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Orthopedics & Rheumatology

Research Article Volume 6 Issue 7

Computer-Assisted TKR Vs Conventional TKR: Post-Operative Ankle Radiographic Finding and Ankle Clinical Assessment

Methee Khongphaophong,1 Thakrit Chompoosang,2 Pornpavit Sripirom,2 Phattara Chunsiri2

1Department of Orthopaedic, Samut Sakhon Hospital, Thailand
2Department of Orthopaedic, Rajavithi Hospital, College of Medicine, Rangsit University, Thailand

Correspondence: Methee Khongphaophong, Department of Orthopaedic, Samut Sakhon Hospital, Samut Sakhon,Thailand 7400, Tel 6680323660

Received: April 19, 2016 | Published: December 30, 2016

Citation: Khongphaophong M, Chompoosang T, Sripirom P, Chunsiri P (2016) Computer-Assisted TKR Vs Conventional TKR: Post-Operative Ankle Radiographic Finding and Ankle Clinical Assessment. MOJ Orthop Rheumatol 6(7): 00253. DOI: 10.15406/mojor.2016.06.00253

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Abstract

Background: Few previous studies showed that the conventional total knee replacement (TKR) has affection to the same side of talar tilt (TT). We expected to prevent this problem by the computer-assisted (CAS) TKR.

Objective: The purpose of this study was to compare between pre and post-operative talar tilt and ankle clinical assessment on the CAS TKR and the Conventional TKR in 28 patients (56 knees) whom underwent bilateral TKR.

Material and Method: 28 patients, 56 knees, whom underwent both CAS total knee replacement (TKR) and conventional total knee replacement (TKR), in both knees, with the combination of Gap Balance and Measurement Resection techniques performed by one surgeon (P. Sriphirom) at Rajavithi Hospital, Bangkok. The post-operative has a 12 months follow-up for ankle radiographic finding by tibiotalar angle (TTA), tibial articular surface angle (TAS), and talar tilt (TT) = (TAS-TTA) and for ankle clinical assessment by foot functional index (FFI) from pre-operation and post-operation from both groups. The study also compares the CAS TKR with the Conventional TKR for pre-operation and post-operation.

Results: 56 knees, 28 patients, mean age = 67.79 years whom underwent bilateral TKR by the Conventional group and the CAS group had pre-operative TT (TT = TAS - TTA). The Conventional group = 1.5 (-5, 8), the CAS group = .5 (-5, 8), P value = .65. On post-operative TT the Conventional group = .0 (-5, 3), the CAS group = 1.0 (-3, 8), the P value = .4. The comparison of pre-operative TT and post-operative TT in the Conventional group, the P value = .01. On pre-operative TT and post-operative TT in the CAS group, the P value = .65. TT was significantly different in the Conventional group but was not significantly different in the CAS group. The ankle clinical assessment by foot functional index (FFI), which is (1) Pain, (2) Difficulty living, and (3) Daily life activity limitation. The pre-operative FFI in the Conventional group = 1.85 (.81, 6.88) and pre-operative FFI in the CAS group = 1.91 (.24, 66.5), the P value = .57. The post-operative FFI in the Conventional group = 1.68 (0.24, 7.0) and post-operative FFI in the CAS group = 1.65 (.24, 6.76), the P value = .04, which showed a significantly different between the post-operative FFI from both groups. In the Conventional group the post-operative FFI was not significantly different from pre-operative FFI, the P value = .2 but for the CAS group the post-operative FFI was not significantly different from pre-operative FFI, the P value = .04.

Conclusion: This study has shown that the conventional TKR effected to post-operative talar tilt but the CAS TKR has less effect and was not significantly different to ankle joint. Finally, the study needs to be conducted on more patients and to be observed on a longer term follow-up.

Keywords:Total knee arthroplasty, TKR, CAS TKR, Ankle score

Introduction

When osteoarthritis causes severe varus and valgus knee deformities, it is often also present in the ankle joint.1 and it is not rare to find those who have undergone total knee arthroplasty presenting with ankle osteoarthritis. Many of them complain of pain in the ankle joint following total knee arthroplasty, and in some cases radiographs show progressive degenerative changes in the ankle.

Deformity of OA knee changes normal mechanical axis and may also change the axis of rotation of the ankle joint.2 Recently, Jung Hee Lee at al. found that after total knee arthroplasty, arthritis developed or progressed radiographically in many patients’ ankles.3

As yet, there is no single recommended technique for minimizing postoperative ankle arthritis change in total knee arthroplasty (TKA). This study compared and evaluated computer-assisted total knee arthroplasty (CAS-TKA) and conventional total knee arthroplasty (TKA), and we anticipated that computer- assisted total knee arthroplasty might minimize the postoperative ankle effect both clinically and radiographically.

Materials and methods

We retrospectively enrolled 28 patients who underwent traditional total knee arthroplasty on one knee and computer-assisted total knee arthroplasty on the other with a 6-month interval between operations. All patients attended for follow-up for at least 12 months between February 2010 and November 2012 in our institute. There were 26 females and 2 males, their mean age was 67.9, and all cases were 1o OA knee. We excluded post-traumatic knee or ankle joint, 20 OA (inflammatory, infection, congenital), and valgus knee. We performed pre-operative and postoperative scannograms in all cases for tibial articular surface angle (TAS), tibio-talar angle (TTA) and talar tilt (TT).1 (Figure 1) after which we calculated Talar tilt (TT), for which the normal range is (-4,+4), as the difference between TAS and TTA for radiologic ankle assessment. We compared the results of total knee arthroplasty of the two groups pre- and post-operatively, and the pre- and postoperative results within each group.

Figure 1 Pre/Post-operative Mechanical axis and talar tilt angle.
We used the foot functional index (FFI).4 scores in clinical assessment pre- and post-operatively, and FFI was compared with talar tilt (TT) for radiologic assessment.

Surgical technique

Total knee arthroplasty was performed by a single surgeon with a combination of the gap balancing and measured resection techniques using both conventional total knee arthroplasty and computer- assisted total knee arthroplasty.1 Tibial cut was performed first, after which the extension and flexion gaps were measured. The distal femoral cut thickness and angle were calculated, and after soft tissue balancing was carried out, femoral block cut was performed. Prosthesis implantation was the final step. Conventional total knee arthroplasty used NexGen LPS prosthesis, Zimmer, and computer-assisted total knee arthroplasty used Emotion knee prosthesis, Asculab, Orthopilot Navigation version 4.3.

Statistics

We used Descriptive Statistics. Mean, SD for radiographic pre-operations and post-operations. For foot functional index we used student t-test and Wilcoxon Signed Ranks Test, and pd” 0.05 was considered statistically significant

Results

We enrolled 28 patients (56 total knee arthroplasties) of whom 26 were female and 2 were male and whose mean age was 67.9 year old (the youngest was 58, and the oldest was 82 years old). There were no significant differences in pre-operative TAS and TTA in the two groups (Table 1).

 

Age

Pre-op TAS

Pre-op TTA

Pre-op_TAS

Pre-op_TTA

Mean±SD

67.96±679

91.29±3.63

90.38±3,99

91.04±4,45

90.79±4.39

Median

66.50

91

90

90

90

Minimum

58

84

80

84

84

Maximum

82

101

101

112

112

Table 1 Number, mean and quality of patient in this serios (n-56).
TAS: Tibial articular Surface Angle TTA: Talar Angle

The mean pre-CAS-TKA talar tilt was 0.7o, while in the pre-conventional TKA it was 1.1o, but these differences were not statistically significant (p=0.45) as shown in Table 2; however, pre-operative talar tilt (1.0 o) and post-operative talar tilt (0.0 o) in all cases were significantly different as shown in Table 3 (p=0.02).

Computer-Assisted Surgery

Conventional method

p-value

Mean

S.D

Mean

S.D

Angle radiographs

 

Pre_TAS

90.89

3.55

91.68

3.72

0.094

Prc_TTA

90.18

3.88

90.57

4.17

0.562

Post_TAS

90.71

3.68

91.36

5.15

0.369

Post_TTA

90.18

3.15

91.39

5.35

0.095

 

0.71

2.19

1.11

3.15

0.450W

Median(Min, Max)

0.50(-5,8)

1.50(-5,8)

 

Post-TT

0.54

1.93

-0.04

1.58

0.400W

Median(Min, Max)

1.00(-3,8)

0.00(-5,3)

 

Table 2 Mean radiographic measurement: CAS Tic.R vs CCINV TKR.
p-value from pair t-test; W: p-value from Wilcoxon Signed Ranks Test; TAS: Tibial Articular Surface angle TTA: Tatar Angle; TT: Talar Tilt = (TAS-TTA)

>
 

PPre-op

PPost-op

p-value

TT angle Median (Min,Max)

1.00 (-5,8)

0.00 (-5,8)

0.026

Table 3 Talar tilt pre vs. post-operation.

A comparison of pre–operative and post- operative talar tilt (TT) showed that in the CAS-TKA group, talar tilt was not significantly different; however, in the Conventional TKA group there was a significant difference (p=0.016) as shown in Table 4.

 

Pre op

Post-op

p-value

CAS TKR

     

Median (Min, Max)

0.50 (-5,8)

I .00 (-3,8)

0.657

Mean ± SD.

0.71±2.19

0.54±1.93

CONV TKR

     

Median (MM , Max)

1.50 (-5.8)

0.00 (-5.3)

0.016

Mean ± SD.

1.11±3.16

-0.04±1.58

Table 4 Talar tilt : pre-op vs, post-op in CAS TKR vs CONV TKR

A comparison of a foot functional index (FFI) for clinical foot and ankle assessment revealed that there was no significant difference between pre- operative foot functional indexes (FFI) in the two groups. However, postoperative pain, difficulty walking (?), and overall sub-scores were significantly different (p-value = 0.033, 0.039 and 0.047, respectively) while only scores for daily life activity limitation were not significantly different (Table 5).

>

Clinical assessment

Computer assisted surgery

Conventional Method

p-value

 

Median

Min

Max

Median

Min

Max

Pre-op

             

pain

I.10

0.2

6

1.1

0

6.4

0.533

difficulty

1.94

0.22

6.78

1.89

0.22

6.89

0.269

daily life activity limitation

2.67

0

8.33

2.83

0

9.33

0.604

overall

1.91

0.24

6.65

1.85

0.18

6.88

0.577

Post-op

             

pain

0.13

0.2

4.8

0.8

0.2

5

0_033*

Difficulty

0.78

0.22

7

1.94

0.22

7.33

0.0391

Daily life activity limitation

2

0

9.33

2,17

0

9,33

0.32

overall

1.65

0.24

6.76

1.68

0.24

7

0.047*

Table 5 Foot Functional Index (FF1) CAS TKR vs. CONV TKR.
p-value from Wilcoxon Signed Ranks Test, *significant at the 0.05 level

Clinical assessment of patients in the Conventional TKA group, revealed no significant difference pre- and post-operatively, as shown in Table 6. In contrast, in the CAS-TKA group, pre- and postoperative clinical assessment revealed significant differences in difficulty, daily life activity limitation and overall scores (p-value =0.046, 0.025 and 0.047, respectively), while the only scores that were not significantly different were those for pain (Table 7).

Clinical assessment

Conventional Method

p-value

 

Pre-op

Post-op

 
 

Median

Min

Max

Median

Min

Max

 

pain

1.1

0

6.4

0.8

0.2

5

1

difficulty

1.89

0.22

6.89

1.94

0.22

7.33

0.314

daily life activity limitation

2.83

0.00

9.33

2.17

0.00

9.33

0.075

overall

1.85

0.18

6.88

1.68

0.24

7.00

0.208

Table 6 Foot Functional Indox (FFI): pro vs. post-CONV TKR.

Clinical assessment

Computer-Assisted Surgery

p-value

Pre-op

Post-op

Median

Min

Max

Median

Min

Max

Pain

1.1

0.2

6

0.8

0.2

4.8

0.352

Life difficulty for living

1.94

0.22

6.78

1.78

0.22

7

0.046*

Daily life activity limitation

2.67

0.00

8.33

2.00

0.00

9.33

0.025*

Overall

1.91

0.24

6.65

1.65

0.24

6.76

0.047*

Table 7 Foot Functional Index (FF1); pre vs. post-CAS TKR
p-value from Wilcoxon Signed Ranks Test; *significant at the 0.05 level

Conclusion

Ankle osteoarthritis is mostly secondary osteoarthritis that develops as a sequel to fractures and few reports are found of primary osteoarthritis in the ankle. The factors that influence the onset and progression of osteoarthritis are not well understood, although it is known that lower extremity mal-alignment is related to joint problems.2,5-9 We found that many patients complained of pain in the ankle after total knee arthroplasty, and we surmised that a change in the alignment of the lower extremity caused by a relatively large knee varus correction angle might be one of the reasons for the discomfort. Jung Hee Lee et al.3 reported that 35.2% of patients had radiographic change in ankle joint after conventional total knee arthroplasty (TKA), and this may be an early sign of ankle osteoarthritic change.3

Takakura et al.10 reported that varus deformity of the ankle was compensated by the valgus inclination of the subtalar joint, and osteoarthritis began to progress when the compensatory function was inoperative. To date, however, the relationship between subtalar compensation and medial compartment osteoarthritis of the ankle has not yet been explored.

According to several cadaveric studies on degenerative changes of the lower extremity, about a third of patients who had osteoarthritis in the knee also had it in the ankle.11-14 In particular, Tallroth et al.14 analyzed pre- and postoperative radiographs and clearly observed ankle joint osteoarthritis before surgery in 30 out of 104 patients who underwent conventional total knee arthroplasty (TKA).

In our study, we aimed to minimize the alteration of mechanical axis after total knee arthroplasty by utilizing the computer-assisted technique, which we believed, could achieve superior alignment of components, resulting in more accuracy and closer-to- normal knee alignment; in turn, this might minimize the chance of future osteoarthritic change in the ankle.

We measured talar tilt for radiologic evaluation and foot functional index (FFI) for clinical assessment. We found smaller alteration for talar tilt in the computer- assisted group, which we assume, is because this technique helps to minimize ankle problems and is less likely than conventional total knee arthroplasty to lead to ankle osteoarthritic change.

We also found that Foot functional index (FFI) tended to be better in the computer-assisted TKA group than in the conventional TKA one. There were also greater post-operative clinical improvements in the computer–assisted group compared to their pre- operative assessment.

One limitation of this study is that we studied only 28 patients, which is a small number; furthermore, the follow-up period was only of 12 months duration and, therefore, our results may not be very reliable. Another limitation was a lack of equipment: when degenerative changes and angular deformities of the knee are severe, a varus deformity is usually three- dimensionally associated with a flexion contracture of the knee, so the varus angle measured on radiographs may not be a true varus angle.15,16 and we did not have CT scan available to evaluate these deformities. With regard to ankle radiographic change, we did not have lateral plain film or CT scan to evaluate other dimensional deformities.

In conclusion, we studied 28 patients in 56 total knee arthroplasty operations, and our study showed that computer-assisted total knee arthroplasty was superior to conventional total knee arthroplasty in minimizing the chance of early postoperative ankle arthritis, but further research is required with larger numbers of patients, longer follow-up and more accurate radiographic imaging applications.

What is already known on this topic?

  1. Some research told after convention TKA had the problem of ankle pain. The hypothesis of acute change of talar tilt angle after TKA.
  2. What does this study add?
  3. The research shows results of CON TKA compared with CAS TKA in Mechanical alignment of knee in Bilateral TKA.
  4. The research shows resulting effect of talar tilt angle post CAS TKA compared with CON TKA.
  5. The research shows clinical results of Angle pain after pert-operation CON TKA vs CAS TKA.

Acknowledgment

This present study was supported by the research fund of Rajavithi Hospital.

Conflicts of interest

None.

References

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  4. Lee WC, Moon JS, Lee HS et al. Alignment of ankle and hindfoot in early stage ankle osteoarthritis. Foot Ankle Int. 2011;32(7):693‒699.
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