer (n = 10 in the screening arm, n = 6 in the control arm), who were too ill to complete the screening exams (n = 4), or who had moved away (n = 4). Participants who had not completed the baseline screening exams (n = 27) were included in the adherence rate calculation for the screening arm because they were still eligible for the second round of screening and had been contacted by the PLCO office to complete the exams. However, those who had not completed the year 0 baseline screening exams were excluded from the logistic models because we sought to assess the role of the year 0 screening result (abnormal versus normal) in adherence to the year 1 screening exams.

In the control arm, 78.7% (166 of 211) of the participants completed the annual PLCO questionnaire. Chi-square analyses (Table 6) indicated that individuals with a higher level of education were more likely to be adherent ({chi}2 = 7.3 [1, N = 210]; P = .03). Adherent individuals did not differ from nonadherent individuals in the likelihood of having intrusive thoughts on the IES ({chi}2 = 3.2 [1, N = 211]; P = .08).


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Table 6. Bivariate analyses of year 1 adherence in the Georgetown University PLCO Ancillary HRQL Study*

 
The logistic regression analysis (Table 7) revealed that education was positively associated with adherence in the control arm; participants with a graduate degree (OR = 3.4, 95% CI = 1.4 to 8.4) were more likely to complete the questionnaire than those with some college education or less. A similar but not statistically significant association was seen in those with a college degree compared with those with some college education or less (OR = 2.3, 95% CI = 0.98 to 5.2). Participants with greater cancer-related distress were less likely to be adherent than those with lower distress (OR = 0.54, 95% CI = 0.26 to 1.1), but the difference was not statistically significant (P = .09). Sex was related to adherence, with women being more likely than men to return questionnaires (OR = 2.1, 95% CI = 1.05 to 4.4). There were no statistically significant interactions among the predictors.


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Table 7. Logistic regression analysis predicting year 1 adherence in the control arm of the Georgetown University PLCO Ancillary HRQL Study (n = 210)*

 
In the screening arm, 76.6% (151 of 197) of those eligible for screening were adherent, defined as completing all three exams required at the year 1 screening. The chi-square analyses (Table 6), which included only the 171 participants who had a year 0 baseline screening exam, indicated that, compared with nonadherent participants, adherent participants were younger ({chi}2 [1, N = 171] = 5.9; P = .02), had higher education ({chi}2 [1, N = 171] = 6.6; P = .04), did not have a first-degree relative with cancer ({chi}2 [1, N = 171] = 3.9; P = .05), and had negative results on all of the year 0 screening exams ({chi}2 [1, N = 171] = 6.7; P = .01). The baseline PCS score was not statistically significantly related to adherence ({chi}2 [1, N = 171] = 3.7; P = .06), and the IES and the MCS scores were not related to adherence.

In the logistic regression model (Table 8), adherence at year 1 was statistically significantly better among participants who had received all normal results (i.e., no false-positive results) at the year 0 screening (OR = 3.7, CI = 1.1 to 12.0) than among those who had received at least one abnormal result. There were no other statistically significant main effects and no statistically significant interactions between result status and the other variables in the model (gender, age, educational level, first-degree relative with cancer, and baseline PCS score; all P>.20).


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Table 8. Logistic regression analysis predicting year 1 adherence for screening arm of the Georgetown University PLCO Ancillary HRQL Study (n = 171)*

 

    DISCUSSION
 Top
 Notes
 Abstract
 Introduction
 Subjects and Methods
 Results
 Discussion
 References
 
This study is one of the first, to our knowledge, to demonstrate the feasibility of collecting data on HRQL and related measures as part of a cancer screening trial. Further, we have demonstrated the impact that abnormal results can have on both HRQL and trial adherence. Participants who received abnormal baseline screening results reported a higher level of intrusive thoughts about cancer shortly following receipt of the results, although this relationship was no longer statistically significant at the intermediate-term follow-up assessment, when abnormal results among remaining participants were known to be false positive. Adherence to the second round of screening tests was statistically significantly lower among participants who had received false-positive results at the previous year's screening. In the control arm, adherence (returning the annual questionnaire) was higher among those with more education and among women and was lower among those with cancer-related distress, although that association was not statistically significant. Taken together, these results suggest that receipt of an abnormal result may only temporarily heighten cancer-related distress but may negatively affect trial adherence at the subsequent annual screening exams. An important question for future research is whether receipt of false-positive results in the subsequent screening years will negatively affect trial adherence in an additive fashion.

The high participation and retention rates in our study demonstrated that participants were willing to enroll and complete a series of telephone assessments and a mailed questionnaire concerning HRQL. These participation rates corroborate those found in cancer treatment trials (610) and cancer prevention trials (1113). In addition, as is typical of healthy individuals who are participating in medical research, subjects reported a favorable quality of life, with the means for the MCS and PCS subscales of the SF-12 virtually identical to those in the ERPSC screening trial (14).

We also found that random assignment did not have a statistically significant impact on HRQL. Participants in the control arm did not report less satisfaction with trial participation or poorer HRQL at the baseline assessment than participants in the screening arm. This outcome suggests that random assignment may not have negative implications for participants or for the trial itself. The high level of satisfaction with participation was similar to that reported by another study of PLCO participants (53). Our results also indicate that an abnormal screening result had negative implications for short-term but not intermediate-term cancer-related distress. These findings are consistent with those of a number of prior studies. For example, a false-positive screening result has been associated with poorer short-term cancer-related HRQL (32,54) but not with short-term general HRQL (14,32). The intermediate-term outcomes in our study are consistent with those of a number of longitudinal clinically based screening studies (20,23,25,2732) that found no lasting relationship between false-positive results and general HRQL.

One of the most commonly expressed reasons for undergoing cancer screening is to seek peace of mind about cancer (5557). The lack of immediate reassurance for participants who receive abnormal results may explain the increased cancer-related distress in this group at the post-results (i.e., short term) assessment. One implication of this finding is that, on enrollment, participants in screening trials need to be clearly informed that they may or may not achieve peace of mind about cancer from participating in the trial because of the substantial possibility of obtaining an abnormal result. Presenting this information in a consent form is not likely to be sufficient for the information to be fully understood; a better understanding would likely require that additional information detailing the benefits and limitations of trial participation be included with the introductory materials. In addition, after receiving an abnormal screening result, participants may benefit from additional attention from trial staff both to encourage completion of follow-up diagnostic exams and to allay concerns that may exist about continued participation in the trial. For example, participants with an abnormal result might think that if they have cancer, they would be more comfortable if monitored closely by a personal doctor rather than remaining in the trial.

We found that, consistent with the two previous studies of screening adherence within the PLCO (40,41), false-positive screening results at baseline were associated with poorer trial adherence 1 year later. A possible explanation for this finding is if, for example, participants with abnormal results become more vigilant and/or more anxious about cancer screening and therefore leave the trial to seek regular screening with their own physician, as noted above. Conversely, those whose screening results were all normal may have received positive reinforcement for their trial participation (i.e., reassurance that they did not have cancer) and were therefore likely to continue their participation. Finally, adherence in the screening arm could be affected by the test losing credibility due to an inadequate prior screen. Indeed, Weissfeld (41) reported that having had a technically inadequate prior screening was associated with poorer adherence.

Our results suggest several potential interventions that may improve adherence among screening trial participants. One straightforward solution would be to make proactive phone calls to the less adherent subgroups of participants to remind them about the upcoming screening and to make an appointment with them rather than relying on participants to make their own appointments. In addition, it may be beneficial to target persons with poorer physical functioning, as it is conceivable that their health problems may take precedence over trial participation and that they may perceive PLCO participation as less important. Thus, they may require additional resources to improve their trial adherence. Similarly, printed educational materials that address the meaning of an abnormal test result, the importance of following through with the recommended diagnostic workup, and the need for continued trial participation may improve adherence among participants with abnormal screening results (58). Among control participants, phone calls or letters to men and to those with less education who do not return their questionnaires by a particular date may improve the rate of questionnaire completion. In addition, conducting the questionnaire by phone with those who do not return the questionnaire by mail would substantially improve the completion rates. Enhanced efforts that are focused on particular subgroups may improve overall adherence rates in a cost-efficient manner, as has been discussed in several reviews of the behavioral and logistic issues that are important to trial adherence (5861). Maintaining high rates of completion of the annual questionnaires is essential to adequately track cancer incidence and use of screening tests in both the screening and control arms.

Our study has several limitations that should be considered in evaluating the results. One is the homogeneity of the sample: Participants were largely white, highly educated, and in good mental and physical health. Thus, although this sample was representative of the 8111 PLCO participants accrued at the Georgetown site and is similar to the participants who typically enroll in other cancer screening and prevention trials, the results cannot necessarily be generalized to other populations. Another limitation was that we were unable to evaluate the association between an abnormal screening result and subsequent adherence to the same test because the majority of abnormal exams were flexible sigmoidoscopies, and that exam was not one of the three required at the year 1 screening. It is possible that different relationships with adherence would have emerged if the abnormal result was linked with adherence to the same screening test. However, the results do provide a strong test of the association between abnormal results and adherence, given that we found that an abnormal sigmoidoscopy result was associated with poorer adherence with three different tests at year 1 (blood test, chest x-ray, and prostate or ovarian exams).

In conclusion, this study has confirmed the feasibility of collecting HRQL data in a cancer screening trial. It has also provided insights about the impact of cancer screening results on HRQL and screening adherence within a large cancer screening trial. This information is important from the standpoint of understanding the impact of trial participation and cancer screening on HRQL and adherence. This knowledge will be particularly important if the data from the PLCO trial do not provide definitive evidence for or against screening, because individuals will need to continue to make an informed, personal decision about whether to undergo screening for these four cancers, which may include weighing the impact of screening on quality of life. Finally, these findings revealed subgroups of participants who were less likely to adhere to screening or to questionnaire completion at the year 1 follow-up, including those who previously had a false-positive screening result. Providing additional attention to these subgroups may serve to improve adherence in a cost-efficient manner. Future research needs to address the potential of such interventions as well as the impact of receiving repeated false-positive screening results on long-term HRQL and trial adherence. As is now the case in cancer treatment and cancer prevention trials, we contend that the assessment of HRQL and the evaluation of behavioral and psychological predictors of trial adherence should also become standard in cancer screening trials.


    NOTES
 Top
 Notes
 Abstract
 Introduction
 Subjects and Methods
 Results
 Discussion
 References
 
Supported by the National Cancer Institute (K07 CA 72645 (KT) and NCI funding for a PLCO ancillary study (N01-CN-25522) (KT, EG).

Present address: R. Shelby, The Ohio State University, Columbus.


    REFERENCES
 Top
 Notes
 Abstract
 Introduction
 Subjects and Methods
 Results
 Discussion
 References
 

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Manuscript received September 26, 2003; revised May 18, 2004; accepted May 25, 2004.


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