Knee Arthritis
Conditions
Keywords
Unicompartmental Knee Replacement, Patient Specific Instrumentation
Brief summary
Patient-specific instrumentation guides have previously been used to improving surgical accuracy and ease of implantation during Total Knee Replacement but have received less attention for implanting Unicompartmental Knee Replacement. The aim of this prospective study is to compare the accuracy of implantation and functional outcome of mobile bearing medial Unicompartmental Knee Replacement implanted with and without patient specific instrumentation by experienced knee surgeons.
Detailed description
The aim of this prospective study is to compare the accuracy of implantation and functional outcome of mobile bearing medial Unicompartmental Knee Replacements implanted with and without patient specific instrumentation by experienced Unicompartmental Knee Replacement surgeons. This single-centre parallel-design trial was conducted between March 2012 and March 2014 at the Nuffield Orthopaedic Centre, Oxford. Four expert knee surgeons performed all of the procedures in this study. Patients who were being placed on the waiting list for a medial Unicompartmental Knee Replacement, and met the entry criteria for the trial, were asked to see if they would be willing to receive further information about participation in the study. They were provided with a study information leaflet that they could read in their own time. A member of the research team subsequently contacted the patients in order to determine if they would agree to take part in the study and enrolled them onto the study. Patients were randomized to either Patient Specific Instrumentation, or Conventional Instrumentation group. There were 23 patients (23 knees) in the Patient Specific Instrumentation group and 22 patients (22 knees) in the Conventional Instrumentation group. Randomization was performed using sealed opaque envelopes. Concealment from operating surgeons and patients was not possible owing to the surgeon needing to confirm the Patient Specific Instrumentation plans, and the patients undergoing pre-operative MRI scans. Patient Specific Instrumentation group patients underwent an MRI scan using the protocol outlined by the Patient Specific Instrumentation manufacturers to plan development of the Patient Specific Instrumentation guides. The preliminary plan indicating prosthesis size, positioning, alignment, and proposed bone resection levels was reviewed by the surgeons who accepted the default preoperative plans unless gross errors were present. The patient specific cutting blocks were then manufactured and sent for sterilization. Operative Technique: All patients received a mobile bearing medial Oxford unicompartmental knee replacement via a minimally invasive approach under general anaesthetic, and high thigh tourniquet. Intra-operatively, the bone cuts were made through the Patient Specific Instrumentation guides without the use of any intra or extra-medullary instrumentation on the femoral side but with a tibial extramedullary guide for some cases. The subsequent milling process and all soft tissue balancing was performed manually in the standard fashion. Post-operatively, the need to have a blood transfusion, and the change haemoglobin levels were also recorded. Oxygen saturation levels over the first 24 hours post surgery were also recorded. Screened anteroposterior and lateral post-operative radiographs were performed prior to discharge. Patients attended the physiotherapy ward discharge clinic at six weeks. A further clinical review was performed at 12 months at which point Oxford Knee Scores were recorded. The primary outcome measure was radiological assessment of component positioning. (See Outcome measures section for more detail) Target sample size: The sample size was calculated from a previous study that used similar radiological assessments to compare unicompartmental knee replacements performed using conventional instrumentation, with those performed using computer navigation. In this study, the standard deviation of the tibia varus/valgus angle for the control group was 3.6°. Assuming a minimum clinically important difference of 3°, the standard mean difference would be 0.8. Hence with a power of 0.8 and significance level of 0.05, a total sample size of 44 patients (22 in each group) was required.
Interventions
PROCEDUREPatient Specific Instrumentation
Patients will undergo a medial unicompartmental knee replacement. This knee replacement is implanted using patient specific cutting guides that have been produced based on the patient's individual anatomy (using plans from pre-operative MRI scans of the patient's knee).
PROCEDUREConventional Instrumentation
Patients will undergo a medial unicompartmental knee replacement using standard conventional instruments.
Sponsors
Oxford University Hospitals NHS Trust
Study design
Allocation
RANDOMIZED
Intervention model
PARALLEL
Primary purpose
TREATMENT
Masking
NONE
Eligibility
Sex/Gender
ALL
Age
18 Years to No maximum
Healthy volunteers
No
Inclusion criteria
* Both cruciate ligaments functionally intact * Full thickness cartilage in the lateral compartment * Correctable intra-articular varus deformity * Full thickness cartilage loss in the medial compartment
Exclusion criteria
* Contra-indication for MRI * All forms of inflammatory arthritis
Design outcomes
Primary
| Measure | Time frame | Description |
|---|---|---|
| Radiological Assessment of Component Positioning | Within a weeks after surgery | Radiological assessment of component positioning and alignment based on post-operative knee radiographs. |
Secondary
| Measure | Time frame | Description |
|---|---|---|
| Assessment of Functional Outcome | One year after surgery | Use of the patient reported outcome tool (Oxford Knee Score) to determine functional outcome at one year following surgery. Total score is 48. Minimum score 0 and Maximum score 48 with higher score indicating better function. Scores on a scale |
Other
| Measure | Time frame | Description |
|---|---|---|
| Post-operative Change in Haemoglobin Between Baseline Baseline and 48 Hours After Surgery | Within the first 48 hours after surgery | Change in haemoglobin levels between baseline and 48 hours after surgery will be determined |
| Number of Participants With The Need for Blood Transfusion Following Surgery | Within the first 48 hours after surgery | Number of Participants with The Need for Blood Transfusion within 48 hours of Surgery |
Participant flow
Participants by arm
| Arm | Count |
|---|---|
| Patient Specific Instrumentation Patients undergoing unicompartmental knee replacement with the additional aid of patient specific instrumentation.
Patient Specific Instrumentation: Patients will undergo a medial unicompartmental knee replacement. This knee replacement is implanted using patient specific cutting guides that have been produced based on the patient's individual anatomy (using plans from pre-operative MRI scans of the patient's knee). | 23 |
| Conventional Instrumentation Patients undergoing unicompartmental knee replacement using standard instrumentation.
Conventional Instrumentation: Patients will undergo a medial unicompartmental knee replacement using standard conventional instruments. | 22 |
| Total | 45 |
Baseline characteristics
| Characteristic | Conventional Instrumentation | Patient Specific Instrumentation | Total |
|---|---|---|---|
| Age, Categorical <=18 years | 0 Participants | 0 Participants | 0 Participants |
| Age, Categorical >=65 years | 14 Participants | 12 Participants | 26 Participants |
| Age, Categorical Between 18 and 65 years | 8 Participants | 11 Participants | 19 Participants |
| Age, Continuous | 68.18 years STANDARD_DEVIATION 10.4 | 66.80 years STANDARD_DEVIATION 7.17 | 67.50 years STANDARD_DEVIATION 8.82 |
| Region of Enrollment United Kingdom | 22 participants | 23 participants | 45 participants |
| Sex: Female, Male Female | 9 Participants | 13 Participants | 22 Participants |
| Sex: Female, Male Male | 13 Participants | 10 Participants | 23 Participants |
Adverse events
| Event type | EG000 affected / at risk | EG001 affected / at risk |
|---|---|---|
| deaths Total, all-cause mortality | — / — | — / — |
| other Total, other adverse events | 0 / 23 | 0 / 22 |
| serious Total, serious adverse events | 1 / 23 | 1 / 22 |
Outcome results
Primary
Radiological Assessment of Component Positioning
Radiological assessment of component positioning and alignment based on post-operative knee radiographs.
Time frame: Within a weeks after surgery
| Arm | Measure | Group | Value (MEAN) | Dispersion |
|---|---|---|---|---|
| Patient Specific Instrumentation | Radiological Assessment of Component Positioning | Tibia: posterior tilt angle | 1.8 Degrees | Standard Deviation 2.8 |
| Patient Specific Instrumentation | Radiological Assessment of Component Positioning | Tibia:posterior tilt angle | 3.5 Degrees | Standard Deviation 2.9 |
| Patient Specific Instrumentation | Radiological Assessment of Component Positioning | Femur: flexion/extension angle | 9.1 Degrees | Standard Deviation 3 |
| Patient Specific Instrumentation | Radiological Assessment of Component Positioning | Tibia: medial fit | 0 Degrees | Standard Deviation 1 |
| Patient Specific Instrumentation | Radiological Assessment of Component Positioning | Femur: varus/valgus angle | 0.9 Degrees | Standard Deviation 4 |
| Patient Specific Instrumentation | Radiological Assessment of Component Positioning | Tibia: anterior fit | 1.0 Degrees | Standard Deviation 0.9 |
| Patient Specific Instrumentation | Radiological Assessment of Component Positioning | Tibia: varus/valgus angle | 3.5 Degrees | Standard Deviation 2.9 |
| Patient Specific Instrumentation | Radiological Assessment of Component Positioning | Tibia: posterior fit | 0 Degrees | Standard Deviation 0.8 |
| Conventional Instrumentation | Radiological Assessment of Component Positioning | Tibia: varus/valgus angle | 8.8 Degrees | Standard Deviation 4.8 |
| Conventional Instrumentation | Radiological Assessment of Component Positioning | Tibia: posterior tilt angle | 3.7 Degrees | Standard Deviation 2.1 |
| Conventional Instrumentation | Radiological Assessment of Component Positioning | Femur: varus/valgus angle | 1.8 Degrees | Standard Deviation 3 |
| Conventional Instrumentation | Radiological Assessment of Component Positioning | Femur: flexion/extension angle | 8.8 Degrees | Standard Deviation 4.8 |
| Conventional Instrumentation | Radiological Assessment of Component Positioning | Tibia: posterior fit | 0 Degrees | Standard Deviation 0.9 |
| Conventional Instrumentation | Radiological Assessment of Component Positioning | Tibia:posterior tilt angle | 4 Degrees | Standard Deviation 2.1 |
| Conventional Instrumentation | Radiological Assessment of Component Positioning | Tibia: medial fit | 1.0 Degrees | Standard Deviation 1.3 |
| Conventional Instrumentation | Radiological Assessment of Component Positioning | Tibia: anterior fit | 1.0 Degrees | Standard Deviation 0.7 |
Comparison: The sample size was calculated from a previous study that used similar radiological assessments to compare OUKAs performed using conventional instrumentation and computer navigation. In this study, the standard deviation of the tibia varus/valgus angle for the control group was 3.6°. Assuming a minimum clinically important difference of 3°, the SMD would be 0.8. Hence with a power of 0.8 and significance level of 0.05, a total sample size of 44 patients (22 in each group) was required.p-value: <0.05t-test, 2 sided
Secondary
Assessment of Functional Outcome
Use of the patient reported outcome tool (Oxford Knee Score) to determine functional outcome at one year following surgery. Total score is 48. Minimum score 0 and Maximum score 48 with higher score indicating better function. Scores on a scale
Time frame: One year after surgery
| Arm | Measure | Value (MEAN) |
|---|---|---|
| Patient Specific Instrumentation | Assessment of Functional Outcome | 18.3 score on a scale |
| Conventional Instrumentation | Assessment of Functional Outcome | 18.2 score on a scale |
p-value: <0.05t-test, 2 sided
Other Pre-specified
Number of Participants With The Need for Blood Transfusion Following Surgery
Number of Participants with The Need for Blood Transfusion within 48 hours of Surgery
Time frame: Within the first 48 hours after surgery
| Arm | Measure | Value (COUNT_OF_PARTICIPANTS) |
|---|---|---|
| Patient Specific Instrumentation | Number of Participants With The Need for Blood Transfusion Following Surgery | 0 Participants |
| Conventional Instrumentation | Number of Participants With The Need for Blood Transfusion Following Surgery | 0 Participants |
Other Pre-specified
Post-operative Change in Haemoglobin Between Baseline Baseline and 48 Hours After Surgery
Change in haemoglobin levels between baseline and 48 hours after surgery will be determined
Time frame: Within the first 48 hours after surgery
Population: Mean drop in post-operative Haemoglobin
| Arm | Measure | Value (MEAN) | Dispersion |
|---|---|---|---|
| Patient Specific Instrumentation | Post-operative Change in Haemoglobin Between Baseline Baseline and 48 Hours After Surgery | 1.66 g/dl | Standard Deviation 0.79 |
| Conventional Instrumentation | Post-operative Change in Haemoglobin Between Baseline Baseline and 48 Hours After Surgery | 1.80 g/dl | Standard Deviation 0.59 |
p-value: <0.05t-test, 2 sided