For the Dutch Bone Metastasis Study Group
Affiliations of authors: W. B. van den Hout, J. Kievit (Department of Medical Decision Making), Y. M. van der Linden, E. Steenland (Department of Clinical Oncology), Leiden University Medical Center, Leiden, The Netherlands; R. G. J. Wiggenraad, Department of Radiotherapy, Haaglanden Medical Center, The Hague, The Netherlands; H. de Haes, Department of Medical Psychology, University of Amsterdam, Amsterdam, The Netherlands; J. W. H. Leer, Joint Center for Radiation Oncology Arnhem-Nijmegen, The Netherlands.
Correspondence to: Wilbert B. van den Hout, Ph.D., Department of Medical Decision Making, Leiden University Medical Center, P.O. Box 9600, 2300 RC Leiden, The Netherlands (e-mail: W.B.van_den_Hout{at}LUMC.NL).
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ABSTRACT |
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INTRODUCTION |
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The 1996 Dutch Bone Metastasis Study was a large randomized trial in which patients with painful bone metastases received palliative radiotherapy either in a single fraction of 8 Gy or in six fractions of 4 Gy each (9). At the conclusion of the study, no statistically significant differences were found in pain response, treatment side effects, and descriptive quality of life. A limited analysis of the costs of radiotherapy suggested that the cost difference was small. The medical costs for the single-fraction schedule were only 25% lower, because a large proportion of the costs did not change with the number of fractions. Moreover, the cost difference was decreased by the number of retreatments, which was 25% after the single-fraction schedule, compared with only 7% after the multiple-fraction schedule (9).
To determine from a societal perspective which radiotherapy schedule provides better value for the money, we performed a full costutility analysis of the Dutch Bone Metastasis Study. In the costutility analysis, effectiveness is measured by quality-adjusted life expectancy, i.e., the overall valuation of the health of the patients in the study. The difference in this quality-adjusted life expectancy was compared with the difference in total costs to society, including the medical costs of radiotherapy, other costs of health care utilization, and costs incurred by the patients.
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PATIENTS AND METHODS |
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Details of the patient population and study design for the Dutch Bone Metastasis Study have been published elsewhere (9). In brief, from March 1996 through September 1998, patients with painful bone metastases from solid tumors were randomly assigned to receive either a single fraction of 8 Gy (n = 579) or six fractions of 4 Gy (n = 578). The patients were enrolled in the study from 17 of 21 Dutch radiotherapy institutions. Of the 1157 patients, 36% had bone metastases that were located in the pelvis, 30% in the spine, 10% in the femur, 8% in the ribs, 6% in the humerus, and 10% in other sites. Thirty-nine percent of the patients had breast cancer, 25% had lung cancer, 23% had prostate cancer, and 13% had cancer at other primary sites. Patient age ranged from 32 to 89 years, and 54% of the patients were male.
To be eligible for the study, patients had to have a maximum pain score during the preceding week of at least 2 on an 11-point scale from 0 (no pain) to 10 (worst imaginable pain) (13). The bone metastases had to be confined to an area that could be encompassed in a single radiation treatment field. Patients were excluded from the study if their metastases had already been irradiated, if they had metastases in the cervical spine, or if they had a pathologic fracture or compression of the spinal cord. Patients were also excluded if they had renal cell carcinoma or malignant melanoma, because these diseases were expected to respond differently to radiotherapy.
In this study, we aimed to enroll 1200 patients, which would be sufficient to provide the required sample size of 900 assessable patients to demonstrate a 10% difference in the main outcome measure, which was pain response ( = 0.05,
= 0.15). The Medical Ethics Committees of all participating institutions approved the study, and all patients signed informed consent forms.
Assessment of Quality-Adjusted Life Years
The patients were followed for up to 2 years after randomization. During this follow-up period, patients completed 13 weekly and 23 monthly questionnaires containing questions on pain at the treatment site, analgesic consumption, treatment side effects, and quality of life. Patients also described their health state using the EuroQol classification system (EQ-5D) (14). The EQ-5D has five attributes (mobility, self-care, usual activities, pain/discomfort, and anxiety/depression), with three levels each (no problem, some problems, or major problems). The descriptions were transformed into the corresponding EQ-5D utility (15). This utility reflects the valuation by the general public of the health states provided by the patients, ranging from 1.00 (optimal health), through 0.00 (equivalent to death), to 0.594 (worse than death).
The Dutch Bone Metastasis Study ended in December 1998. At that time, the survival status of all patients was recorded by the data managers of the participating institutions. For the patients who died during the study period, the duration of survival was observed directly. For the surviving patients, the observed survival duration was censured at between 3 and 27 months. Because the patients with censured survival data were likely to have a favorable prognosis, neglecting the censured data could bias the analysis by underestimating survival. Therefore, each observed censured survival was increased by the remaining lifetime estimated from the last available EQ-5D utility measurement: extrapolated remaining lifetime in days = 156 + 150 x last EQ-5D utility. This formula was estimated from the available survival data by using standard linear regression (R2 = 0.12). Depending on the value of the last EQ-5D utility, the estimated remaining lifetime ranged from 67 to 306 days.
Shortly before their death, patients tended to stop returning their questionnaires. Because the values of these missing measurements were likely to be worse than the available measurements, neglecting the missing EQ-5D data or carrying forward the last measurement could bias the analysis by overestimating the utilities. Therefore, the values of the missing EQ-5D utilities were estimated from the last available measurement: extrapolated EQ-5D utility = constant x (1 + 98/remaining lifetime in days)-1, with the constant individually fitted to the last available EQ-5D utility. This formula was estimated from the available EQ-5D data using standard nonlinear regression (R2 = 0.15).
For each patient, quality-adjusted life years (QALYs) were calculated from the survival and the EQ-5D utility measurements. Survival was truncated to the maximum follow-up of 2 years. QALYs were truncated to 12 weeks and to 2 years after randomization and were discounted at 3%.
Assessment of Costs
For both randomization groups, we estimated the societal costs during the first 12 weeks after randomization. These costs included the medical costs of radiotherapy, the nonmedical costs of radiotherapy such as travel costs, medical nonradiotherapy costs such as the cost of hospitalization, and health-related nonmedical costs such as the cost of domestic help. Costs were estimated in strict accordance to current guidelines for cost-effectiveness analyses (16).
The medical costs of radiotherapy have been reported earlier (9) but are reported here in greater detail. These costs were estimated for three of 21 Dutch radiotherapy institutions: one of seven academic hospitals, one of eight general hospitals, and one of six independent radiotherapy institutions. The results from the three institutions were weighted relative to the number of each type of institution and combined to generate a typical Dutch radiotherapy department. For each institution, the costs of different types of staff, equipment, material, housing, and overhead were obtained from 1997 annual reports. To estimate the costs of different radiotherapy schedules, each cost item was assigned to one of three allocation bases: treatments, for cost items independent of the treatment schedule; sessions, for cost items proportional to the number of fractions in a treatment schedule; or gray, for cost items proportional to the radiation dose delivered. The annual costs assigned to each allocation base were divided by the annual number of each allocation base to provide an estimate of the unit cost per treatment, per session, and per gray. The costs of a treatment schedule consisting of a single fraction of 8 Gy were then estimated as the costs per treatment plus the costs per session plus eight times the costs per gray. Similarly, the costs of a treatment schedule consisting of six fractions of 4 Gy were estimated as the costs per treatment plus six times the costs per session plus 24 times the costs per gray.
The nonmedical costs of radiotherapy and nonradiotherapy costs were mostly estimated from cost questionnaires. For practical reasons and to limit the burden to the patients, these questionnaires were filled out by a subsample of the patients over a period of 12 weeks after randomization. Patients from the three institutions from which the typical Dutch radiotherapy department was constructed were asked to fill out six additional bi-weekly cost questionnaires. They could refuse to fill out these additional questionnaires without being excluded from the study. Of 213 consecutive patients enrolled in the trial, 166 (78%) consented to participate. The costs estimated from the cost questionnaires included nonmedical costs of radiotherapy (means of transportation, time spent in transit to and from the radiation department, and out-of-pocket expenses), retreatment costs, hospitalization costs, consultation costs (visits to general practitioners, specialist consultations, paramedics, and alternative treatments), purchased medication, in-home nursing care costs, out-of-pocket expenses, costs of domestic help, and paid and unpaid labor costs. From the trial registration, we obtained the schedules of the initial radiotherapy and of retreatments more than 12 weeks after randomization (deduced from the number of treatment days), data on systemic therapy, and the travel distance from the patient's home to the radiation department.
Most cost prices were obtained from Dutch standard prices that were designed to reflect societal costs and to standardize economic analyses (17,18). Out-of-pocket expenses (e.g., an antidecubitus bed) were valued as reported by the patients. Transportation costs were valued at $0.29 per kilometer for car rides, at $2.26 plus $1.49 per kilometer for taxi rides, at $385 for ambulance rides, and at no cost for walking (17). Patients' time was valued at minimum wage ($8.43 per hour). Hospitalization costs were valued at $482 per day for clinical admission, $193 per day for outpatient care, and $144 per day for nursing home care (17). The cost of a general practitioner was valued at $18 per in-house consultation (17), $9 per telephone consultation, and $36 per home consultation. The cost of a specialist was, on average, valued at $48 per consultation (17), with different specialties ranging from $25 to $86 per consultation. The costs of physiotherapists and other paramedics were valued at $19 per consultation (17), and alternative medicine was, on average, valued at $29 per consultation. The cost of purchased medication was valued according to the Pharmacotherapeutic Compass (18), plus $6 per nondrugstore purchase (17). The costs of in-home nursing care and domestic help were valued at $34 and $19 per hour, respectively (17). The reported amount of time spent on paid and unpaid labor was valued at minimum wage and counted as profits (i.e., negative costs).
Because the type of systemic therapy was not available, the costs of systemic chemotherapy or hormonal therapy were based on Dutch treatment guidelines, with prices obtained from the Pharmacotherapeutic Compass (18). Breast cancer patients for whom systemic therapy lasted less than 4 months were assumed to have had a CMF regimen valued at $2450 (six cycles of cyclophosphamide at 100 mg/m2 on days 114, two cycles of methotrexate at 40 mg/m2 on days 1 and 8, and two cycles of 5-fluorouracil at 600 mg/m2 on days 1 and 8). Breast cancer patients receiving longer systemic therapy were assumed to have had hormonal therapy valued at $18 per month (tamoxifen at 20 mg per day). Prostate cancer patients receiving systemic therapy were assumed to have had hormonal therapy valued at $171 per month (either cyproteron at 200 mg per day or goserelin at 3.6 mg subcutaneously per month). In the absence of a reasonable standard therapy, no costs were considered for the remaining patients receiving systemic therapy (8% of all patients).
For each patient who consented to fill out the cost questionnaires, the societal costs during the first 12 weeks after randomization were estimated. For missing cost measurements, the last available measurement was carried forward. Costs are reported at the 2002 price level and were discounted at 3%. Prices were converted to U.S. dollars by using the exchange rate of June 26, 2002 (€1 = $0.99).
CostUtility Analysis
In the costutility analysis, the 2-year QALYs were compared with the 12-week societal costs. These different time periods were chosen mainly because of the different measurement periods for utilities and costs and were justified by the observation that no statistically significant differences were observed in the costs of radiotherapy after 12 weeks or in the nonradiotherapy costs. Extrapolating costs to a longer time horizon would require substantial modeling assumptions, which could introduce modeling errors. Therefore, the 12-week time period was considered more appropriate for the costs in the costutility analysis.
Whether a treatment is cost-effective depends on the willingness-to-pay per QALY. Acceptability curves graph the P value of the hypothesis of equal net benefit (i.e., willingness-to-pay x QALYs costs) in both randomization groups as a function of the willingness-to-pay (19,20). Better cost-effectiveness of the schedule with the more favorable net benefit is demonstrated if the difference in net benefit is statistically significant (P.05). By considering the net benefit, acceptability curves eliminate the problems associated with negative cost-effectiveness ratios. For the acceptability curves, the mean and variance of the QALYs were obtained from the entire sample (n = 1157), and the mean and variance of the costs and their covariance with the QALYs were obtained from the patients who filled out the cost questionnaires (n = 166).
The baseline costutility analysis used the societal perspective, including all costs incurred during the first 12 weeks after randomization. In addition, we performed sensitivity analyses from the medical perspective (including only medical costs of radiotherapy and of other health care during the first 12 weeks after randomization) and the long-term radiotherapy perspective (including only medical and nonmedical costs of radiotherapy during the first 2 years after randomization).
Statistical Analysis
All analyses were performed on an intent-to-treat basis. Groups were compared by use of standard two-sided unequal-variance t tests at a 5% significance level (21), with the corresponding 95% confidence intervals (CIs) for the difference in means. Reported CIs for means within groups are standard 95% CIs (average ± [tn,0.05 x n-1/2] x standard deviation). A standard multivariate regression analysis adjusted for the randomization schedule was used to identify statistically significant predictors of costs among the variables that differed between samples or randomization groups. All statistical analyses were performed with SPSS software (version 10.0; SPSS Inc., Chicago, IL).
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RESULTS |
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During the study period, 74% of all patients died. Estimated cumulative mortality for the first 2 years was approximately 88% for both treatment schedules (Fig. 1). The survival curves decreased with an almost constant rate.
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We also assessed the average EQ-5D utility as a function of the remaining lifetime, rather than a function of the time since randomization (Fig. 2). Toward the end of life, the valuation of health markedly decreased, to an average valuation of approximately 0.00 (equivalent to death). Sixteen percent of all utility measurements were negative, indicating health states valued as worse than death.
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We estimated the medical costs of radiotherapy for the constructed typical radiotherapy department (Table 3). The total annual costs for this typical department were 5.391 million dollars. It used a total of 48 full-time equivalent personnel, including 6.7 full-time equivalent radiation oncologists. Approximately two-thirds of the costs of personnel were attributed to the treatments (mainly radiation oncologists and planning) and approximately one-third to the sessions (radiation therapists and technologists). The typical department had 2.3 linear accelerators. The costs of equipment were approximately equally distributed over the three allocation bases: treatments (simulation, planning, and maintenance), sessions (because linear accelerators wear out by turning them on and off), and gray (because linear accelerators wear out according to the duration of the on-period). Costs of housing were primarily assigned to the sessions (i.e., for patient waiting rooms and the linear accelerators), but also to the treatments (i.e., for staff). Costs of overhead were primarily assigned to the treatments and, therefore, do not contribute to the difference in costs between both schedules. The estimated medical costs per allocation base were $1678 per treatment, $96.55 per session, and $7.95 per gray. After multiplying by the appropriate numbers for each radiotherapy schedule, the estimated medical costs were $1838 for the single-fraction schedule and $2448 for the multiple-fraction schedule. The estimated difference in medical costs for the initial radiation treatment was therefore $610.
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Societal Costs
Of all possible lifetime cost questionnaires, 78% were obtained and used to estimate health care utilization and costs (Table 4). The medical costs (excluding radiotherapy treatment costs) consisted mainly of the costs associated with hospitalizations. They were equivalent in size to radiotherapy treatment costs, but the difference between the randomization groups was not statistically significant (P = .18).
The total nonmedical costs other than for radiotherapy were small because the additional costs were compensated by the value of the provided labor. Although some of the differences in these nonradiotherapy cost items were considerable, they were all not statistically significant (P.19).
The overall medical costs (including the medical costs of radiotherapy and all other medical costs) were estimated to be $1344 lower for patients in the single-fraction group than for patients in the multiple-fraction group (95% CI = $214 to $2904). Similarly, the overall societal costs, including all medical and all nonmedical costs, were estimated to be $1753 lower for patients in the single-fraction group (95% CI = $99 to $3604). However, both overall differences were not statistically significant (P = .09 and P = .06, respectively).
Because the differences in initial pain score and sex (Table 1) could have influenced the comparison, we performed a multivariate regression analysis of the estimated radiotherapy costs, the medical costs, and the societal costs. After adjusting for the randomization schedule, costs were not statistically significantly predicted by the initial pain score (P = .37, P = .95, and P = .60, respectively) or by sex (P = .66, P = .52, and P = .38, respectively). Also, the estimated QALYs of the patients who filled out the cost questionnaires did not differ from the estimated QALYs in the entire sample (P = .25 for the single-fraction group and P = .95 for the multiple-fraction group).
CostUtility Analysis
The estimated QALYs and societal costs both favored the single-fraction treatment schedule, providing an additional 1.7 quality-adjusted weeks and saving $1753 relative to the multiple-fraction schedule, although in neither case was the difference statistically significant. Consequently, the single-fraction schedule is likely to be more cost-effective than the multiple-fraction schedule. The statistical certainty of this statement depends, however, on the relative value of QALYs compared with the relative value of money; that is, on how much one is willing to pay per QALY. If, on the one hand, QALYs are infinitely more valuable than money, then comparing costutility reduces to comparing QALYs (Table 2, P = .21). If, on the other hand, money is infinitely more valuable than QALYs, then comparing costutility reduces to comparing societal costs (Table 4
, P = .06).
It is difficult to say how much society is willing to pay for a QALY. A rule of thumb that is often quoted in the international literature is that $50 000 per QALY is acceptable, whereas $100 000 per QALY might not be acceptable (22). We tested cost-effectiveness by comparing the net benefit in both randomization groups: the better cost-effectiveness of the single-fraction treatment schedule is demonstrated if the net benefit in the single-fraction group is statistically significantly better than that in the multiple-fraction group. The derived P values for different levels of the willingness-to-pay were then plotted in acceptability curves (Fig. 4). From a societal perspective, the better cost-effectiveness of the single-fraction radiotherapy was statistically significant if one values a QALY between $5000 and $40 000. When a QALY is valued at less than $5000 or more than $40 000, then better cost-effectiveness of the single-fraction schedule was still likely but no longer statistically significant. For example, at $50 000 and $100 000 per QALY, the statistical significance was P = .06 and P = .09, respectively.
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DISCUSSION |
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In the costutility analysis presented here, effectiveness was measured by quality-adjusted life expectancy; that is, the overall valuation of health. Again, we found no statistically significant difference between single- and multiple-fraction radiotherapy. The average nonadjusted life expectancies were 43.0 weeks for the single-fraction schedule and 40.4 weeks for the multiple-fraction schedule, which was not a statistically significant difference. The societal value of these life expectancies was assessed using the EQ-5D questionnaire, taking into account mobility, self-care, usual activities, pain/discomfort, and anxiety/depression. Besides these general attributes, there are other issues that are also specifically relevant in the valuation of end-of-life care (23). For example, psychosocial outcomes such as relieving the burden of care and strengthening relationships with loved ones are not included in the EQ-5D. Unfortunately, however, no valuation instrument exists that incorporates these specific end-of-life issues. Moreover, we noted a distinct decrease of the EQ-5D utility over time, especially toward the end of life, suggesting that the instrument is responsive to the changing health status of these patients. On the basis of the EQ-5D measurements, the average quality-adjusted life expectancies were 17.7 weeks in the single-fraction group and 16.0 weeks in the multiple-fraction group, which was not a statistically significant difference.
From the patient perspective, it is obvious that a single-fraction schedule is less burdensome than a multiple-fraction schedule. The one outcome measure in our study that could make patients favor the multiple-fraction over a single-fraction treatment schedule is the probability of retreatment: 7% for the multiple-fraction group versus 25% for the single-fraction group. Although this is a considerable difference, an extra single fraction may still be experienced as less burdensome by most patients than a multiple-fraction schedule. Furthermore, we believe that the difference in retreatment is not so much caused by inadequacy of the single-fraction schedule, but more by the doctors' opinions on expected effectiveness and tolerance after the single dose. During the study, radiation oncologists seemed reluctant to accept the single-fraction schedule as a reliable treatment. Compared with the multiple-fraction group, patients in the single-fraction group were retreated at a lower pain score (6.8 versus 7.5 in the single- and multiple-fraction groups, respectively) (9).
The costs of radiotherapy for the single- and the multiple-fraction radiotherapy schedules, including retreatments and nonmedical costs of radiotherapy, were estimated at $2438 and $3311, respectively. Including other societal costs increased the estimated costs to $4700 for single-fraction radiotherapy and $6453 for multiple-fraction radiotherapy, a difference of $1753. Because the estimated societal costs and the quality-adjusted life expectancy were both favorable for single-fraction radiotherapy, the combined cost-effectiveness clearly favors this treatment schedule. For willingness-to-pay between $5000 and $40 000 per QALY, the better cost-effectiveness of the single-fraction schedule was statistically significant relative to the multiple-fraction schedule. The reliability of these estimates may be less for radiotherapy institutions outside The Netherlands because costs can vary substantially by country or even by radiotherapy institution.
Efficient use of the available treatment capacity is an important issue because new types of radiotherapy techniques, such as conformal radiotherapy and intensity-modulated radiotherapy (24,25), require skilled personnel and more treatment time per patient. Moreover, as the population ages, the number of patients increases. As a result of the trial and facilitated by the fact that in The Netherlands the financial reimbursement is not directly proportional to the number of fractions prescribed (26), all 21 Dutch radiotherapy institutions have adopted single-fraction radiotherapy as their standard treatment (27). The reduction of the waiting time resulting from insufficient treatment capacity, rather than lower costs, is considered the major economic advantage to single-fraction radiotherapy (9,28). In The Netherlands, the annual number of radiotherapy treatments is approximately 40 000 (28), with a total of approximately 640 000 fractions. Because 10% of the treatments are palliative radiotherapy for patients with painful bone metastases and because before the Dutch Bone Metastasis Study such patients, on average, received six fractions per treatment, using only single-fraction schedules saves approximately 3% of the national linear accelerator capacity and departmental workload.
Controversial medical decisions are often those that are made in a field of conflicting interests. We believe this is not the case here. Compared with multiple-fraction therapy, single-fraction therapy provides equal palliation to patients and reduces the number of journeys to the hospital. Single-fraction therapy is more easily included into departmental schedules, reducing both medical and societal costs and saving treatment capacity for other patients. Therefore, single-fraction radiotherapy should be considered as standard palliative treatment for patients with painful bone metastases.
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APPENDIX |
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The Dutch Bone Metastasis Study Group consists of the steering committee (Jan Willem H. Leer, Elsbeth Steenland, Yvette M. van der Linden, Hans van Houwelingen, Wendy J. Post, Job Kievit, Wilbert B. van den Hout, Hanneke de Haes) and the coordinators from the participating institutes (Hendrik Martijn, Department of Radiotherapy, Catharina Hospital, Eindhoven; Bing Oei, Dr. Bernard Verbeeten Institute, Tilburg; Ernest Vonk, Department of Radiotherapy, Deventer Hospital, Deventer; Elzbieta M. van der Steen-Banasik, Arnhem Radiation Institute, Arnhem; Ruud G. J. Wiggenraad, Department of Radiotherapy, Haaglanden Medical Center, The Hague; Jaap Hoogenhout, Department of Radiotherapy, St. Radboud Medical Center, Nijmegen; Carla C. Wárlám-Rodenhuis, Department of Radiotherapy, University Medical Centre, Utrecht; Geertjan van Tienhoven, Department of Radiotherapy, University Medical Centre, Amsterdam; Rinus Wanders, Limburg Radiation Institute, Heerlen; Jacqueline Pomp, Department of Radiotherapy, Reinier de Graaf Hospital, Delft; Matthijs van Reijn, Department of Radiotherapy, Twente Hospital, Enschede; Ineke van Mierlo, Daniel Den Hoed Cancer Centre, Rotterdam; Ewald Rutten, Department of Radiotherapy, Medical Centre Alkmaar; Jan Metsaars, Department of Radiotherapy, Leyenburg Hospital, The Hague; Gerrit Botke, Friesland Radiation Institute, Leeuwarden; and Ben G. Szabó, Department of Radiotherapy, University Medical Centre, Groningen).
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NOTES |
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See "Appendix" for the names of the members of the Dutch Bone Metastasis Study Group.
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REFERENCES |
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1 Blitzer PH. Reanalysis of the RTOG study of the palliation of symptomatic osseous metastasis. Cancer 1985;55:146872.[Medline]
2 Ratanatharathorn V, Powers WE, Moss WT, Perez CA. Bone metastasis: review and critical analysis of random allocation trials of local field treatment. Int J Radiat Oncol Biol Phys 1999;44:118.[Medline]
3 Bone Pain Trial Working Party. 8 Gy single fraction radiotherapy for the treatment of metastatic skeletal pain: randomised comparison with a multifraction schedule over 12 months of patient follow-up. Radiother Oncol 1999;52:11121.[CrossRef][Medline]
4 Cole DJ. A randomized trial of a single treatment versus conventional fractionation in the palliative radiotherapy of painful bone metastases. Clin Oncol (R Coll Radiol) 1989;1:5962.
5 Gaze MN, Kelly CG, Kerr GR, Cull A, Cowie VJ, Gregor A, et al. Pain relief and quality of life following radiotherapy for bone metastases: a randomised trial of two fractionation schedules. Radiother Oncol 1997;45:10916.[CrossRef][Medline]
6 Nielsen OS, Bentzen SM, Sandberg E, Gadeberg CC, Timothy AR. Randomized trial of single dose versus fractionated palliative radiotherapy of bone metastases. Radiother Oncol 1998;47:23340.[CrossRef][Medline]
7 Price P, Hoskin PJ, Easton D, Austin D, Palmer SG, Yarnold JR. Prospective randomised trial of single and multifraction radiotherapy schedules in the treatment of painful bony metastases. Radiother Oncol 1986;6:24755.[Medline]
8 Roos DE. Continuing reluctance to use single fractions of radiotherapy for metastatic bone pain: an Australian and New Zealand practice survey and literature review. Radiother Oncol 2000;56:31522.[CrossRef][Medline]
9 Steenland E, Leer JW, van Houwelingen H, Post WJ, van den Hout WB, Kievit J, et al. The effect of a single fraction compared to multiple fractions on painful bone metastases: a global analysis of the Dutch Bone Metastasis Study. Radiother Oncol 1999;52:1019.[CrossRef][Medline]
10 Niewald M, Tkocz HJ, Abel U, Scheib T, Walter K, Nieder C, et al. Rapid course radiation therapy vs. more standard treatment: a randomized trial for bone metastases. Int J Radiat Oncol Biol Phys 1996;36:10859.[Medline]
11 Rasmusson B, Vejborg I, Jensen AB, Andersson M, Banning AM, Hoffmann T, et al. Irradiation of bone metastases in breast cancer patients: a randomized study with 1 year follow-up. Radiother Oncol 1995;34:17984.[CrossRef][Medline]
12 Tong D, Gillick L, Hendrickson FR. The palliation of symptomatic osseous metastases: final results of the Study by the Radiation Therapy Oncology Group. Cancer 1982;50:8939.[Medline]
13 Jensen MP, Karoly P, Braver S. The measurement of clinical pain intensity: a comparison of six methods. Pain 1986;27:11726.[CrossRef][Medline]
14 The EuroQol Group. EuroQol-a new facility for the measurement of health-related quality of life. Health Policy 1990;16:199208.[Medline]
15 Dolan P. Modeling valuations for EuroQol health states. Med Care 1997;35:1095108.[CrossRef][Medline]
16 Gold MR, Siegel JE, Russell LB, Weinstein MC. Cost-effectiveness in health and medicine. New York (NY): Oxford University Press; 1996.
17 Oostenbrink JB, Koopmanschap MA, Rutten FF. Manual for cost analyses, methods and standard prices for economic evaluations in health care. Amstelveen (The Netherlands): Dutch Health Insurance Executive Board; 2000 (in Dutch).
18 Dutch Health Insurance Executive Board. Pharmacotherapeutic compass. Amstelveen (The Netherlands): Dutch Health Insurance Executive Board; 1999 (in Dutch).
19 van Hout BA, Al MJ, Gordon GS, Rutten FF. Costs, effects and C/E-ratios alongside a clinical trial. Health Econ 1994;3:30919.[Medline]
20 Briggs AH, O'Brien BJ, Blackhouse G. Thinking outside the box: recent advances in the analysis and presentation of uncertainty in cost-effectiveness studies. Annu Rev Public Health 2002;23:377401.[CrossRef][Medline]
21 Thompson SG, Barber JA. How should cost data in pragmatic randomised trials be analysed? BMJ 2000;320:1197200.
22 Earle CC, Chapman RH, Baker CS, Bell CM, Stone PW, Sandberg EA, et al. Systematic overview of cost-utility assessments in oncology. J Clin Oncol 2000;18:330217.
23 Singer PA, Martin DK, Kelner M. Quality end-of-life care: patients' perspectives. JAMA 1999;281:1638.
24 Tubiana M, Eschwege F. Conformal radiotherapy and intensity-modulated radiotherapy: clinical data. Acta Oncol 2000;39:55567.[CrossRef][Medline]
25 Suit H. The Gray Lecture 2001: coming technical advances in radiation oncology. Int J Radiat Oncol Biol Phys 2002;53:798809.[Medline]
26 Ben Josef E, Shamsa F, Williams AO, Porter AT. Radiotherapeutic management of osseous metastases: a survey of current patterns of care. Int J Radiat Oncol Biol Phys 1998;40:91521.[Medline]
27 Lievens Y, Van den Bogaert W, Rijnders A, Kutcher G, Kesteloot K. Palliative radiotherapy practice within Western European countries: impact of the radiotherapy financing system? Radiother Oncol 2000;56:28995.[CrossRef][Medline]
28 Dutch Society for Radiotherapy and Oncology. Masterplan on radiotherapy capacity; shortage, a shared concern. Amersfoort (The Netherlands): Dutch Society for Radiotherapy and Oncology; 2000 (in Dutch).
Manuscript received February 14, 2002; revised November 12, 2002; accepted December 2, 2002.
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