Abstract
Purpose:
This study aimed to characterize physical activity (PA) and sedentary behavior (SB) profiles in older gastrointestinal (GI) cancer survivors, assess their interest in interventions to modify these behaviors, and evaluate the acceptability of digital tools for delivering interventions to modify these behaviors.
Methods:
Survivors (M = 65 years) from an outpatient survivorship clinic at the Penn State Cancer Institute completed a questionnaire during a clinic appointment.
Results:
Most survivors failed to attain the recommended level of PA (79%) or exceeded an average of 8 hours of daily SB (42%). Access to internet and text messaging capabilities were high (70%), yet few survivors had access to smartphones or tablets (<40%) or reported interest in using digital tools to improve PA or reduce SB (<30%). Digital PA and SB interventions were more acceptable to younger survivors, survivors reporting more SB and survivors engaging in more PA. The monetary value ascribed to digital health interventions did not differ as a function of mode of delivery (i.e. text messages, web, email, tablet computer apps or smartphone apps).
Conclusions:
Older GI cancer survivors can benefit from interventions to increase PA and decrease SB. Interest in such interventions was moderate and the acceptability of digital health tools for these interventions was limited. At the present time, behavioral interventions for older GI cancer survivors should not be delivered exclusively through digital tools and strategies to improve adoption of various technologies should be implemented when using these tools to modify PA and SB.
Keywords: Lifestyle, Survivorship, Needs Assessment, Mobile Health
Over one million gastrointestinal (GI) cancer survivors live in the United States and an estimated 230,000 new cases will be diagnosed in 2017 [1–3]. Physical activity (PA) reduces risk for many GI cancers, and can improve a variety of survivorship and aging outcomes [4,5]. Although less widely-investigated, excessive sedentary behavior (SB) has emerged as an independent risk factor for some forms of cancer that may also compromise survivorship and aging outcomes [6]. Most of the available evidence about these health behaviors (and interventions to modify them) has focused on samples of breast and colorectal cancer survivors. Less is known about these behaviors in older survivors with a variety of GI cancers. This study assessed the normative need for interventions to promote PA or limit SB among older survivors of GI cancers.
Regular PA following cancer treatment is safe, can improve survival rates and positively impacts a variety of physical and psychological survivorship outcomes including quality of life (QoL), anxiety, fatigue, pain and emotional well-being [5,7–10]. Limiting SB (i.e., sitting) is emerging as another important component of cancer survivorship because it also appears to be associated with improved QoL and reduced mortality for survivors [8,11].
A number of PA and SB interventions exist but access to those supports is limited for many older survivors who live in rural areas without specialty care [12]. Digital interventions for lifestyle behavior change show promise for increasing PA in cancer survivors and represent a potential solution for reaching survivors without access to specialty care [13]. Interest in digital interventions among cancer survivors is generally positive, with a recent study finding 97% of survivors expressed interest in mobile and internet technologies [14]. Yet technology adoption rates are limited among older adults so it is not clear whether older cancer survivors would accept digital tools for modifying activity-related behaviors [15]. The purpose of this study was to characterize PA and SB profiles in older GI cancer survivors, assess interest in interventions to modify these behaviors, and evaluate the acceptability of digital tools for modifying these behaviors.
Methods
Participants
Informed consent was obtained from all individual participants included in the study. Participants were recruited from an outpatient survivorship clinic at the Penn State Cancer Institute, a tertiary care center serving a largely rural, 28-county catchment area. A research assistant recruited eligible survivors individually after the survivor completed check in for a post-treatment follow-up care visit.
Participants completed Research Electronic Data Capture (REDCap) surveys on a tablet computer in the waiting or examination room while waiting for the oncologist. Study data were collected on tablet computers and managed using REDCap electronic data capture tools hosted at the Penn State Milton S. Hershey Medical Center and College of Medicine. REDCap is a secure, web-based application designed to support data capture for research studies [16].
Measures
Demographic information was collected via nine questions assessing race, ethnicity, employment status, marital status, parental status, family income and education level. Medical histories included both cancer-specific (e.g., type of cancer, time of diagnosis, type of treatment, time since treatment completion) and other health characteristics (e.g., comorbid chronic diseases, smoking).
PA and SB were recalled for the past seven days using the International Physical Activity Questionnaire-Short form (IPAQ-short) [17]. Participants reported the frequency and average daily duration of vigorous-intensity PA, moderate-intensity PA, and walking over the past 7 days. Responses at each intensity were weighted by intensity and summed to estimate PA volume. A separate score was calculated for moderate and vigorous intensity PA to determine whether participants met national PA guidelines. Survivors also reported the average duration of daily SB (i.e., time spent sitting) on weekdays and weekend days. Responses were weighted and summed to estimate average daily SB sitting time. Survivors also reported how many days they spent 8+ waking hours seated or reclined (a level of SB associated with elevated health risks) [18,19].
Impact of cancer diagnosis on survivors’ ability to engage in moderate–to-vigorous intensity PA was assessed with one question rated on a scale ranging from 0 (strongly disagree) to 100 (strongly agree). Motivation to participate in PA and limit SB was assessed by asking survivors to report the number of days they lacked motivation to engage in each behavior. Interest in future PA and SB interventions was measured with two questions; survivors reported either that they would or would not sign up for each intervention.
Finally, the acceptability of digital tools was measured with questions about access to different technologies (i.e., internet, smartphone, text messaging), whether survivors would use a digital tool to promote PA or limit SB, and the perceived value of potential digital tools used to modify those behaviors (i.e., email, web page, tablet or smartphone app, text messaging).
Data Analysis
Descriptive statistics were estimated for participants’ demographic characteristics and medical histories. Bivariate correlations estimated relations between scores. Paired t-tests were used to test for differences in the monetary value of the various digital health tools.
Results
The sample comprised male (57%) and female (43%) survivors of pancreatic (29%), colorectal (27%), esophagogastric (22%), and hepatobiliary (21%) cancers. Survivors ranged from 32 to 91 years with a mean age of 64.9 years (SD = 11.1). Over 70% were aged 60 or older, and 75% had children. The sample was almost exclusively Caucasian (95%) and not Hispanic/Latino (99%). Table 1 summarizes additional demographic characteristics for the sample. Approximately 70% of the sample reported having both internet access at home and the capacity to receive text messages on their phone. Yet few had access to smartphones (39%) or tablet computers (22%).
Table 1.
Participant demographic characteristics and medical histories
| N | % | ||
|---|---|---|---|
| Marital Status | |||
| Married or domestic partner | 94 | 62.7 | |
| Divorced | 24 | 16 | |
| Widowed | 23 | 15.3 | |
| Never married, single | 6 | 4 | |
| Separated | 3 | 2 | |
| Employment Status | |||
| Retired | 73 | 48.7 | |
| Full-time | 34 | 22.7 | |
| Part-time | 11 | 7.3 | |
| Unemployed | 32 | 21.3 | |
| Household Income | |||
| <$50K | 43 | 28.6 | |
| $50K-$150K | 49 | 32.7 | |
| >$150K | 5 | 3.3 | |
| Prefer not to answer | 53 | 35.3 | |
| Education | |||
| High school education or less | 99 | 65.9 | |
| Some college or Associate’s degree | 27 | 18 | |
| Completed ≥4 year college degree | 24 | 16 |
Most survivors underwent surgery as their only treatment (55%) but some received both surgery and chemotherapy (34%). A small percentage of survivors received either chemotherapy alone or radiation as part of a multi-component treatment plan (9%). Survivors had an average BMI of 28.2 km/m2 (SD = 6.4) and included participants classified as obese (31%), overweight (37%) normal weight (24%) and underweight (3%). Few survivors reported prior diagnoses of obesity (5%), depression (14%), diabetes (20%), or cardiovascular disease (23%). A limited number of survivors were currently being treated for cardiovascular disease (18%), diabetes (18%), depression (13%), or obesity (<1%), but nearly half of the survivors (40%) were currently receiving treatment for at least one of these conditions. Most survivors had smoked in the past (57%) but few were current smokers (18%).
Behavioral Characteristics
Following screening, 47 cases were identified as outliers (±3 SD) on self-reported PA and SB. Subsequent results are based on the subset of survivors (N=103) without outlying values. As seen in Table 2, PA was limited in frequency and duration, regardless of intensity level; however, light-intensity was most common, averaging about 30 min/day and 4.5 days/week. Based on the reported frequency and duration of moderate- and vigorous-intensity PA, the majority of survivors failed to achieve the recommended amount in national PA guidelines (79%). Survivors perceived that their cancer diagnosis had a limited impact on their ability to engage in moderate-intensity PA for 2.5 hrs/week (M = 34.8/100; SD = 31.9). Survivors reported engaging in less PA than desired on an average of 1.2 days in the past week (SD = 2.2).
Table 2.
Descriptive statistics on weekly physical activity and sedentary behavior
| M | SD | Median | Mode | Range | |
|---|---|---|---|---|---|
| Vigorous-intensity PA | |||||
| Frequency (day/week) | 0.33 | 1.22 | 0.00 | 0 | 0–7 |
| Duration (min/day) | 5.24 | 21.36 | 0.00 | 0.00 | 0–180 |
| Moderate-intensity PA | |||||
| Frequency (day/week) | 2.03 | 2.25 | 2.00 | 0 | 0–7 |
| Duration (min/day) | 28.79 | 44.95 | 15.00 | 0.00 | 0–240 |
| Light-intensity PA (walking) | |||||
| Frequency (day/week) | 4.45 | 2.32 | 5.00 | 7 | 0–7 |
| Duration (min/day) | 30.19 | 30.86 | 20.00 | 30.00 | 0–180 |
| Total volume of PA (MET·min) | 1110.35 | 1575.97 | 560.50 | 0.00 | 0–9,492 |
| Sedentary behavior | |||||
| Weekday duration (min/day) | 438.93 | 148.16 | 420.00 | 360.00 | 60–780 |
| Weekend duration (min/day) | 442.14 | 150.94 | 420.00 | 360.00 | 120–780 |
| Average weighted duration (min/day) | 441.22 | 147.42 | 428.57 | 360 | 102.86–780 |
Data were excluded from participants who reported >16 hrs/day of total physical activity or sedentary behavior. Outlying data points (+3 SD) were also excluded from analysis (n = 47).
Table 2 also shows that survivors reported over 7 hours/day of SB. Daily SB did not vary between weekdays and weekends (p > .05). Across the entire week, 42% of survivors reported averaging 8+ hours of sedentary time/day. Survivors reported spending more than 8 waking hours on an average of 2.2 days in the past week (SD = 3.1) and wanting to limit or interrupt their SB but lacking the motivation to do so on 1.0 days in the past week (SD = 2.1).
Table 3 summarizes joint behavioral profiles in relation to recommended levels of PA (compared to national guidelines) and SB (compared to 8 hours/day of sedentary time). Only 17% of survivors reported attaining the recommended level of weekly PA and limiting their SB to less than 8 hrs/day. Insufficient PA was more common than excessive SB.
Table 3.
Physical activity and sedentary behavior profiles among clinic patients (based on subset of data within 3 SD of mean; n = 103).
| Meeting PA Guidelines | Not Meeting PA Guidelines | Marginal Totals | |
|---|---|---|---|
| Limited Sedentary Time | n = 18 (17%) | n = 42 (41%) | n = 60 (58%) |
| Excessive Sedentary Time | n = 4 (4%) | n = 39 (38%) | n = 43 (42%) |
| Marginal Totals | n = 22 (21%) | n = 81 (79%) |
Interest in Lifestyle Interventions
Notwithstanding the normative need for behavioral interventions, survivors had moderate interest in interventions to promote PA (50%) or limit SB (47%). Age was not associated with interest in PA interventions (p > .05); however, older participants were less likely to be interested in SB interventions (r = −.21, p < .05). Interest in PA and SB interventions did not vary as a function of survivors’ sex, BMI, type of cancer, PA, or SB (all p > .05).
Acceptability of Digital Intervention Tools
Approximately 25% of the sample reported they would use a digital health tool to improve PA. Digital PA interventions were more acceptable to younger survivors (r = −.30, p < .01) and survivors reporting more SB (r = −.23, p < .05); however, no differences existed as a function of sex, BMI, type of cancer, or PA. Ascribed monetary value did not differ as a function of whether digital PA interventions were delivered via text messages, web, email, tablet computer apps, or smartphone apps (all p > .05). On average, digital PA intervention tools were ascribed more value by survivors who engaged in more PA (r = .38, p < .05); ascribed value did not differ by type of cancer, age, BMI, or SB (p ≥ .05).
Only 27% of the sample reported they would use a digital health tool to reduce SB. There were no differences in perceived monetary value of a monthly subscription for interventions delivered via text messages, web, email, tablet computer apps, or smartphone apps (all p > .05). Digital SB intervention tools were ascribed more value by younger survivors (r = −.22, p < .05) and survivors who engaged in more PA (r = .38, p < .05); ascribed value did not differ by type of cancer, BMI, or SB (p > .05).
Discussion
This study characterized PA and SB profiles in older GI cancer survivors and assessed this population’s interest in interventions to modify these behaviors and the acceptability of digital health tools for these behavior changes. The majority of older GI cancer survivors either did not meet PA national guidelines, reported excessive SB or both. Insufficient levels of PA were more common than excessive SB among older GI cancer survivors. This health behavior profile mirrors results from related populations. For example, midlife and older adult survivors of lung, breast, prostate, colon and a variety of less prevalent, unspecified cancers reported insufficient moderate and vigorous PA (41%) more frequently than excessive SB (30%) [8]. Similarly, among older adults not diagnosed with cancer, insufficient PA was more common than excessive SB when objectively measuring PA and SB in older adults over the age of 60 [20,21]. A similar needs assessment on breast cancer survivors revealed that excessive SB was more common than lower PA levels but many survivors still failed to meet PA recommendations [22]. This lack of PA in older adults with and without a cancer diagnosis is alarming considering the rapidly aging population and increased life expectancy of cancer survivors [23]. Lifestyle interventions involving PA can improve cancer-related symptoms and protect cancer survivors from a variety of comorbidities related to both a cancer diagnosis and aging in general. Yet older adults continue to be understudied and underserved, and older cancer survivors are often left out of interventions and clinical trials [23]. Our results indicate that there is a normative need for behavioral interventions to increase PA in older GI cancer survivors.
Although older GI cancer survivors need interventions to modify PA and SB, they reported only moderate interest in these types of interventions. Interest in PA interventions has been higher among other cancer survivor populations. For example, a cross-sectional study of breast, colorectal and prostate survivors revealed about 67% were at least somewhat interested in using an exercise program to get in shape [24]. On the other hand, a large percentage (89%) of older adults believe that participating in PA would help them feel better and remain independent yet still expressed a lack of interest in PA [25]. It is possible that a negative health outcome such as a cancer diagnosis leads to older adults becoming interested in regular PA but, despite their diagnosis, the present sample of older GI cancer survivors were not interested in lifestyle interventions.
Research with other cancer survivor populations (e.g. breast) has indicated that a cancer diagnosis can motivate survivors to participate in PA, even if they were inactive prior to diagnosis [26]. In some cases, PA levels can increase as much as 31% following a cancer diagnosis [27]. However, in a sample of mixed adult cancer survivors over half reported not changing their exercise behaviors following a cancer diagnosis, while approximately 30% reported exercising less [28]. The present sample of older GI cancer survivors were not motivated to increase PA following their diagnosis. Future research should determine why older GI cancer survivors are not interested in behavioral interventions for PA and SB. PA interventions for this survivor population should address this motivational deficit early in the process of behavior change.
Less than half of the present sample reported having access to either a tablet computer or smartphone. National rates of digital technology adoption by older adults are similar [15]. One can expect adoption rates to increase as younger cohorts who have already adopted this technology age. Approximately a quarter of the sample reported interest in digital health tools for both PA and SB. Consistent with our results, younger survivors from other cancer survivor populations have expressed greater interest than older survivors in digital health interventions [14]. At present, it appears that digital tools should not be used as a sole behavioral intervention modality with older GI cancer survivors.
When digital tools are used, increasing adoption of a variety of technologies may be the first step in improving acceptability of digital health interventions in this population. Increasing adoption could involve breaking down some of the barriers to using technology. Future studies should assess whether this survivor population would increase technology adoption if cost was not an issue and the technology was provided to them. Researchers may need to consider providing the technology in future interventions, particularly if cost is identified as a barrier among GI cancer survivors.
Digital tools were also more acceptable for survivors who engaged in more PA or reported higher levels of SB. These participants may accumulate SB in occupational settings that promote technology adoption. Oncologists may be able to use high SB as a trigger to query older cancer survivors’ interest in digital tools for health behavior change.
This needs assessment was based on self-reported behavioral data which can be vulnerable to bias [29,30]. Future studies should incorporate device-based measures of these behaviors as well as clinician ratings and medical records to improve understanding of lifestyle influences on survivorship outcomes. The demographic profile of survivors in this sample was representative of the catchment area but was homogeneous and conclusions may not generalize to more diverse populations. Future studies should include older GI cancer survivors from diverse ethnic and racial backgrounds. Finally, this study used a cross-sectional design so inferences cannot be drawn about how this population’s behavior or attitudes would change over time. It is likely that technology adoption and acceptability of digital health tools will improve as younger cohorts age and become older adults. Older GI cancer survivors’ acceptance of digital health tools should be re-examined periodically.
In sum, the population of older GI cancer survivors has increased over time due to earlier diagnosis and improved treatment [23]. Improved treatments are also extending longevity. Against this backdrop, it is important to find ways to improve the quality of survivorship. Older GI cancer survivors can benefit from increasing PA and limiting SB yet revealed only moderate interest in lifestyle behavior interventions. Efforts are needed to educate older GI cancer survivors about the impact of an active lifestyle on survivorship outcomes. Digital health tools hold promise for increasing access to lifestyle interventions but acceptance of these tools is currently limited among older GI cancer survivors. For now, traditional in-person approaches should continue to be employed and efforts to implement digital interventions should be accompanied by strategies to improve adoption of the digital tool. This challenge seems likely to fade as younger cohorts who have greater experience integrating technology into their lives age into the next generation of older cancer survivors.
Acknowledgments
Funding for this study was provided by the Penn State Cancer Institute, Social Science Research Institute, and the Penn State Clinical & Translational Research Institute, Pennsylvania State University CTSA, NIH/NCATS Grant Number UL1 TR000127 and UL1 TR002014. The contents are solely the responsibility of the authors and do not necessarily represent the official views of the NIH or NCATS.
Footnotes
The authors have no conflicts to declare.
All procedures performed in studies involving human participants were in accordance with the ethical standards of the institutional and/or national research committee and with the 1964 Helsinki declaration and its later amendments or comparable ethical standards.
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