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Orthopaedic Proceedings
Vol. 99-B, Issue SUPP_6 | Pages 8 - 8
1 Mar 2017
Sim J Lee B
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Introduction

Well-balanced soft tissue is essential for achieving a good result when performing total knee arthroplasty. The preoperative planning is critical for ensuring a good operation. This study evaluated the preoperative distractive stress radiographs in order to quantify and predict the extent of medial release according to the degree of varus deformity in primary total knee arthroplasty.

Methods

We evaluated 120 varus, osteoarthritic knee joints (75 patients). The association of the angle on the distractive stress radiograph with extent of medial release was analyzed. The extent of medial release was classified into the following 4 groups according to the stage: release of the deep medial collateral ligament (group 1), release of the posterior oblique ligament and/or semimembranous tendon (group 2), release of the posterior capsule (group 3) and release of the superficial medial collateral ligament (group 4).


Orthopaedic Proceedings
Vol. 99-B, Issue SUPP_6 | Pages 9 - 9
1 Mar 2017
Sim J Lee B
Full Access

Introduction

The acquisition of proper soft tissue balance is one of the crucial factors for preventing long-term failure and obtaining successful treatment outcomes of total knee arthroplasty (TKA). Medial collateral ligament (MCL) release is essential for encountering severe varus deformity. However, conventional subperiosteal MCL release for severe varus deformity can cause the complete detachment of MCL. This study compared retrospectively the results of complete distal release of the MCL with those of medial epicondylar osteotomy during ligament balancing in varus knee TKA

Methods

This study retrospectively reviewed 9 cases of complete distal release of the MCL (group 1) and 11 cases of medial epicondylar osteotomy (group 2) which were used to correct severe medial contracture. The clinical assessment was based on the American Knee Society knee score (KS), function score (FS), and the ROM preoperatively and at the final follow-up. For the radiological assessment, the femorotibial angle was measured based on the whole lower extremity radiograph preoperatively and at the final follow-up. Three months after surgery and at the final follow-up, medial instability was assessed using the valgus stress radiographs, in which the contralateral side was compared using Telos (Telos, Weterstadt, Germany).


Orthopaedic Proceedings
Vol. 98-B, Issue SUPP_10 | Pages 41 - 41
1 May 2016
Sim J Lee B
Full Access

Severely varus deformed knees are common in Asian countries due to lifestyles such as sitting on the floor. MCL release is essential for encountering severe varus deformity. However, conventional subperiosteal MCL release for severe varus deformity can cause the complete detachment of MCL and it can induce mid-flexion instability. We performed medial epicondylar osteotomy when conventional subperiosteal MCL release couldn't resolve tight medial gap of severely varus deformity. The epicondyle is reattached with #5 nonabsorbable sutures or screws (figure 1). This study evaluated the clinical and radiologic results of medial epicondylar osteotomy for severe varus TKA. From 2004 to 2012, 63 cases (of total 909 cases of primary TKA, 6.9%) with a minimum follow-up of 2 years (24 to 116 months) were included in this study. Two cases of 63 cases were excluded due to the loss of follow up. Intraoperative medial and lateral gap difference in flexion and extension was accepted at less than 2 mm. Average follow up was 50.6±29.8 months (24–116 months). Average clinical knee score was 35.5±17.1 preoperatively and 89.1±8.4 postoperatively. Average function score improved from 48.7±16.0 preoperatively to 88.6±8.0 postoperatively. Average flexion contracture was reduced from 8.5±9.8° preoperatively to 1.0±2.3° postoperatively and range of motion improved from 112.0±21.8° preoperatively to 118.9±13.3° postoperatively. Preoperative femorotibial angle was average varus 10.4±5.7° and mechanical axis was average varus 16.7±5.6°. Postoperative femorotibial angle was average valgus 5.5±3.4° and mechanical axis was average varus 1.0±4.1° (figure 2). Valgus stress radiographs showed average 1.6±0.7 mm gap (femoral implant to liner) and varus stress radiographs revealed average 2.7±1.5 mm gap. The difference with medial and lateral gaps was average 1.2±1.1 mm (figure 2). Unions of bony wafer were 39 bony and 22 fibrotic unions (figure 3). According to the difference with medial and lateral gaps, bony union was average 1.2±1.2 mm and fibrotic union was average 1.2±0.9 mm. There were no significant differences between bony and fibrotic union groups. The clinical and radiological results of medial epicondylar osteotomy are satisfactory in severe varus TKA. The stability with bony and fibrotic unions is not different.