HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Abstract Figures Only Full Text (PDF) All Versions of this Article: 2421051368v1 242/1/85    most recent Submit a response Alert me when this article is cited Alert me when eLetters are posted Alert me if a correction is posted Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Vincken, P. W. J. Articles by Bloem, J. L. Search for Related Content PubMed PubMed Citation Articles by Vincken, P. W. J. Articles by Bloem, J. L.

MR Imaging: Effectiveness and Costs at Triage of Patients with Nonacute Knee Symptoms¹

¹ From the Departments of Radiology (P.W.J.V., A.P.M.t.B., A.R.v.E., J.L.B.), Orthopedic Surgery (R.M.B.), Surgery (P.A.v.L.), Medical Decision Making (W.B.v.d.H.), and Medical Statistics (H.C.v.H.), Leiden University Medical Center, Albinusdreef 2, 2333 ZA Leiden, the Netherlands; Departments of Radiology (E.G.C., T.P.W.d.R.) and Orthopedic Surgery (S.d.L.), MCH Westeinde Hospital, The Hague, the Netherlands; and Departments of Radiology (W.M.C.M.) and Orthopedic Surgery (L.N.J.E.M.C.), Leyenburg Hospital, The Hague, the Netherlands. Received August 15, 2005; revision requested October 17; revision received January 8, 2006; accepted February 17; final version accepted April 28. Address correspondence to P.W.J.V. (e-mail: P.W.J.Vincken{at}lumc.nl).

	ABSTRACT

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION ADVANCE IN KNOWLEDGE References

 
Purpose: To prospectively evaluate the cost and effectiveness of magnetic resonance (MR) imaging performed to exclude the need for arthroscopy in patients with nonacute knee symptoms who are highly suspected clinically of having intraarticular knee abnormality.

Materials and Methods: The study was approved by the institutional review boards of three hospitals; informed patient consent was obtained. All 584 included patients (406 male, 178 female; mean age, 31.1 years ± 8.0 [standard deviation]) underwent MR imaging. Patients with an MR result positive for the diagnosis of intraarticular knee abnormality underwent arthroscopy (group A). Patients with a negative MR result were randomly assigned to undergo either conservative (group B) or arthroscopic (group C) treatment. Treatment was considered effective if the Noyes function score had increased 10% or more at 6 months. A cost analysis was performed from a societal perspective to compare the treatment strategy involving MR imaging with the strategy not involving MR imaging.

Results: Of the 584 patients, 294 (50.3%) were assigned to group A; 149 (25.5%), to group B; and 141 (24.1%), to group C. At 6 months, the number of patients effectively treated in group B (conservative treatment) was a mean of 5.1% ± 10.0 larger than the number of patients effectively treated in group C (arthroscopy). Owing to savings in productivity costs, total societal costs were lower with use of the strategy involving MR imaging by a mean of $153 ± 488 (P = .54).

Conclusion: MR imaging can be used without additional costs or disadvantageous effects on function to obviate arthroscopy in patients with nonacute knee symptoms who are highly suspected of having intraarticular knee abnormality.

© RSNA, 2006

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION ADVANCE IN KNOWLEDGE References

 
Arthroscopy of the knee is frequently used to diagnose and treat intraarticular abnormalities. Despite clinical selection by the orthopedic surgeon, based on history and physical examination findings, 39%–73% of arthroscopies remain diagnostic and are not used for therapy (1–4). The objective is to use this invasive procedure primarily for treatment and to limit the number of nontherapeutic arthroscopies performed. During the past 15 years, magnetic resonance (MR) imaging of the knee has become available as an alternative to diagnostic arthroscopy. The purpose of our study was to prospectively evaluate the cost and effectiveness of MR imaging performed to exclude the need for arthroscopy in patients with nonacute knee symptoms who are highly suspected clinically of having intraarticular knee abnormality.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION ADVANCE IN KNOWLEDGE References

 
Patients
The study was approved by the institutional review boards of the three participating hospitals; informed patient consent was obtained. Between March 1997 and October 1999, consecutive patients aged 16–45 years who had had knee symptoms—specifically, pain, swelling, instability, and/or locking—for at least 4 weeks (nonacute) and were referred to one of the three participating nonaffiliated hospitals (one academic [Leiden University Medical Center], two teaching [MCH Westeinde Hospital and Leyenburg Hospital]) were eligible for the study. All patients underwent a standardized physical examination that consisted of, at least, knee inspection, instability and meniscal provocation tests, and measurement of the circumference of both legs 15 cm above the medial joint line. In addition, anteroposterior and lateral radiographs of the knee were obtained.

Exclusion criteria were known joint disease, abnormality diagnosed earlier with MR imaging or arthroscopy, contraindication to MR imaging or arthroscopy, locked knee at presentation, a combination of locked knee and either extension deficit or positive McMurray test results, prior knee surgery, a radiographically confirmed fracture, severe osteoarthritis of the knee (Kellgren grade 4), and/or a clinical diagnosis of retropatellar chondromalacia.

Patients were included in the study if they were highly suspected clinically of having an intraarticular knee abnormality and thus arthroscopy was indicated according to the guidelines of the Dutch Orthopedic Society (5). Arthroscopy is warranted if at least one of the following clinical criteria is met at physical examination: substantial joint effusion (more than bulging sign), passive extension deficit of at least 10°, passive flexion deficit of at least 20°, instability (ie, positive varus and valgus stress, Lachman, anterior and posterior drawer, and Pivot test results), a positive result of at least one meniscal provocation test (ie, McMurray, Apley, or squat test), and atrophy of at least 2 cm relative to the contralateral leg measured 15 cm above the medial joint line. The threshold for arthroscopy is kept relatively low by the Dutch Orthopedic Society to avoid the rendering of too many false-negative diagnoses on the basis of physical examination results.

Study Design
After study inclusion, all patients first underwent MR imaging. Patients with a positive MR result (ie, in which arthroscopy was indicated on the basis of the MR findings, in concordance with high clinical suspicion) were referred for arthroscopy (group A). Patients with a negative MR result (ie, in which arthroscopy was not indicated on the basis of the MR findings alone, despite high clinical suspicion, but rather on the basis of the Dutch Orthopedic Society guidelines) were randomly assigned, by using permuted block randomization, to undergo conservative (group B) or arthroscopic (group C) treatment. The MR result was reported to the central study center by telephone, after which the patients were assigned to the groups (Figure) by one of two research physicians (A.P.M.t.B., P.W.J.V.).

View larger version (33K): [in this window] [in a new window] [Download PPT slide]   Flow diagram outlining study design and number of patients enrolled in the study. IAP = intraarticular pathology. PE = physical examination.

All MR findings were prospectively and individually evaluated by one of five available musculoskeletal radiologists (including J.L.B., W.M.C.M., T.P.W.d.R., and E.G.C., with 2–12 years experience in musculoskeletal MR imaging). The medical history, physical examination findings, and radiographs of each patient at study entry were available to the radiologist. All MR findings were recorded on a standardized case record form. The MR result was categorized as negative (arthroscopy not indicated), equivocal, or positive (arthroscopy indicated) according to the criteria outlined in Table 1. The term negative MR finding in this context does not imply that there was no intraarticular abnormality but rather that there was no intraarticular abnormality that necessitated therapeutic arthroscopy. By using all available information, a panel consisting of the radiologist who evaluated the MR result and the orthopedic surgeon assigned the patients with equivocal MR findings to group A or randomized group B or C.

MR Imaging
The MR examinations were performed at all three hospitals by using the same 0.5-T system (Gyroscan T5; Philips Medical Systems, Best, the Netherlands) and the same software with a dedicated transmit-receive knee coil.

The standardized MR imaging protocol consisted of three sequences: sagittal dual spin echo, coronal dual spin echo, and sagittal T1-weighted three-dimensional gradient echo with frequency-selective fat suppression. A 140–160-mm field of view and an echo time of 20 or 80 msec were used for both spin-echo sequences. For coronal dual spin-echo imaging, a repetition time of 2100 msec, matrix of 256 x 205, and section thickness of 5 mm with a 0.5-mm intersection gap were used. For sagittal dual spin-echo imaging, a repetition time of 2350 msec, matrix of 256 x 179, and section thickness of 4 mm with a 0.4-mm intersection gap were used. The parameters for sagittal frequency-selective fat-suppressed T1-weighted three-dimensional gradient-echo imaging were 70-msec repetition time, 13-msec echo time, 45° flip angle, 160-mm field of view, 256 x 205 matrix, and 4-mm section thickness with a 2-mm overlap. The total imaging time for the standard MR imaging protocol (including the initial survey sequence) was 26 minutes.

Arthroscopy
All arthroscopic examinations were performed by an orthopedic surgeon or a resident supervised by an orthopedic surgeon. A total of 17 surgeons (including S.d.L., R.M.B., L.N.J.E.M.C., and P.A.v.L., with 1–21 years experience) participated in the study. At each participating hospital, one orthopedic surgeon was assigned to the panel that decided the diagnosis in the cases of equivocal MR findings.

Like the radiologist, the surgeon was informed of the patients' medical history and physical examination findings. The surgeon, however, was informed of the MR category (positive or negative findings) only—not the detailed MR diagnosis. An arthroscope with a 30° viewing angle was introduced into the knee through an anterolateral or transpatellar portal. All structures were not only visualized but also probed. After the standardized diagnostic part of the arthroscopic examination, the arthroscopist reported an arthroscopic diagnosis and the therapeutic intentions, if any. For this report, a standardized case record form identical to that used to record the MR findings was used. The researcher then revealed the detailed MR diagnosis to the arthroscopist. In cases of discrepancy, the arthroscopist then examined the joint again. Then, depending on the second-look findings, the arthroscopist either terminated the procedure or continued to the therapeutic portion of the examination.

Outcome Measures
All patient demographic data, clinical characteristics, MR findings, and findings of arthroscopy (if performed) were recorded. The MR and arthroscopic findings were considered to be intermediate outcome measures.

Effectiveness.—Knee function and symptoms were assessed during interviews with the patients at the time of MR imaging and at 3- and 6-month intervals by using Noyes function scores, which ranged from 200 (indicating poor function) to 550 (indicating good function), and Noyes symptom scores, which ranged from 0 (indicating serious symptoms) to 400 (indicating no symptoms) (6,7). The patients were interviewed by one of two research physicians (A.P.M.t.B., P.W.J.V.).

The Noyes scale for symptoms was used in group B to determine whether the treatment for some patients should be changed to arthroscopy after 3 months of conservative treatment. Patients were scheduled for arthroscopy if the initial Noyes symptom score had not increased at least 10% at 3 months. The mean interval between MR imaging and arthroscopy in group B was 136.3 days ± 57.2 (median, 126.0 days; range, 83–321 days).

The Noyes function score at 6 months was chosen as the primary outcome parameter for determining the effectiveness of each treatment strategy. We considered a treatment strategy to be effective if the initial Noyes function score had increased at least 10% at 6 months. The orthopedic surgeons who were involved in the study design considered this value, on the basis of their experience, to be a realistic increase during a period of 6 months after successful therapy, whether this be conservative or arthroscopic treatment. The cutoff value was therefore empirically determined.

Costs.—The economic evaluation was performed from a societal perspective and included assessment of the medical and productivity costs during the initial 6 months after randomization to the treatment groups. Costs are reported in U.S. dollars and were updated to the 2005 price level by using the Dutch consumer price index (www.cbs.nl). The cost analyses involved the evaluation of volumes (ie, numbers of procedures and other cost elements) and prices.

Volumes were determined from the study registrations for initial consultation with the orthopedic surgeon, MR examination (including subsequent consultations), and arthroscopy (including hospital stays and postoperative consultations). These data were supplemented by volumes of secondary medical care (ie, consultations, physiotherapy sessions, hospitalizations, medications, and out-of-pocket expenses) and days of absenteeism (from work) reported by the patients in two quarterly cost diaries. These diaries were handed in and discussed with the patients at 3 and 6 months.

Detailed cost analyses of MR imaging and arthroscopy were performed at the three participating centers and included assessment of the costs of different staff members, equipment, material, housing, and overhead items and of the costs in time and travel of the patients. The money spent on medical aids was gleaned from the diaries. The costs of other health care entities were determined according to standard Dutch prices that were designed to reflect societal costs and standardize economic evaluations (8,9). The time and travel costs for medical care were based on national averages for the duration of health care and the travel distances calculated from postal codes. The costs for absenteeism were calculated by using the patients' reported actual gross income per day according to the friction cost method; for our study duration of 6 months, these values amounted to the costs for all reported absenteeisms.

Data and Statistical Analyses
All performed analyses were based on the intention to treat principle. The effectiveness of different treatment strategies was compared by using ² tests. Costs were compared by using standard unequal-variance t tests. All analyses were performed by using SPSS for Windows (release 11.5.0; SPSS, Chicago, Ill).

Effectiveness.—We compared the effectiveness of the treatments performed in groups B (conservative treatment) and C (arthroscopy) to determine whether treatment B would not be inferior to treatment C. We expected treatment C to be effective in 90% of the patients. We allowed a noninferiority margin of 15% and accepted an effectiveness of 75%.

We computed a sample size of 91 patients per group ( = 5% one sided, 1 – ß = .90) for the case in which treatment B was actually as effective as treatment C. Since we expected about 50% of the patients to be randomly assigned between groups B and C, we needed to include a total of 364 patients (two groups times two times 91 patients). To establish noninferiority of treatment B, we reported confidence intervals for the differences between treatments B and C.

Costs.—In our economic evaluation, we compared the results of a treatment scenario involving MR imaging with the results of a scenario not involving MR imaging. If in the strategy involving MR imaging denotes the fraction of patients with a negative MR examination result who do not require arthroscopic treatment, the difference in costs between the two strategies is calculated as follows:

where C_A,in represents the costs for group A with MR imaging included; C_A,ex, the costs for group A with MR imaging excluded; C_B,in, the costs for group B with MR imaging included; C_B,ex, the costs for group B with MR imaging excluded; C_C,ex, the costs for group C with MR imaging excluded; and C_MR, the costs for MR imaging.

The power calculation for the economic evaluations was based on the break-even fraction (₀), for which the difference in costs between the strategy with and the strategy without MR imaging is zero. On the basis of a priori data on average costs per patient, we estimated a ₀ of 0.4. For larger values, the strategy with MR imaging is cost-effective.

The sample size calculation was based on the results of testing equals ₀ versus is greater than _0. To show a difference of 10%, we needed 206 patients ( = 5% one-sided, 1 – ß = .90). In practice, we would not use estimated average costs but rather the actual costs per patient. Differences in cost between the strategy with and the strategy without MR imaging are reported as 95% confidence intervals of the mean costs. The width of these intervals around the difference in costs between the strategies was calculated as times the width of the standard 95% confidence interval of the mean difference in costs between treatment groups B and C. This approach ignores the uncertainty in the estimated MR-negative fraction . Ignoring this uncertainty is justified because the much larger uncertainty in the cost difference dominates the uncertainty in their independent product.

Study sample size and sensitivity analysis.—On the basis of the computations described for effectiveness and costs, we determined that we needed to include about 400 patients. We performed univariate sensitivity analysis of our data on the percentage of negative-result MR examinations and the costs of MR imaging and arthroscopy.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION ADVANCE IN KNOWLEDGE References

 
Of the 962 patients who agreed to participate in the study, 378 either were excluded (103 patients) or had negative physical examination findings according to the Dutch Orthopedic Society guidelines (275 patients). In the remaining 584 patients (178 female, 406 male; mean age, 31.1 years ± 8.0 [standard deviation]), arthroscopy was indicated according to Dutch Orthopedic Society guidelines. The data regarding 430 of these patients (those included between March 1997 and October 1998) had been used in a prior study (10). The mean interval between study inclusion and MR imaging was 10.9 days ± 9.2 (median, 8.0 days; range, 0–77 days).

Effectiveness
All 584 patients were interviewed at the time of MR imaging (Figure). Initially, 289 patients had MR findings positive for intraarticular knee abnormality, 285 had negative MR findings, and 10 had equivocal MR findings. The panel concluded that five of the patients with equivocal findings needed arthroscopy (group A) and five did not (randomly assigned to group B or C). Thus, 294 (50.3%) patients were assigned to undergo arthroscopy (group A). The remaining 290 patients were randomly assigned to undergo conservative (group B, 149 [25.5%] patients) or arthroscopic (group C, 141 [24.1%] patients) therapy (Table 2). Two hundred seventy-seven (94.2%) group A patients, 126 (89.4%) group C patients, and 28 (18.8%) group B patients underwent arthroscopy. Seventeen group A patients and 15 group C patients did not undergo arthroscopy. Of these 32 patients, 17 were lost to follow-up and 15 refused to undergo or delayed undergoing arthroscopy for various reasons, including sufficient subsiding of symptoms during wait to undergo arthroscopy (eight patients).

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION ADVANCE IN KNOWLEDGE References

 
MR imaging of the knee in patients with nonacute knee symptoms who are highly suspected clinically of having an intraarticular knee abnormality can be used to obviate arthroscopy, with nonsignificant differences in total societal costs. On the basis of the negative MR findings in our study, arthroscopy and conservative management had similar effectiveness and costs at 6 months.

To our knowledge, no other multicenter prospective randomized studies in which clinical outcome was used and total societal costs (including medical and productivity costs) were calculated have been published. However, investigators in several studies have addressed the question of whether MR imaging can be used cost effectively or assessed the value of MR imaging as a diagnostic examination (1–4,11–17). In these studies, intermediate outcome parameters (eg, diagnostic accuracy of MR imaging) or the influence of MR imaging on therapy was used to assess the value of MR imaging. We also used part of our patient group (those included between March 1997 and October 1998, hence the difference in the number of reported patients between the present study and our previous investigation) to compare the diagnostic accuracy of MR imaging with that of arthroscopy (10). One study involving the use of clinical outcome was a single-center randomized controlled trial conducted by Bryan et al (18) in which 118 patients were randomly assigned to be examined with MR imaging or arthroscopy. That study had similar results: The use of MR imaging led to a decreased number of arthroscopies without increased overall costs or associated worsened outcomes.

Knowing the prevalence of treatable knee abnormalities in the given population is critical to the efficient application of MR imaging to exclude patients for arthroscopy. In our study population, which was selected by the orthopedic surgeon on the basis of clinical examination findings, the prevalence of treatable abnormalities seen at MR imaging was only 50%. The prevalences of abnormalities in other studies have been similar to the prevalence in our study. Ruwe et al (2) found, in a group of 103 patients with clinical findings that necessitated diagnostic arthroscopy, MR abnormalities in 41 (40%) patients. Rappeport et al (12) found in 47 patients suspected of having intraarticular knee injuries 27 (57%) patients with MR abnormalities. To our knowledge, only Bui-Mansfield et al (4) have observed, in a group of 50 patients, a prevalence of knee abnormality that was substantially higher (35 [70%] patients) than that observed in our study. The fact that their study population consisted predominantly of male military personnel might explain this difference.

The results of sensitivity analysis of our data suggest that use of the strategy involving MR imaging will significantly reduce societal costs when the prevalence of MR abnormalities is lower than 75%. The percentage of positive-result MR examinations in all of the preselected populations described was lower than 75%. Our economic evaluations were based on conditions in the Netherlands, and the generalization to other settings may be influenced by differences in economic climate and treatment patterns. However, our sensitivity analysis revealed that the costs of MR imaging can more than double, to $1233, before the societal costs of the strategy not involving MR imaging are significantly preferred, whereas lowering the costs of arthroscopy will not lead to a significant preference for the strategy not involving MR imaging.

Other considerations, in addition to effectiveness and cost, may guide the decision to use or not to use the MR imaging strategy. For instance, the wait to undergo both procedures may have a decisive role. When the wait to undergo arthroscopy is long, MR imaging can be used to reduce the number of arthroscopies performed and shorten the wait. On the other hand, if the wait to undergo MR imaging is long, no such gain is expected. In the Netherlands, MR units are commonplace in hospitals and waiting lists for MR imaging of the knee are short compared with these lists some years ago, when the wait to undergo this examination could be several months.

Apart from the societal considerations used to decide whether MR imaging should be performed to select patients for arthroscopy, on an individual level, the ability to prevent unnecessary arthroscopy by using MR imaging also may have a role in this decision. When an arthroscopic procedure is not performed for therapeutic purposes, no health gain can be expected from it. The prolonged morbidity after diagnostic arthroscopy, compared with that after MR imaging, and the risk of complications with arthroscopy may guide the decision of the orthopedic surgeon and the patient to use MR imaging initially.

There were some limitations in our study. As mentioned earlier, the generalization of our present study findings to other settings may be influenced by differences in not only the economic climate but also the treatment patterns of different countries. For instance, in the Netherlands, an isolated tear of the anterior cruciate ligament is not considered an indication for therapeutic arthroscopy for the general population because the initial therapy of choice is physiotherapy. In other countries, however, early anterior cruciate ligament reconstruction is considered the therapy of choice for certain patients, and, thus, isolated tear of the anterior cruciate ligament is an indication for arthroscopy. However, the number of these patients with isolated tears of the anterior cruciate ligament would be small, and these differences would not substantially alter our results.

Other possible limitations were our use of a 0.5-T MR system and the probability that MR and arthroscopy techniques have changed since 2000 (the year in which the last arthroscopies were performed in our study). A comprehensive review (19) revealed that the magnetic field strength does not significantly affect the performance of MR systems in the detection of meniscal abnormalities. In our study population, the majority of arthroscopies (90%, for 265 of 294 positive-result MR examinations) were indicated because of a meniscal abnormality (10). To our knowledge, no important developments in the diagnosis and treatment of meniscal tears have been reported in the past 2 years. The most promising changes reported have been in the diagnosis and treatment of cartilage lesions, which were not prevalent in our study population.

We therefore conclude that in patients with nonacute knee symptoms who are highly suspected clinically of having an intraarticular knee abnormality, MR imaging can be used to obviate arthroscopy, without additional societal costs or disadvantageous effects on function.

	ADVANCE IN KNOWLEDGE

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION ADVANCE IN KNOWLEDGE References

 

• In patients with nonacute knee symptoms who are highly suspected clinically of having an intraarticular knee abnormality, MR imaging can be used to obviate arthroscopy, without additional societal costs or disadvantageous effects on function.
  

	FOOTNOTES

 
Authors stated no financial relationship to disclose.

Author contributions: Guarantor of integrity of entire study, J.L.B.; study concepts/study design or data acquisition or data analysis/interpretation, all authors; manuscript drafting or manuscript revision for important intellectual content, all authors; manuscript final version approval, all authors; literature research, P.W.J.V., A.P.M.t.B., A.R.v.E., W.B.v.d.H., H.C.v.H., J.L.B.; clinical studies, P.W.J.V., A.P.M.t.B., A.R.v.E., E.G.C., T.P.W.d.R., S.d.L., W.M.C.M., L.N.J.E.M.C., R.M.B., P.A.v.L., J.L.B.; statistical analysis, P.W.J.V., A.P.M.t.B., W.B.v.d.H., H.C.v.H., J.L.B.; and manuscript editing, all authors

	References

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION ADVANCE IN KNOWLEDGE References

 

1. Tait GR, Maginn P, Macey AC, Beverland DE, Mollan RA. Unnecessary arthroscopies. Injury 1992;23(8):555–556.[CrossRef][Medline]
2. Ruwe PA, Wright J, Randall RL, Lynch JK, Jokl P, McCarthy S. Can MR imaging effectively replace diagnostic arthroscopy? Radiology 1992;183(2):335–339.[Abstract/Free Full Text]
3. Carmichael IW, MacLeod AM, Travlos J. MRI can prevent unnecessary arthroscopy. J Bone Joint Surg Br 1997;79(4):624–625.
4. Bui-Mansfield LT, Youngberg RA, Warme W, Pitcher JD, Nguyen PL. Potential cost savings of MR imaging obtained before arthroscopy of the knee: evaluation of 50 consecutive patients. AJR Am J Roentgenol 1997;168(4):913–918.[Abstract/Free Full Text]
5. NOV (Nederlandse Orthopaedische Vereniging) ism CBO (Centraal Begeleidingsorgaan voor de Intercollegiale Toetsing). Consensus Arthroscopie, 1992.
6. Barber SD, Noyes FR, Mangine RE, McCloskey JW, Hartman W. Quantitative assessment of functional limitations in normal and anterior cruciate ligament-deficient knees. Clin Orthop Relat Res 1990;255:204–214.
7. Noyes FR, Barber SD, Mooar LA. A rationale for assessing sports activity levels and limitations in knee disorders. Clin Orthop Relat Res 1989;246:238–249.
8. Oostenbrink JB, Koopmanschap MA, Rutten FFH. Handleiding voor kostenonderzoek, methoden en richtlijnprijzen voor economische evaluaties in de gezondheidszorg. Diemen, the Netherlands: College voor zorgverzekeringen, 2000.
9. Oostenbrink JB, Koopmanschap MA, Rutten FF. Standardisation of costs: the Dutch manual for costing in economic evaluations. Pharmacoeconomics 2002;20(7):443–454.[CrossRef][Medline]
10. Vincken PW, ter Braak BP, van Erkel AR, et al. Effectiveness of MR imaging in selection of patients for arthroscopy of the knee. Radiology 2002;223(3):739–746.[Abstract/Free Full Text]
11. Birch N, Powles D, Dorrell H, Brooks P. The investigation and treatment of disorders of the knee: indications and a cost-comparison of arthroscopy and magnetic resonance imaging. Health Trends 1994;26(2):50–52.[Medline]
12. Rappeport ED, Wieslander SB, Stephensen S, Lausten GS, Thomsen HS. MRI preferable to diagnostic arthroscopy in knee joint injuries: a double-blind comparison of 47 patients. Acta Orthop Scand 1997;68(3):277–281.[Medline]
13. Ruwe PA, McCarthy SM. Cost effectiveness of magnetic resonance imaging of the knee. Magn Reson Imaging Clin N Am 1994;2(3):475–479.[Medline]
14. Spiers AS, Meagher T, Ostlere SJ, Wilson DJ, Dodd CA. Can MRI of the knee affect arthroscopic practice? a prospective study of 58 patients. J Bone Joint Surg Br 1993;75(1):49–52.
15. Stull MA, Nelson MC. The role of MRI in diagnostic imaging of the injured knee. Am Fam Physician 1990;41(2):489–500.[Medline]
16. Warwick DJ, Cavanagh P, Bell M, Marsh CH. Influence of magnetic resonance imaging on a knee arthroscopy waiting list. Injury 1993;24(6):380–382.[CrossRef][Medline]
17. Weinstabl R, Muellner T, Vecsei V, Kainberger F, Kramer M. Economic considerations for the diagnosis and therapy of meniscal lesions: can magnetic resonance imaging help reduce the expense? World J Surg 1997;21(4):363–368.[CrossRef][Medline]
18. Bryan S, Bungay HP, Weatherburn G, Field S. Magnetic resonance imaging for investigation of the knee joint: a clinical and economic evaluation. Int J Technol Assess Health Care 2004;20(2):222–229.[CrossRef][Medline]
19. Oei EH, Nikken JJ, Verstijnen AC, Ginai AZ, Myriam Hunink MG. MR imaging of the menisci and cruciate ligaments: a systematic review. Radiology 2003;226(3):837–848.[Abstract/Free Full Text]

This Article Abstract Figures Only Full Text (PDF) All Versions of this Article: 2421051368v1 242/1/85    most recent Submit a response Alert me when this article is cited Alert me when eLetters are posted Alert me if a correction is posted Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Vincken, P. W. J. Articles by Bloem, J. L. Search for Related Content PubMed PubMed Citation Articles by Vincken, P. W. J. Articles by Bloem, J. L.