Introduction
In the majority of studies concerning
cancer-associated fatigue, no clear association between fatigue and
the type of cancer treatment has been revealed (1,2).
Severe fatigue was not only observed in patients with malignant
tumors but also in patients treated for benign bone tumors
(3,4). Severe fatigue remained present in
over a quarter of patients after a 2-year disease-free period and
appears to be associated with tumor recurrence, less patient
optimism, lower self-efficacy and increased somatization. It is
unclear to what extent the fatigue already existed prior to the
treatment of the tumor.
While fatigue is known to be an important factor
influencing the quality of life of patients, little is known about
the development of fatigue before, during or after tumor treatment
and its contributing factors. Few studies have measured fatigue in
patients before or during the treatment of a tumor (5–7).
Therefore, the first objective of the present study
was to investigate fatigue severity in patients diagnosed with
benign or low-grade malignant bone and soft tissue tumors prior to
the surgical treatment of the tumor and 6 months post-operatively.
The second objective was to determine which variables within the
tumor group are significantly associated with fatigue severity.
Variables which were expected to contribute to severe fatigue were
selected, including physical limitations, physical (in)activity,
pain, self-efficacy and anxiety. It was expected that decreased
levels of physical activity caused by local pain from the tumor and
weight-bearing restrictions, as well as the more physical
limitations, would be associated with a higher level of fatigue
(8). Anxiety was expected to be
higher in the tumor group, both in benign and malignant tumors, due
to the knowledge of having a tumor, the stress of the surgical
treatment and the fear of local recurrence. A higher pain score and
level of anxiety were expected to be associated with a higher level
of fatigue. An association between higher self-efficacy and lower
fatigue severity was demonstrated in a previous study (6).
The level of fatigue was assessed before the
patients underwent surgery (the only tumor treatment) and 6 months
post-operatively. Fatigue severity and possible associated factors
in the tumor patients were compared with those of patients
undergoing knee arthroscopy for suspected meniscus tears. The knee
arthroscopy patients were selected as the control group, since
these patients suffer from knee pain and decreased physical
activity but do not have the psychological stress of a tumor
diagnosis. The level of fatigue in the arthroscopy and tumor groups
was also compared with published data from healthy controls.
Patients and methods
Patients
Consecutive patients recently diagnosed with benign
or low-grade malignant bone and soft tissue tumors at the
Department of Orthopaedic Surgery of the Radboud University Medical
Centre Nijmegen (Nijmegen, The Netherlands) aged between 18 and 75
years and undergoing surgical therapy for the tumor only were asked
to participate in the present study. Patients receiving
chemotherapy or radiotherapy as adjuvant treatments were excluded
from the study. Other exclusion criteria included previous
treatment for cancer and severe co-morbidity causing fatigue. The
control group contained patients undergoing knee arthroscopy for
suspected meniscus tears, aged between 18 and 75 years, without
severe co-morbidity causing fatigue. The tumor and the arthroscopy
groups received the same assessment and this was performed prior to
surgery and 6 months later. Permission for this study was given by
the ethics committee of the medical centre. A written informed
consent was signed by all participating patients.
Assessment
Fatigue severity
Fatigue was measured with the fatigue severity
subscale of the checklist individual strength (CIS) (2,9).
This subscale contains 8 items scored on a 7-point Likert scale.
Scores range between 8 (no fatigue) and 56 (severe fatigue). A
score of ≥35 points indicates severe fatigue. This score is higher
than the mean plus two standard deviations of a healthy control
group (9,10). The CIS fatigue subscale has been
used in studies concerning chronic fatigue syndrome and post-cancer
fatigue and measures fatigue severity over the past 2 weeks. Since
this questionnaire has a cut-off point for severe fatigue, it may
be used to identify severe fatigue in individual patients and also
for prevalence estimates in populations. Normative data are
available for healthy controls. In the present study, the fatigue
scores of the 2 patient groups were compared with the fatigue
scores of a group of 53 healthy adults with a mean age of 37.1
years (SD, 11.5) (10).
Pain.
Current pain was measured with an 11-point numeric
rating scale (NRS) with a score of 0 for no pain and 10 for severe
pain. The pain subscale of the SF-36, in which patients have to
indicate the magnitude of their pain symptoms and the impairment to
daily functioning caused by this pain, was used to assess the
impact of pain. Scores range between 0 and 100 (100 = no pain and
no impairments due to pain; 0 = maximal pain and maximal impairment
due to pain) (11,12).
Physical limitations.
Physical limitations were measured with the SF-36
subscale of physical functioning. This score ranges between 0 (very
low physical functioning) and 100 (optimal physical functioning)
(11,12).
Anxiety.
The level of anxiety was measured with the
Spielberger State-Trait Anxiety Inventory version Y (STAI-form Y)
(13,14). Only the subscale state anxiety was
used, since the present level of anxiety was relevant to the
present study. Scores range between 20 and 80 and a higher score
reflects a higher level of anxiety.
General self-efficacy.
General self-efficacy, a general sense of personal
competence and effectiveness, was measured with the general
self-efficacy scale. The total score ranges between 10 and 40 and a
higher score reflects a higher sense of control (15,16).
Physical activity.
An actometer (Actilog V3.0), a motion-sensing device
worn at the ankle for 12 consecutive days and nights, was used to
quantify physical activity. The actometer detects movements of the
leg (e.g., during walking or climbing stairs). A general physical
activity score that expressed the mean activity level over this
period as the mean number of accelerations per 5-min intervals was
calculated (17). Higher scores
indicate a higher level of physical activity. Self-reported
physical activity was measured on an 11-point NRS, with a score of
0 for ‘not physically active’ and 10 for ‘physically very
active’.
Statistical analysis
Statistical analysis was performed using SPSS
software (version 16.0). Descriptive statistics were used for
description of the sample. The differences in fatigue, pain,
physical activity, anxiety and self-efficacy between the tumor and
arthroscopy group were tested using t-tests for independent
samples. A t-test for independent samples was also used to compare
the levels of fatigue of the 2 patient groups with a group of
healthy controls. Pearson correlation analyses were used to
determine the associations between fatigue severity and
demographic, psychological and/or physical variables in the tumor
group.
The variables that significantly correlated with
fatigue severity were used as predictors in a multiple regression
(backward method) with fatigue severity as the dependent variable.
Only significant variables were entered in the multiple regression.
As the sample size was expected to be rather small, this step was
performed to limit the number of predictors. P<0.05 in the
t-test and correlations were considered to indicate statistically
significant differences. For the multiple regression, a P-value of
0.10 was used as the criterion for the removal of the variable from
the regression. The significant predictors resulting from the
regression analysis were considered to be possible determinants of
fatigue.
Results
Patients
In the tumor patient group, 48 patients were
included prior to the treatment of the tumor. At the 6-month
follow-up, four patients refused to complete the assessment and
were excluded from the analysis. One patient was also excluded due
to a cerebrovascular accident during treatment. Of the remaining 43
patients, 20 were male (47%) and 23 female (53%). The mean age was
41.5 years (range, 19–67 years) and the tumors were located in the
upper extremity (40%) or the lower extremity (60%). Treatment
consisted of local excision (soft tissue tumors, osteochondroma) or
curettage and cryosurgery (aneurysmal bone cysts, giant cell tumor,
fibrous dysplasia, aggressive enchondroma, low-grade
chondrosarcoma). One patient in the follow-up period underwent a
second surgery to explore the previously operated area for
suspected local recurrence but no local recurrence was identified.
All other tumor patients were disease-free during the follow-up
period. In the control group of knee arthroscopy patients, 24
patients completed the assessment before and 6 months after the
arthroscopy. There were 13 males (54%) and 11 females (46%) in this
group with a mean age of 43.1 years (range, 23–68 years). During
the 6-month follow-up, 2 patients underwent a second surgery due to
medial gonarthrosis, 1 patient underwent a high tibial osteotomy
and 1 patient received an unicondylar knee prosthesis.
Fatigue severity in the tumor and knee
arthroscopy group
In the tumor group, 35% of the patients were
severely fatigued prior to treatment and 33% at the 6-month
follow-up. The CIS fatigue score decreased significantly between
pre- and post-operative assessment in the tumor and arthroscopy
groups (Table I). The decrease
over time in the CIS score was not significantly different between
the tumor and arthroscopy groups [F (1.65)=0.326; P=0.570]. The
mean CIS score at follow-up of the 2 groups was markedly higher
than that of the healthy controls: 26.1 (SD, 13.7) in the tumor
group and 24.4 (SD, 12.6) in the arthroscopy group, compared with a
mean CIS-fatigue score of 17.3 (SD, 10.1) in the healthy control
group (6).
 | Table ICIS fatigue, pain, anxiety,
self-efficacy and physical functioning scores before and 6 months
after surgical treatment. |
Table I
CIS fatigue, pain, anxiety,
self-efficacy and physical functioning scores before and 6 months
after surgical treatment.
| Tumor (n=43), mean
(SD)
| Arthroscopy (n=24),
mean (SD)
|
|---|
| Characteristic | Pre-op | Follow-up | P-value | Pre-op | Follow-up | P-value |
|---|
| CIS fatigue | 29.7 (14.2) | 26.1 (13.7) | 0.023 | 29.7 (13.1) | 24.4 (12.6) | 0.090 |
| Pain (NRS) | 2.7 (2.5) | 2.1 (2.1) | 0.061 | 2.3 (3.1) | 1.8 (2.2) | 0.445 |
| SF-36 pain | 57.0 (26.2) | 71.8 (23.7) | 0.000 | 66.5 (22.0) | 82.8 (16.4) | 0.007 |
| SF-36 physical
functioning | 60.5 (26.8) | 72.6 (23.7) | 0.000 | 61.9 (20.7) | 82.9 (18.7) | 0.000 |
| State anxiety | 37.5 (10.5) | 32.9 (10.1) | 0.006 | 30.1 (7.7) | 29.0 (9.9) | 0.498 |
| Self-efficacy | 32.1 (4.5) | 31.8 (4.8) | 0.763 | 34.3 (4.3) | 34.2 (4.3) | 0.951 |
In the arthroscopy group 9 patients (38%) were
severely fatigued prior to the surgery. Of these 9 patients, four
remained severely fatigued 6 months later without any physical
problems associated with the surgery. The 3 knee arthroscopy
patients that developed severe fatigue during or after treatment
all underwent a second knee surgery or had persistent knee
complaints. In the tumor patient group, only one patient underwent
a second surgery and all patients were without evidence of disease
6 months after treatment.
Pain, physical limitations, physical
activity, anxiety and self-efficacy in both patient groups
Scores for pain and anxiety decreased over time,
whereas the actometer and physical functioning scores increased. No
significant differences were observed between the tumor and
arthroscopy groups with respect to the changes in these variables.
The score for self-efficacy did not change over time as expected.
Pre- and post-operative actometer scores were not compared, due to
the small sample size of the pre-operative group (Table I).
Correlation of fatigue with other
variables in the tumor patients
In the tumor group the NRS pain score, SF-36 pain,
SF-36 physical functioning, anxiety and self-efficacy correlated
significantly with fatigue severity (Table II). The anxiety score in the tumor
patient group did not significantly differ between a benign and
malignant diagnosis (t-test, P=0.405).
| Table IICorrelation of variables with fatigue
severity (CIS fatigue)a in tumor patients prior to
surgical treatment. |
Table II
Correlation of variables with fatigue
severity (CIS fatigue)a in tumor patients prior to
surgical treatment.
| Variable | Tumor (n=48) |
|---|
| Pain (NRS) | 0.525c |
| SF-36 pain | −0.598c |
| SF-36 physical
functioning | −0.338b |
| State anxiety | 0.355b |
| Self-efficacy | −0.343b |
| Physical activity
(self-reported NRS) | −0.215 |
| Actometer | −0.026 |
Multiple regression
Multiple regression analysis was used to identify
predictors of severe fatigue in the tumor group 6 months after
treatment (Table III). Factors
significantly correlated with the CIS fatigue score in the previous
study were entered in the analysis (anxiety at follow-up SF-36 pain
at follow-up and self-efficacy at follow-up), as well as the CIS
fatigue score before treatment.
| Table IIIResults of multiple regression
analysis to determine the contribution of variables to fatigue
severity (CIS fatigue) in tumor patients 6 months after surgical
treatment. |
Table III
Results of multiple regression
analysis to determine the contribution of variables to fatigue
severity (CIS fatigue) in tumor patients 6 months after surgical
treatment.
| Predictor | B | Beta | P-value |
|---|
| Constant | −2.903 | | |
| State anxiety
(follow-up) | 0.401 | 0.302 | 0.033 |
| CIS-fatigue
(pre-op) | 0.505 | 0.539 | 0.000 |
| R2
adjusted | 0.553 | | |
Analysis revealed that higher CIS fatigue scores
prior to treatment and higher state anxiety at follow-up were
predictors of fatigue severity that explained ∼55% of the
variance.
Discussion
The primary objective of the present study was to
determine the level of fatigue in patients diagnosed with benign
and low-grade malignant bone and soft tissue tumors prior to the
surgical treatment of the tumor and 6 months post-operatively. It
was revealed that a substantial number of patients (38%) were
severely fatigued. Six months after surgical treatment, 33% of the
patients remained severely fatigued. When this group of severely
fatigued patients was analyzed, it was apparent that the majority
of the severely fatigued patients before treatment remained
fatigued 6 months later. This severe fatigue cannot be explained by
the physical condition of the patients, since all lacked evidence
of disease and no complications from the surgical treatment
occurred. Multiple regression analysis confirmed that a high CIS
fatigue score prior to treatment was the most successful predictor
of severe fatigue 6 months later. The CIS fatigue score decreased
significantly over time but the percentage of patients severely
fatigued before and after treatment remained similar.
In the knee arthroscopy group, severe fatigue was
present to the same extent as in the tumor group prior to
treatment. This supports the theory that severe fatigue is not
induced by the tumor itself but by symptoms caused by the tumor or
a meniscus tear, including pain, restricted physical activity and
anxiety. In the arthroscopy group, severe fatigue at follow-up was
associated with a second surgery or persistent knee complaints in
approximately half of the patients.
It appears that severe fatigue is a symptom that
develops prior to treatment and, if present at the clinical
diagnosis, often persists over time. Interventions for persistent
fatigue following cancer treatment, such as a physical training
programs or cognitive behavioral therapy (18–20)
have been demonstrated to be successful at reducing fatigue
severity. With the results of the present study revealing that the
majority of patients suffer from severe fatigue prior to treatment,
we suggest that it may be useful to perform a screen for
pre-existing fatigue severity prior to diagnosis and begin
intervention for severe fatigue as early as possible after
treatment.
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