Abstract
Purpose
Postoperative radiotherapy for breast cancer has a number of associated complications. This study examined whether supervised moderate-intensity exercise could mitigate the complications that occur during radiotherapy.
Patients and Methods
Forty women were randomized before radiotherapy after various operations for breast cancer. Seventeen patients who were assigned to the exercise group performed supervised moderate-intensity exercise therapy for 50 min 3 times per week for 5 weeks. Twenty-three patients in the control group were asked to perform self-shoulder stretching exercise. The World Health Organization Quality of Life-BREF (WHOQOL-BREF), brief fatigue inventory (BFI), range of motion (ROM) of the shoulder, and pain score were assessed before and after radiotherapy.
Results
There were no significant differences noted at baseline between groups. In the exercise group, there was an increase in the WHOQOL-BREF and shoulder ROM and decrease in BFI and pain score after radiotherapy. On the other hand, patients in the control group showed decrease in the WHOQOL-BREF and shoulder ROM and increase in BFI and pain score after radiotherapy. There were statistically significant differences in the changes in the WHOQOL, BFI, shoulder ROM, and pain score between the groups.
Breast cancer is the most common type of cancer among women in many Western countries including the United States, and is expected to comprise 31% of all new cases of cancer among women in the US in 2006.1 Breast cancer accounts for 16.8% of the female cancer burden in Korea.2 The incidence of breast cancer has increased but survival has also improved, thus increasingly emphasizing the quality of life (QOL) of women diagnosed with breast cancer.
Among the adjuvant therapies for breast cancer, radiotherapy after mastectomy can reduce the risk of a local recurrence by approximately 2/3 and remains an important component of management for breast cancer.3,4 Although the beneficial effect of postoperative radiotherapy for breast cancer is well documented, there are a number of complications associated with this treatment, that might affect the patients' QOL and possibly survival. Among the long-term irradiation complications, there is cardiac and lung damage, impaired shoulder mobility, and chronic pain.5 Fatigue after radiation therapy for breast cancer is also a common side effect of irradiation and has been reported by 100% of patients.6,7
Previous meta-analysis has shown that there are a number of QOL interventions that may help individuals cope with cancer including cognitive-behavioral therapy, information and educational strategies, individual counseling, psychotherapy, and social support.8 However, a common feature among these interventions is that they do not adequately address the QOL or the physical and functional problems encountered by patients such as fatigue, nausea, and weight gain. Several interventions in the management of radiotherapy-related fatigue have been tested and some randomized studies have recently been published.7,9,10 Although there is no optimal method, some promising results using relaxation therapy, group psychotherapy, sleep, and physical exercise have been reported.
Exercise is associated with improved cardiovascular fitness, pulmonary function, and selfesteem, and with decreased anxiety and depression, which are all aspects of health that are typically diminished in radiotherapy patients.11 Recent studies have reported that exercise is feasible, safe, and well tolerated by breast cancer survivors, and has beneficial effects on QOL, fatigue, fitness, side effects of therapy, body composition, and survival.12-14 Mock et al.15 reported that adherence to a home-based moderate-intensity walking exercise program mitigated the high levels of fatigue that are prevalent during breast cancer treatment.
To our knowledge, there have been few randomized controlled trials to examine the effects of supervised moderate-intensity exercise therapy during radiotherapy for breast cancer. Moreover, most of the studies showed the effects of only 1 type of exercise therapy such as walking exercise to increase aerobic capacity or shoulder stretching exercises to improve shoulder mobility and activities of daily living. Many complications occur simultaneously during radiotherapy for breast cancer; therefore, research on structured exercises and comprehensive evaluations of their effects are needed.
In the present study, we performed a randomized controlled trial to determine whether supervised and structured moderate-intensity exercise during radiotherapy would offer some benefit to breast cancer patients by improving QOL and shoulder mobility and reduce levels of fatigue and pain.
Consecutive unselected women on the outpatient waiting list for radiotherapy for breast cancer were approached at their first planned visit. The exclusion criteria included concurrent major health problems that could affect their participation in an exercise program, including uncontrolled hypertension, cardiovascular disease, acute or chronic respiratory disease, and cognitive dysfunction. Forty participants were recruited and randomly assigned to either an exercise or control group. Three patients in the control group were lost during follow up because they did not want to participate in follow-up measurements. Finally, 37 patients completed the follow-up assessment (17 in the exercise group, 20 in the control group). Among patients in the exercise group, 6 had undergone modified radical mastectomy (MRM), 6 had undergone breast-conserving surgery (BCS) with axillary lymph node dissection (ALND), and 5 had undergone BCS with sentinel lymph node biopsy. In the control group, 7 patients had undergone MRM, 6 had undergone BCS with ALND, and 7 had undergone BCS with sentinel lymph node biopsy. Patients were irradiated with a dose of 50 Gy during 5 weeks with a dose per fraction of 2 Gy.
Patients assigned to the exercise group attended a supervised exercise program 3 times per week for 5 weeks. The 50-min program consisted of a 10-min warm-up, 30 min of exercise (including stretching exercises focused on the shoulders, aerobic exercise such as treadmill walking and bicycling, and strengthening exercise), and a 10-min cool-down (relaxation period). Heart rates were monitored throughout the class to ensure that patients were exercising at the target heart rate of 50 - 70% of the age-adjusted heart rate maximum.
Patients in the control group were shown how to perform shoulder ROM exercises and were encouraged to continue with normal activities.
All questionnaires and assessments were assessed at baseline and after completion of radiotherapy.
The WHOQOL-BREF was developed by the WHOQOL-100.16,17 The Korean version of the WHOQOL was developed in 2002, and has demonstrated valid psychometric properties.18 The WHOQOL-BREF consists of 26 items: 24 items tap 4 subscales/facets, including physical, psychological, social relations, and environmental QOL; 1 item related to overall health; and 1 item that measures overall QOL. Each item is scaled from 1 - 5. The score in each 4 subscale was converted to a 4 - 20 scaled score. The average WHOQOL-BREF score, which was the sum of 26 items of the WHOQOL-BREF divided by 26, was used and ranged from 1 - 5. The higher the score, the more positive response to QOL.
The BFI is a 1-page questionnaire assessing 9 items, each being measured on numeric rating scales from 0 ("no fatigue" or "does not interfere") to 10 ("fatigue as bad as you can imagine" or "completely interferes"), using a single-word designation of the fatigue severity levels and domains to make it easy to administer and understand. The Korean version of the BFI was reported to be a reliable, valid self-rating instrument in its psychometric properties.19 The global score for the BFI was calculated as the mean value of 9 items ranging from 0 - 10. In this study, the BFI was self-reported by all patients at baseline and follow up after the completion of treatment.20
Data were analyzed using SPSS version 10.0 software (SPSS Inc., Chicago, IL, USA). We compared baseline characteristics of the 2 groups using independent-samples t tests. Data were analyzed using analyses of covariance in which groups were compared according to follow-up data with baseline data as the covariate. P value < 0.05 was taken as significant.
There were no significant differences in all of the outcome measures at the baseline between groups (Table 1). The most common area of pain was the shoulder area of the affected side, followed by the operation site and the arm of the affected side. A few patients complained of pain at the scapular area and lower back.
After radiotherapy, mean WHOQOL score increased in the exercise group and decreased in the control group. There was a significant difference in the change in mean WHOQOL score between groups (Fig. 1). On the WHOQOL-BREF subscale, changes in mean scores in overall health, physical, psychological, and social facets showed significant differences between groups (Table 2).
The mean BFI decreased in the exercise group and increased in the control group after radiotherapy. There was a significant difference in the change in mean BFI between groups (Fig. 2).
After radiotherapy, ROM of the shoulder in all directions increased in the exercise group and decreased in the control group. Changes in ROM of the shoulder in all directions showed significant differences between groups (Fig. 3).
Mean VAS score decreased in the exercise group and increased in the control group. There was a significant difference in the change in mean VAS score between groups (Fig. 4).
Accumulated data have confirmed beneficial effects of radiotherapy on women with breast cancer.3,4 However, there are a number of complications associated with postoperative radiotherapy for breast cancer.5 Among them, shoulder and arm complications are quite troublesome sequelae.21 In addition, life-threatening cardiac and lung damage and radiotherapy-related fatigue can also occur.5,6 All of these complications could decrease QOL. On the other hand, it was reported that exercise during radiotherapy improved QOL.22,23 In this study, QOL of the exercise group showed significant improvement, particularly in the physical and psychosocial areas, compared to the control group. This is in line with previous studies on exercise in patients with breast cancer during adjuvant therapy. One randomized trial demonstrated that women who participated in an exercise program during radiotherapy for early-stage breast cancer showed a trend toward improved physical and psychological functioning.7 Park et al.2 reported that the physical and psychosocial domains showed worsened QOL for patients with breast cancer. Courneya et al.24 showed that exercise training had beneficial effects on physical function and QOL in breast cancer survival, and improvements in physical functioning were associated with improvements in QOL. Therefore, it was suggested that exercise improved physical and psychological functioning during radiotherapy, which was attributed to the improvement of QOL in this study.
In the present study, the exercise group showed a decrease in mean fatigue score after radiotherapy, unlike patients in the control group. Mock et al.15 reported that a home-based moderate-intensity exercise program might effectively mitigate the high levels of fatigue during treatment for breast cancer. Many researchers have reported that exercise therapy for cancer patients during radiotherapy reduced fatigue, but the reason is unclear. Windsor et al.25 suggested that improvement in physical functioning by exercise therapy might help overcome radiation fatigue. In patients with cancer who were rendered disease-free after completing radiotherapy 9 mo earlier, the most significant predictor of fatigue was the degree of post-radiotherapy functional disability.26 Advising patients to rest and reduce levels of activity leads to muscular deconditioning and a loss of performance, which means that more effort is needed for patients to perform normal daily activities. Moreover, Schwartz suggested that the effects of exercise on QOL might be mediated by the effects of exercise on fatigue.22
There was no significant difference in baseline ROM of the shoulder joint and baseline level of pain between the 2 groups. After radiotherapy, the control group showed decreased ROM of the shoulder in all directions and increased pain score. In contrast, the exercise group showed increased ROM of the shoulder in all directions and decreased pain score. Most patients complained of mild to moderate pain at the shoulder girdle and/or incision area. Pain and muscle spasms can occur in the shoulder region as a result of muscle guarding.27 In addition, chest wall adhesion can lead to increased risk of pain and reduction in ROM of the shoulder on the involved side as well as postural dysfunction.28 Robb et al.29 reported a positive outcome in a pain management program that included exercise for patients with chronic cancer treatment-related pain. Andersen et al.30 also reported that a 6-week exercise intervention decreased the level of pain and the other treatment-related symptoms in cancer patients during chemotherapy. Baseline pain score of patients included in this study was low, indicating little room for reduction in pain. Nevertheless, we could show significantly different changes in pain scores between the 2 groups. So it seemed not to come into question.
In most studies examining the effects of exercise, only the effects of walking exercise on aerobic capacity or the effects of shoulder stretching exercises on improvement of shoulder mobility were evaluated.21,23,31,32 Although it could improve a single parameter in such cases, it did not alter the other parameters for exercises that had not been performed. Therefore, it was difficult to improve overall physical state. It is believed that a structured exercise program including various exercises would produce better results. Segal et al.33 reported greater improvement in physical functioning of participants in the self-directed exercise group than the supervised exercise group. However, the duration of exercise was so long (26 weeks) that there was a lower dropout rate in the more convenient self-directed home-based exercise group than the supervised class, which was attributed to significant differences in increased physical functioning. Pickett et al.32 reported that 22% of patients did not exercise, and 13% of patients dropped out when moderate-intensity walking exercise was performed for 6 mo. In contrast, Windsor et al.25 reported that adherence increased when the same moderate-intensity exercise was performed for 4 weeks. Indeed, Mutrie et al.34 reported that the supervised exercise group showed improvement in physical and psychological functioning in comparison with the home-based exercise group, which was similar to our results. Therefore, supervised exercise guided by professional therapists might be more effective than home-based exercise, if it is possible to achieve high adherence. In this study, the exercise program was initiated the same day that patients received radiotherapy; therefore there was no dropout in the exercise group. However there was a 13% dropout rate in the control group.
This study had a small sample size, and patients were assessed immediately after radiotherapy. Therefore, further research with long-term follow up studies and larger sample size is needed.
In conclusion, despite the small sample size, there were positive physical and psychological benefits from supervised moderate-intensity exercise during radiotherapy for breast cancer. There was no evidence of any negative effects associated with exercise in cancer survivors. Cancer care teams should consider exercise as a part of rehabilitation during radiotherapy.
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