|Year : 2019 | Volume
| Issue : 2 | Page : 289-296
|New instrumentation improves patient satisfaction and component positioning for mobile-bearing medial unicompartmental knee replacement
Rajesh Malhotra1, Vijay Kumar1, Naman Wahal1, Arnaud Clavé2, James A Kennedy2, David W Murray2, Hemant Pandit3
1 Department of Orthopaedics, All India Institute of Medical Sciences, New Delhi, India
2 Nuffield Department of Orthopaedics, Rheumatology and Musculoskeletal Sciences, Botnar Research Centre, University of Oxford, Oxford, UK
3 Nuffield Department of Orthopaedics, Rheumatology and Musculoskeletal Sciences, Botnar Research Centre, University of Oxford, Oxford; Leeds Institute of Rheumatic and Musculoskeletal Medicine, University of Leeds, Leeds, UK
Click here for correspondence address and email
|Date of Web Publication||22-Feb-2019|
| Abstract|| |
Background: The Oxford unicompartmental knee replacement (OUKR) has achieved excellent functional outcomes and long term survivorship in many single center and single surgeon series. However, in national registries, the failure rates are up to three times higher than total knee replacement. This is at least in part due to difficulty experienced by low-volume surgeons in implanting the prosthesis accurately. A new instrumentation system (Microplasty) was introduced to help surgeons achieve better component positioning, however, it is not known whether the new instruments achieve that goal. This study investigates whether the new system achieves better component positioning and whether it improves the clinical outcomes when compared to the existing instruments. Materials and Methods: This retrospective cohort study compared 50 consecutive OUKR implanted using the conventional Phase 3 instrumentation with 100 consecutive OUKR implanted using the new Microplasty instrumentation. Component orientation was measured on postoperative radiographs, and the percentage outside the recommended range was identified. Intraoperative data and retrospectively collected clinical data were also analyzed. Results: Femoral component alignment improved significantly, and there were no outliers in the Microplasty group. Although there were fewer tibial component alignment outliers with Microplasty, the difference was not significant. The intraoperative incidence of tibial recut, patient satisfaction and patient expectations was significantly better in the Microplasty group. The Oxford Knee Scores were also better with Microplasty, however, the difference was not significant. Conclusion: Microplasty instrumentation helps the surgeon achieve optimal component positioning and reduces the need for tibial recut. The clinical outcomes are also better with the Microplasty instrumentation.
Keywords: Alignment, Microplasty, outcomes, unicompartmental knee replacement
|How to cite this article:|
Malhotra R, Kumar V, Wahal N, Clavé A, Kennedy JA, Murray DW, Pandit H. New instrumentation improves patient satisfaction and component positioning for mobile-bearing medial unicompartmental knee replacement. Indian J Orthop 2019;53:289-96
|How to cite this URL:|
Malhotra R, Kumar V, Wahal N, Clavé A, Kennedy JA, Murray DW, Pandit H. New instrumentation improves patient satisfaction and component positioning for mobile-bearing medial unicompartmental knee replacement. Indian J Orthop [serial online] 2019 [cited 2019 Aug 23];53:289-96. Available from: http://www.ijoonline.com/text.asp?2019/53/2/289/252662
| Introduction|| |
In patients with symptomatic end-stage anteromedial osteoarthritis (AMOA) or medial osteonecrosis of the knee joint, unicompartmental knee replacement (UKR) is an effective treatment with the advantages of significantly lower morbidity and mortality. A higher percentage of good or excellent patient reported outcomes, and a more rapid recovery is noted, as compared to total knee replacement (TKR).
The Oxford UKR (OUKR), which is the most commonly performed UKR, has demonstrated excellent functional outcomes and long term survivorship similar to that of the best TKR in many single center and single-surgeon series.,,,, However, this is not reflected in the national registers which typically show a revision rate about three times higher with UKR than TKR. This disparity is at least in part due to lower UKR caseload per surgeon. According to the National Joint Registry of England and Wales (NJR), between 2004 and 2012, users of UKR performed an average of 5.4 UKRs/year, with 25% doing only one UKR/year and this was the most common UKR caseload. Lower case-load contributes to the higher failure rates of UKR seen in various national joint registries. Liddle et al. demonstrated that in the NJR, the mean 8-year rate of survival of the UKRs in the hands of surgeons performing <10 UKRs/year was 88.1% (95% confidence interval [CI] = 86.9% to 88.8%) compared with 92.1% (95% CI = 90.9%-93.6%) for those who performed 30 or more per year.
One of the main reasons why low-volume surgeons have poor results is that they have difficulty accurately positioning the implant. This is particularly a problem when minimally invasive surgical (MIS) techniques are used. Since 1998, the OUKR has been implanted using this technique (Phase 3), which does not require patella eversion and minimizes soft-tissue damage resulting in a faster recovery, less postoperative pain, and better function in the long term., However, a MIS approach can make the intraoperative visualization more difficult with fewer surgical landmarks available, and as a result, the surgery may be more difficult. Some publications have highlighted the inability of the surgeons to achieve the recommended implant orientation using Phase 3 instrumentation, as these series demonstrate a substantial population of OUKRs are implanted outside the proposed limits of tolerance.,, This may in part be due to the way the Phase 3 instrumentation works. The surgeon has to judge by eye the height of the tibial cut and the femoral component orientation. As a result, many surgeons find it necessary to recut the tibia which in turn may weaken the bone or result in damage to the medial collateral ligament (MCL).
New instrumentation known as Microplasty (Zimmer Biomet, Bridgend, United Kingdom) was introduced in 2011 to make the surgery easier and to improve the reproducibility of component positioning. The instrumentation has a stylus system to ensure a more consistent tibial resection level, a femoral drill guide linked to an intramedullary rod to improve femoral orientation, and slotted saw guides , [Figure 1], [Figure 2], [Figure 3]. Although in theory, these changes should make the surgery more reproducible, limited data exist in the literature comparing the old and new instrumentation. In addition, it is not known whether these changes have resulted in better functional outcome. It is important to establish if there are any real advantages with the new instrumentation as any change in surgical technique introduces a learning curve possibly with associated harmful effects and increased costs.
|Figure 1: Microplasty instrumentation tibial resection guide with spoon/stylus and “G-clamp” for setting resection depth: lateral view. (Reproduced courtesy of Zimmer Biomet, Inc.)|
Click here to view
|Figure 2: Microplasty instrumentation tibial resection guide with spoon/stylus and “G-clamp” for setting resection depth: Anteroposterior view. (Reproduced courtesy of Zimmer Biomet, Inc.)|
Click here to view
|Figure 3: Microplasty intramedullary linked femoral alignment guide: lateral view (Reproduced courtesy of Zimmer Biomet, Inc.)|
Click here to view
Purpose and hypothesis
The aim of this single-center, two-surgeon retrospective cohort study was to answer three key questions: Does the new instrumentation improve component alignment; does it reduce the risk of tibial recut during surgery, and does it improve the clinical outcome? The study compares intraoperative findings, postoperative clinical and radiological outcomes in patients with AMOA undergoing cemented medial OUKR using either the Phase 3 or Microplasty instrumentation.
| Materials and Methods|| |
Following institutional ethical approval, we analyzed the radiographs and retrospectively collected clinical outcome data on two consecutive cohorts with a total of 150 cemented medial OUKRs implanted in 150 patients with bone-on-bone AMOA. All surgeries were performed by either of two senior surgeons (RM, VK) under spinal anesthetic with recommended indications, described surgical technique and standardized physiotherapy regime postoperatively. All patients were contacted within the last 12 months.
The first cohort consisted of the first consecutive 50 minimally invasive implantations of the Oxford UKR (OUKR) using the conventional Phase 3 instrumentation (Zimmer Biomet UK Limited, Swindon, UK) between August 2008 and July 2013 (Group A). The second cohort consisted of a consecutive series of the 100 minimally invasive OUKR with the new Oxford Microplasty instrumentation between August 2013 and May 2015 (Group B).
Operative data were collected using a standard form, which recorded surgical findings including the status of the ACL and the cartilage in the involved and the retained compartments. In addition, data on need for tibial recut, and the thickness of tibial bearing were recorded. The clinical outcome was assessed using the Oxford Knee Score (OKS), a validated patient-based questionnaire. We used this score with a minimum of 0 (worst outcome) and maximum of 48 (best outcome). Based on established criteria, patients were classified into those with excellent (OKS >41), good (OKS 34–41), fair (OKS 27–33), and poor (OKS <27). The American Knee Society Score (AKSS) was also used including assessment of patient expectations and patient satisfaction., Each patient's level of activity was recorded with the Tegner score. At the time of last followup, all patients underwent radiographic assessment in addition to detailed clinical assessment including careful recording of any perioperative complications encountered.
In all patients, anteroposterior (AP) radiographs aligned on the tibial component and lateral radiographs aligned on the femoral component were taken under fluoroscopic guidance. Weight-bearing long leg limb alignment radiographs were obtained preoperatively as well as postoperatively to assess overall limb alignment.
Femoral component varus/valgus
Measured as the acute angle between the femoral component and the femoral diaphyseal axis in the coronal plane on the screened short leg X-rays [Figure 4]. The diaphyseal axis was drawn from the femoral notch to a point bisecting the cortex at a point 10 cm proximal to the notch. A 7° subtraction was made from the measured angle to make the reported angle representative of the mechanical axis. The aim is for the femoral component to be aligned parallel to the mechanical axis. Thus, an angle of 0° was seen as neutral with a range of tolerance of ±10°.
|Figure 4: Accepted coronal alignment of tibial and femoral components. Femoral component coronal alignment: 10° varus to 10° valgus (black dashed arrow); Tibial component coronal alignment: 5° varus to 5° valgus (yellow dashed arrow)|
Click here to view
Flexion/extension of femoral component
Measured as the acute angle between a line through the center of the femoral peg and the femoral axis in the lateral short leg screened view [Figure 5]. The diaphyseal axis was measured using the posterior cortical line as described by Rees et al. The accepted range is 0° to 20° from the intramedullary rod, with an aim to flex the component 10°. As there is a femoral bow of about 5° relative to the distal femur, a 5° addition was made to the measured angle to make the reported angle representative of the mechanical axis. Thus, an angle of 10° flexion was seen as optimal, with a range of tolerance of ±10° (accepted range of 0° to 20° flexion).
|Figure 5: Accepted sagittal alignment of tibial and femoral components. Femoral component sagittal alignment: 5° extension to 15° flexion (black dashed arrow); Tibial component sagittal alignment: 7.5° ± 5° (posterior tibial slope = 90° - α). The red line represents the intramedullary rod, and angle β is between the posterior cortical line and this line (β = 5°)|
Click here to view
Tibial component varus/valgus
Measured as the acute angle between a line perpendicular to the tibial axis and a line drawn across the tibial tray in the coronal plane on a short-leg screened X-ray [Figure 4]. The axis was drawn between a point at the midpoint of the spines, and a point bisecting the cortex 10 cm distal to this point. The accepted range was 0° ± 5°.
Tibial component-anteroposterior slope
Measured as the acute angle between a line drawn along the tibial tray and a line perpendicular to the tibial axis in the lateral short-leg screened view [Figure 5]. The axis was drawn as per the proximal anatomical axis (diaphyseal) described by Yoo et al. with a line drawn to connect mid cortical points at 5 cm and 15 cm distal to the joint space. A slope of 7.5° was seen as optimal with a range of tolerance of ± 5° (thus giving an accepted range of 2° to 13°).
The hip-knee-ankle angle was measured on the standing long leg film by drawing tibial and femoral mechanical axes [Figure 6]. The acute angle subtended between the two was recorded as the leg alignment angle.
|Figure 6: Measuring lower limb alignment by tibiofemoral angle, which is the angle between femoral and tibial mechanical axis. β represents the measured angle, and this case demonstrates postoperative varus alignment|
Click here to view
A component was considered to be an outlier if any of the AP (femoral or tibial component varus/valgus) or sagittal (femoral flexion/extension or tibial slope) measurements were outside the recommended range.
For the purpose of this study comparing old with new instrumentation, two key aspects were assessed. The incidence of tibial recut and thickness of the meniscal bearing. Tibial recut introduces error and ideally should not be performed if the instrumentation is reliable in predicting correct level of horizontal tibial cut. The mobile-bearing thickness was used as an indicator for the height of the resection of the tibial plateau. A bearing size of 3 or 4 mm suggests an appropriate level of resection, whereas a bearing size of 5 mm or more indicates a level of resection too far distally, resulting in unnecessary bone loss.
The quantitative variables are expressed by mean ± standard deviation (SD) and range; and were analyzed by a Student t-test or a Mann–Whitney U-test in the case of unequal variance. Categorical variables are expressed as counts and percentages and were compared by Fisher's exact test or a Z-test. Categorical data are expressed as counts and percentages. Quantitative data are expressed by mean ± SD or range. Statistical significance was set for P ≤ 0.05. Statistical evaluation was performed using XLStat™ v. 2015 (AddInsoft, Paris, France) and Stata version 14 (STATA Corp., Texas, USA).
| Results|| |
None of the patients died as a result of surgery and none were lost to follow up. The mean age at the time of surgery for the entire cohort was 58.8 years (SD 8.3, range 41–79). There were 32 males (21%) and the mean body mass index (BMI) for the entire cohort at the time of surgery was 28.9 (SD 3, range 23–36). The mean followup was 27 months (SD 17.3, range 12–88).
The mean age for Group A was 59.8 years (SD: 8.4, range 41–79) and for Group B was 58.3 years (SD: 8.2, range 44–79). Nearly 28% of patients in Group A and 18% patients in Group B were male. The mean BMI for Group A was 29.3 (SD 2.8, range 23–35.6) and mean BMI for Group B was 28.7 (SD 3.1, range 23–36). The mean followup for Group A was 45 months (SD 17.2, range 18–88) and the mean followup for Group B was 18 months (SD 4.6, range 12–30).
The mean OKS at the time of last followup was 38.1 [SD 5.2, range 11–47, [Table 1] for Group A and 39.2 (SD 5.5, range 22–48) for Group B. The difference between the two was not statistically significant (P = 0.96). According to criteria proposed by Kalairajah et al., 38% of cases in Group A and 45% cases in Group B had excellent outcome (P = 0.41). A small proportion had poor outcome in both the groups (2% in each). The differences were not statistically significant although it showed a trend toward better outcome with the new instrumentation.
|Table 1: Clinical outcomes after Oxford unicompartmental knee replacement in Phase 3 and Microplasty groups|
Click here to view
The mean AKSS Functional was 69.9 (SD 9.9, range 15–83) for Group A and was 70.8 (SD 9.4, range 21–85) for Group B. The difference between the two was not significant (P = 0.61). The mean AKSS Satisfaction was 29.7 (SD 4.0, range 10–38) for Group A and was 32.8 (SD 4.5, range 12–40) for Group B. The difference between the two was statistically significant (P = 0.01). The mean AKSS Expectation was 10.6 (SD 2.5, range 0–14) for Group A and was 11.8 (SD 1.5, range 5–15) for Group B. The difference between the two was statistically significant (P = 0.03). The median activity score for Group A was 3 (range 0–4) and the median activity score for Group B was 3 (range 0–4). The difference between the two was not statistically significant.
The incidence of tibial recut was 22% for Group A and 5% for Group B. The difference between the two groups was statistically highly significant (P = 0.001).
The median bearing thickness was 3 mm (range 3-6) for Group A and was 3 mm (range 3–6) for Group B. In 90% cases in Group A and 96% in Group B, a size 3 or 4 bearing was used. The difference between the two groups was not statistically significant.
Femoral component varus/valgus
The mean femoral component inclination (in the coronal plane: Varus being given negative value) was 2.5° (SD 7.5, range -12 to 12) for Group A and −0.6° (SD 4.0, range -7–8) for Group B [Table 2]. The difference between the two groups was statistically significant (P = 0.001). Fifteen (30%) femoral components in Group A and no components in Group B were found to be outside the recommended range. The difference between the two groups was statistically significant (P < 0.001).
|Table 2: Radiographic parameters after Oxford unicompartmental knee replacement in Phase 3 and Microplasty groups|
Click here to view
Flexion/extension of femoral component
The mean femoral component inclination (in the sagittal plane: extension being given negative value) was 5.3° (SD 3.6, range 1–16) for Group A and 7.5° (SD 4.5, range 0–18) for Group B. The difference between the two groups was statistically significant (P = 0.002). One (2%) femoral component in Group A and no components in Group B were found to be outside the recommended range. The difference between the two groups was not statistically significant (P = 0.33)
Tibial component varus/valgus
The mean tibial inclination (in the coronal plane–varus being given negative value) was 0° (SD 3.4, range -7 to 8) for Group A and -1.5° (SD 3.9, range -10-6) for Group B (P = 0.02). Nine (18%) tibial components in Group A and 13 (13%) components in Group B were found to be outside the recommended range. The difference between the two groups was not statistically significant (P = 0.42).
Tibial component-anteroposterior slope
The mean tibial slope was 7° (SD 3.9, range 2–17) for Group A and 6.6° (SD 3.2, range 0-14) for Group B. The difference between the two groups was statistically not significant (P = 0.48). Three components (6%) in Group A and five components in Group B (5%) were found to be outside recommended range, the difference between the two groups was not statistically significant (P = 0.54).
Overall components out of range
Fifteen (30%) knees had femoral components out of range for Group A, while no femoral components were out of range for Group B [P < 0.001; [Table 3]. Twelve (24%) knees had tibial components out of range in Group A compared with 18 (18%) in Group B (P = 0.39). In total, 22 (44%) knees had components out of range in Group A, while 18 (18%) knees had components out of range for Group B (P = 0.001).
|Table 3: Radiographic outliers after Oxford unicompartmental knee replacement in Phase 3 and Microplasty groups|
Click here to view
The mean hip-knee-ankle angle was 5° of varus (SD 3.1, range 0–15) for Group A and 5° of varus (SD 3.2, range 0–14) for Group B. The difference between the two groups was statistically not significant (P = 0.94).
Partial or complete radiolucency around the tibial component was present in 64% cases in Group A and in 59% cases in Group B. The difference was not statistically significant.
| Discussion|| |
This study demonstrates that the Microplasty instrumentation decreases the numbers of radiographic outliers for the femoral component, reduces the need for tibial recut and most importantly improves the clinical outcome of the medial Oxford UKR compared to Phase 3 instrumentation. Although previous studies have shown improvement in radiographic findings,, this is the first study that has shown improvement in all three areas. The design aims of Microplasty instrumentation were to simplify the operation, to improve its reproducibility and, consequently, to improve outcomes. This study suggests that these outcomes have been achieved.
The Oxford UKR has a femoral component which is part of a sphere. It is, therefore, very forgiving of femoral malalignment. A clinical study has shown that ±10° of malalignment in any direction of the femoral component does not compromise the outcome. During the time that patients were recruited it was recommended that the femoral component should be flexed about 10° to improve the congruity of the knee in high flexion, With Phase 3 instrumentation, the orientation of the femoral drill guide which sets the component orientation was judged by eye relative to an intramedullary rod whereas with the Microplasty instrumentation the femoral drill guide is linked to an intramedullary rod so as to improve the accuracy of implantation. This study has shown that there has been marked improvement in the reproducibility of femoral component orientation with 30% of Phase 3 being outliers and none of the Microplasty being outliers. In addition, the femoral component flexion has increased with Microplasty to an average of 7.5° flexion. Ideally, this should be higher. To obtain optimal flexion when using the drill guide with Microplasty, the surgeon should aim to flex the knee to about 110° which would minimize any bending or distortion in the IM rod or linkage.
With unicompartmental replacement, it is advantageous to remove as little of the tibia as possible. Indeed, best results with the Oxford UKR are achieved when the thinnest bearings, which are 3 or 4 mm thick, are used. At 15 years, the survival with 3 or 4 bearings is 94%. It is therefore reassuring that in this study almost all the bearings used were 3 or 4. The bearing size is selected to restore the MCL tension and thus the predisease alignment. As the overall alignment of the leg is similar in both groups, it suggests that bearing size selection and preservation of the ligaments were similar with both instrumentation systems. With the Phase 3 instrumentation, surgeons judge by eye the height of the tibial cut. To avoid excess resection, surgeons tend to do conservative cuts and recut if necessary. Recuts often result in an irregular surface and may result in damage to the tibia or MCL. They are therefore best avoided. The stylus system was therefore introduced for the Microplasty instrumentation. This stylus system has decreased the need for recuts to a very low level which is a major advantage. If, with the Microplasty, the gap made following the tibial cut is slightly narrow, it can be increased by removing a small amount of cartilage from the back of the posterior part of the femur, before femoral preparation, which will further decrease the need for a recut.
With the Oxford UKR, due to the fully congruent bearing, some malalignment of the tibial component is acceptable. It has previously been shown that within the range of ±5° of either varus or valgus or posterior slope there is no difference in results. For both the Microplasty and Phase 3, the average slope and varus/valgus were satisfactory. There were fewer outliers for tibial alignment with the Microplasty instrumentation than Phase 3; however, the difference was not significant. Despite this 13% of the Microplasty, tibial components were outliers for varus/valgus and 5% for tibial slope, which is higher than expected. The main difference between the Microplasty and the Phase 3 tibial guide is that the Microplasty guide has a slot for the saw blade which should minimize the outliers. The slot was not always used; had it been used always the alignment might have been better. Other factors that could have contributed to the outliers are poorly aligned X-rays, incomplete seating of the component and tibia vara. Further study is needed to improve tibial alignment.
The most important finding of this study is that the clinical results of Microplasty were better than those of Phase 3: With Microplasty, there were significantly better levels of patient satisfaction (AKSS Satisfaction), and patient expectations (AKSS Expectation) were also met significantly more often. Although there was no statistically significant difference in the OKS, Microplasty patients did have a higher OKS than Phase 3 and a higher proportion of patients had excellent OKS. It is not clear why the clinical results were better with Microplasty, but it is likely to be multifactorial. Clearly reducing the number tibial recuts and the number of radiographic outliers will help. However, as the positioning of the components is much simpler with Microplasty, surgeons can focus on what really matters, which is accurate soft-tissue balancing.
There are limitations to our study. Patients were not randomized and part of the improvement in component alignment may be due to surgeons' experience increasing with time. However, the results are important as there are no randomized trials. The study was retrospective so we did not have preoperative OKS. As preoperative OKS influences postoperative scores, it is difficult to interpret postoperative scores without knowing that the preoperative scores were the same for both groups. However, satisfaction and achieved expectation do not require preoperative scores, so perhaps are the most relevant scores, and these showed significant improvements. The followup is relatively short particularly for the Microplasty group, so there is no information about long term revision rate.
| Conclusion|| |
The new Microplasty instrumentation for the Oxford UKR gives better clinical results than the Phase 3 instrumentation. In addition, as component positioning is better and tibial preparation is more accurate we would expect the long term implant survival to be as good or better with Microplasty. We, therefore, recommend that surgeons use the Microplasty rather than the Phase 3 instrumentation.
Declaration of patient consent
The authors certify that they have obtained all appropriate patient consent forms. In the form the patient(s) has/have given his/her/their consent for his/her/their images and other clinical information to be reported in the journal. The patients understand that their names and initials will not be published and due efforts will be made to conceal their identity, but anonymity cannot be guaranteed.
Financial support and sponsorship
This work was financially supported by the UK-India Education and Research Initiative (UKIERI).
Conflicts of interest
The author or one or more of the authors have received or will receive benefits for personal or professional use from a commercial party related directly or indirectly to the subject of this article. In addition, benefits have been or will be directed to a research fund, foundation, education institution, or other nonprofit organization with which one or more of the authors are associated.
| References|| |
Liddle AD, Judge A, Pandit H, Murray DW. Adverse outcomes after total and unicompartmental knee replacement in 101,330 matched patients: A study of data from the National Joint Registry for England and Wales. Lancet 2014;384:1437-45.
Liddle AD, Pandit H, Judge A, Murray DW. Patient-reported outcomes after total and unicompartmental knee arthroplasty: A study of 14,076 matched patients from the National Joint Registry for England and Wales. Bone Joint J 2015;97-B: 793-801.
Lisowski LA, van den Bekerom MP, Pilot P, van Dijk CN, Lisowski AE. Oxford phase 3 unicompartmental knee arthroplasty: Medium-term results of a minimally invasive surgical procedure. Knee Surg Sports Traumatol Arthrosc 2011;19:277-84.
Murray DW, Goodfellow JW, O'Connor JJ. The Oxford medial unicompartmental arthroplasty: A ten-year survival study. J Bone Joint Surg Br 1998;80:983-9.
Price AJ, Svard U. A second decade lifetable survival analysis of the Oxford unicompartmental knee arthroplasty. Clin Orthop Relat Res 2011;469:174-9.
Rajasekhar C, Das S, Smith A. Unicompartmental knee arthroplasty 2- to 12-year results in a community hospital. J Bone Joint Surg Br 2004;86:983-5.
Svärd UC, Price AJ. Oxford medial unicompartmental knee arthroplasty. A survival analysis of an independent series. J Bone Joint Surg Br 2001;83:191-4.
Liddle AD, Pandit H, Judge A, Murray DW. Effect of surgical caseload on revision rate following total and unicompartmental knee replacement. J Bone Joint Surg Am 2016;98:1-8.
Fisher DA, Watts M, Davis KE. Implant position in knee surgery: A comparison of minimally invasive, open unicompartmental, and total knee arthroplasty. J Arthroplasty 2003;18:2-8.
Pandit H, Jenkins C, Barker K, Dodd CA, Murray DW. The Oxford medial unicompartmental knee replacement using a minimally-invasive approach. J Bone Joint Surg Br 2006;88:54-60.
Pandit H, Hamilton TW, Jenkins C, Mellon SJ, Dodd CA, Murray DW, et al.
The clinical outcome of minimally invasive phase 3 Oxford unicompartmental knee arthroplasty: A 15-year followup of 1000 UKAs. Bone Joint J 2015;97-B:1493-500.
Price AJ, Webb J, Topf H, Dodd CA, Goodfellow JW, Murray DW, et al.
Rapid recovery after Oxford unicompartmental arthroplasty through a short incision. J Arthroplasty 2001;16:970-6.
Shakespeare D, Ledger M, Kinzel V. Accuracy of implantation of components in the Oxford knee using the minimally invasive approach. Knee 2005;12:405-9.
Clarius M, Hauck C, Seeger JB, Pritsch M, Merle C, Aldinger PR, et al.
Correlation of positioning and clinical results in Oxford UKA. Int Orthop 2010;34:1145-51.
Müller PE, Pellengahr C, Witt M, Kircher J, Refior HJ, Jansson V, et al.
Influence of minimally invasive surgery on implant positioning and the functional outcome for medial unicompartmental knee arthroplasty. J Arthroplasty 2004;19:296-301.
Hurst JM, Berend KR. Mobile-bearing unicondylar knee arthroplasty: The Oxford experience. Clin Sports Med 2014;33:105-21.
Hurst JM, Berend KR, Adams JB, Lombardi AV Jr. Radiographic comparison of mobile-bearing partial knee single-peg versus twin-peg design. J Arthroplasty 2015;30:475-8.
Goodfellow J, O'Connor J, Pandit H, Dodd CA, Murray D. Unicompartmental Arthroplasty with the Oxford Knee. 2nd
ed. Oxford: Goodfellow Publishers Limited, Oxford University Press; 2015.
Dawson J, Fitzpatrick R, Murray D, Carr A. Questionnaire on the perceptions of patients about total knee replacement. J Bone Joint Surg Br 1998;80:63-9.
Murray DW, Fitzpatrick R, Rogers K, Pandit H, Beard DJ, Carr AJ, et al.
The use of the Oxford hip and knee scores. J Bone Joint Surg Br 2007;89:1010-4.
Kalairajah Y, Azurza K, Hulme C, Molloy S, Drabu KJ. Health outcome measures in the evaluation of total hip arthroplasties – A comparison between the harris hip score and the Oxford hip score. J Arthroplasty 2005;20:1037-41.
Insall JN, Dorr LD, Scott RD, Scott WN. Rationale of the knee society clinical rating system. Clin Orthop Relat Res 1989;248:13-4.
Scuderi GR, Bourne RB, Noble PC, Benjamin JB, Lonner JH, Scott WN. The new knee society knee scoring system. Clinical Orthopaedics and Related Research® 2012;470:3-19.
Tegner Y, Lysholm J. Rating systems in the evaluation of knee ligament injuries. Clin Orthop Relat Res 1985;198:43-9.
Mukherjee K, Pandit H, Dodd CA, Ostlere S, Murray DW. The Oxford unicompartmental knee arthroplasty: A radiological perspective. Clin Radiol 2008;63:1169-76.
Rees JL, Price AJ, Beard DJ, Robinson BJ, Murray DW. Defining the femoral axis on lateral knee fluoroscopy. Knee 2002;9:65-8.
Yoo JH, Chang CB, Shin KS, Seong SC, Kim TK. Anatomical references to assess the posterior tibial slope in total knee arthroplasty: A comparison of 5 anatomical axes. J Arthroplasty 2008;23:586-92.
Tu Y, Xue H, Ma T, Wen T, Yang T, Zhang H, et al.
Superior femoral component alignment can be achieved with Oxford microplasty instrumentation after minimally invasive unicompartmental knee arthroplasty. Knee Surg Sports Traumatol Arthrosc 2017;25:729-35.
Koh IJ, Kim JH, Jang SW, Kim MS, Kim C, In Y, et al.
Are the Oxford(®) medial unicompartmental knee arthroplasty new instruments reducing the bearing dislocation risk while improving components relationships? A case control study. Orthop Traumatol Surg Res 2016;102:183-7.
Gulati A, Chau R, Simpson DJ, Dodd CA, Gill HS, Murray DW, et al.
Influence of component alignment on outcome for unicompartmental knee replacement. Knee 2009;16:196-9.
Mr. James A Kennedy
Nuffield Department of Orthopaedics, Rheumatology and Musculoskeletal Sciences, Botnar Research Centre, University of Oxford, Windmill Road, Oxford OX3 7LD
Source of Support: None, Conflict of Interest: None
[Figure 1], [Figure 2], [Figure 3], [Figure 4], [Figure 5], [Figure 6]
[Table 1], [Table 2], [Table 3]
| Article Access Statistics|
| Viewed||516 |
| Printed||20 |
| Emailed||0 |
| PDF Downloaded||23 |
| Comments ||[Add] |