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The Talar Body Prosthesis: Results at Ten to Thirty-six Years of Follow-up

BACKGROUND Satisfactory results of implantation of the talar body prosthesis were reported in 1997, although some complications associated with the initial design were noted. The present study evaluated outcomes of treatment with a modified talar body prosthesis. METHODS Of the thirty-six talar body prostheses implanted with use of a transmalleolar surgical approach from 1974 to 2011, thirty-three were available for follow-up at ten to thirty-six years or had failed prior to that time. The indication for implantation had been osteonecrosis in twenty-three patients, a comminuted talar fracture in eight, and a talar body tumor in two. RESULTS Twenty-eight of the thirty-three prostheses were still in place at the time of final follow-up and five had failed prior to five years. The duration of follow-up was ten to twenty years in eight patients, twenty to thirty years in eleven, and thirty to thirty-six years in nine. The AOFAS (American Orthopaedic Foot & Ankle Society) ankle-hindfoot score did not differ significantly among these three groups. Patients over sixty-five years of age with underlying disease that impeded walking ability had lower AOFAS scores. Early prosthesis failure occurred as a result of size mismatch in two patients, tumor recurrence in one, infection in one, and osteonecrosis of the talar head and neck in one. These failures, which occurred at eight to fifty-seven months, were treated with tibiotalar arthrodesis in three patients, prosthesis revision in one, and below-the-knee amputation in one. CONCLUSIONS Although early prosthesis failure may occur, survival of the talar body prosthesis can provide satisfactory ankle and foot function. LEVEL OF EVIDENCE Therapeutic Level IV. See Instructions for Authors for a complete description of levels of evidence.

Is the Arthroscopic Transillumination Test Effective in Localizing the Superficial Peroneal Nerve

PURPOSE To evaluate the transillumination test in showing the position of the superficial peroneal nerve (SPN) to quantify the effectiveness of this test. METHODS Prospectively, we selected 53 ankle arthroscopy patients (71 patients were excluded because of the invisible SPN). Demographic data including gender, weight, height, and body mass index were recorded. The intraoperative transillumination test was performed during portal establishment and recorded as positive if the SPN was visible via transillumination. The data were analyzed as mean, standard deviation, and percentage. Wilsons method was used as 95% confidence interval for proportion of the positive transillumination test. RESULTS The intraoperative transillumination test was positive in 0 of 53 patients (0%) with 95% confidence interval ranging from 0% to 6.7%. CONCLUSIONS The transillumination test has no value for showing the SPN. LEVEL OF EVIDENCE Level II, prospective diagnostic study.

Vertical pelvic ring displacement in pelvic ring injury: Measurements in pelvic outlet radiograph and in cadavers.

Background: Vertical pelvic ring displacement (VPRD) is a serious injury and needs assessment. Pelvic outlet radiographs are routinely taken. However, relationship of radiographic and actual VPRD is still in question. Thus, measurement of VPRD from pelvic radiographs was studied. Materials and Methods: 2 dry pelvic bones and 1 sacrum from same cadaver was reconstructed to be the pelvic ring. Five specimens were enrolled. 10, 20 and 30 mm vertical displacement of right pelvic bone was performed at levels of sacroiliac joint and pubic symphysis for representing right VPRD. Then, the pelvis was set sacral inclination at 60° from X-ray table for outlet and anteroposterior pelvic radiographs. Right VPRD was measured by referring to superior most pelvic articular surface of both sacroiliac joints and sacral long axis. Radiographic VPRD and actual displacement were analyzed by Pearson correlation coefficient at more than 0.90 for the strong correlation and strongly significant simple regression analysis was set at P < 0.01. Results: Radiographic VPRD from outlet and anteroposterior pelvic views at 10 mm actual displacement were 20.12 ± 1.98 and 4.08 ± 3.76 mm, at 20 mm were 40.31 ± 1.97 and 9.94 ± 7.27 mm and at 30 mm were 58.56 ± 2.53 and 11.29 ± 2.89 mm. Statistical analyses showed that radiographic VPRD from pelvic outlet view is 1.95 times of actual displacement with strong correlation at 0.992 coefficient and strongly significant regression analysis (P < 0.001) with 0.984 of R2 value. Whereas, the measurement from anteroposterior pelvic radiograph was not strongly significant. Conclusion: Pelvic outlet radiograph provides efficient measurement of VPRD with 2 times of actual displacement.

Radiographic assessment of the safe zone for medial oblique opening wedge high tibial osteotomy.

Purpose. To compare different cephalocaudal angles of the X-ray beam in measuring internal rotation of the proximal tibia that best demonstrates the safe zone. Methods. 10 pairs of embalmed, disarticulated knee joints from 10 cadavers were used. Soft tissues around the proximal tibia and the proximal tibiofibular joint (PTFJ) were dissected to reveal the articular cartilage. A narrow area between the end of the articular cartilage of the posterolateral proximal tibia and of the PTFJ was identified as the safe zone with a U-shape metal used as a radiographic marker. Translation of the proximal tibia was controlled during internal rotation of the proximal tibia. Internal rotation of the proximal tibia that best demonstrated the safe zone (the U-shape metal at its most outermost point) was measured at 0°, 5°, 10°, 15°, 20°, and 25° cephalocaudal angles of the X-ray beam. Results. The mean internal rotation of the proximal tibia that best demonstrated the safe zone at 0°, 5°, 10°, 15°, 20°, and 25° cephalocaudal angle of the X-ray beam were 50°, 45°, 37°, 32°, 23°, and 19°, respectively. Conclusion. The safe zone was best demonstrated with 50° and 45° internal rotation of the proximal tibia at 0° and 5° cephalocaudal angles of the X-ray beam, respectively.

Müller-Weiss Disease: Three- to Eight-Year Follow-Up Outcomes of Isolated Talonavicular Arthrodesis

Abstract Numerous surgical techniques for the treatment of Müller‐Weiss disease (MWD) have been reported. However, no extensive clinical and radiographic studies of isolated talonavicular arthrodesis and MWD have been reported. The present retrospective cohort study examined the outcomes of isolated talonavicular arthrodesis at 3 to 8 years of follow‐up in 16 MWD patients with a collapsed longitudinal arch and at least Maceira stage III. Demographic data, pre‐ and postoperative visual analog scale (VAS) scores for pain on walking and walking disability, foot and ankle outcome scores (FAOSs), and radiographic parameters were analyzed, with statistical significance at p < .05. A survival analysis was used to determine the median time to union. The mean ± standard deviation pre‐ and postoperative VAS scores for pain on walking were 7.69 ± 1.62 and 2.19 ± 1.52 and the walking disability scores were 7.06 ± 2.11 and 2.31 ± 1.92, respectively. The pre‐ and postoperative FAOSs were 48.07 ± 21.50 and 82.27 ± 13.86 for activities of daily living, 30.86 ± 19.70 and 76.17 ± 22.39 for quality of life, and 20.93 ± 22.89 and 51.88 ± 23.66 for sports/recreation, respectively. The median pre‐ and postoperative FAOSs for the symptoms subscale were 73.22 (range 42.88 to 100.00) and 87.50 (35.71 to 100.00) and for pain were 34.72 (range 8.33 to 72.22) and 88.89 (54.41 to 100.00), respectively. Significant improvements occurred from preoperatively to postoperatively for VAS scores and FAOSs (p < .05). The mean pre‐ and postoperative calcaneal pitch angles were 11.31° ± 4.35° and 13.81o ± 5.60o, significant improvement (p = .016). Improvement was also seen midfoot abduction, with a mean pre‐ and postoperative anteroposterior Mearys angle of 14.38° ± 10.07° and 9.38° ± 12.21°. The survival analysis showed union was achieved in all patients, with a median time to union of 2 (95% confidence interval 1.03 to 3.00) months. Our data indicate that talonavicular arthrodesis provides satisfactory functional outcomes for MWD patients with a collapsed longitudinal arch. &NA; Level of Clinical Evidence: 4

Benefit of Adding Fibular Osteotomy to Open-Wedge, Valgus, Distal Tibial Osteotomy for Correcting Varus Ankle Arthritis: An In Vitro Study

Abstract Early‐stage varus ankle arthritis can usually be treated with a medial, open‐wedge, valgus, distal tibial osteotomy; however, the value of adding a fibular osteotomy has been debated. We sought to determine the increase in the maximum medial osteotomy gap and correction angle provided by fibular osteotomy. In 3 sequential experiments on 12 fresh cadaveric legs, we first performed a medial open‐wedge, valgus, distal tibial osteotomy alone. Second, we added a transverse fibular osteotomy. Finally, we added a blocked fibular osteotomy. In each experiment, we measured the maximum corrected osteotomy gap and the maximum correction angle. Correction was defined as the absence of lateral cortex diastasis and talocrural joint incongruity. The mean ± standard deviation maximum osteotomy gaps and correction angles were 8.40 ± 1.6 mm and 10.70° ± 3.3° for the tibial osteotomy alone, 15.70 ± 4.6 mm and 20.20° ± 5.6° for the tibial plus transverse fibular osteotomy, and 16.67 ± 3.7 mm and 20.56° ± 4.6° for the tibial plus transverse plus blocked fibular osteotomies, respectively. The corresponding median maximum correction angles were 10° (range 8° to 18°), 19.5° (range 14° to 30°), and 20° (range 14° to 28°). The osteotomy gap and correction angle in the distal tibial and transverse fibular osteotomy were significantly greater than those in the distal tibial osteotomy alone (p < .001 for both) but not in the distal tibial and blocked fibular osteotomy (p = .62 for the gap and p = .88 for the correction angle). Our data support the clinical use of adjunct transverse fibular osteotomies. The blocked fibular osteotomy provided no additional benefit. &NA; Level of Clinical Evidence: 5

How to harvest the greatest length of tibialis posterior tendon for tendon transfer: A cadaveric study: How to Harvest the Greatest Length

In anterior transfer of the tibialis posterior tendon, the tendon was harvested using two incisions, the first at its attachment point on the navicular bone and second on the medial side of the leg above the medial malleolus. To provide the maximum tendon length, the second incision needs to be as proximal as possible but injury to the muscle origin must be avoided. The purpose of this study is to establish the location of the second incision that yields the greatest tendon length. Forty‐five unpaired embalmed cadaveric legs were dissected. Demographic data, gender, age, and side of specimen were recorded. The distance between the tip of the medial malleolus and the muscle origin was measured. Mobile tendon length, muscle origin, foot length, tibial length, and position of ankle were also noted. The mean mobile tendon length was 11.1 (range 10.7–11.4) cm and the distance between the tip of the medial malleolus and the muscle origin was 6.8 (range 6.5–7.0) cm. The mean foot length was 22.2 cm (range 21.7–22.7), tibial length was 31.5 cm (range 30.8–32.2), and muscle origin was 23.7 cm (range 21.0–26.3). The mean angle position was 46 degrees plantar flexion (range 43–49). In subgroup analysis by gender, the mobile tendon length, distance between the tip of the medial malleolus and the muscle origin, and tibial length, were significantly greater in males than females. In conclusion, for anterior transfer of the tibialis posterior tendon, an incision 7.1 cm above the medial malleolus in the male and 6.4 cm above it in the female provides the longest mobile tendon without injury to its origin. Clin. Anat. 30:1083–1086, 2017.

How to harvest the greatest length of tibialis posterior tendon for tendon transfer: A cadaveric study

In anterior transfer of the tibialis posterior tendon, the tendon was harvested using two incisions, the first at its attachment point on the navicular bone and second on the medial side of the leg above the medial malleolus. To provide the maximum tendon length, the second incision needs to be as proximal as possible but injury to the muscle origin must be avoided. The purpose of this study is to establish the location of the second incision that yields the greatest tendon length. Forty‐five unpaired embalmed cadaveric legs were dissected. Demographic data, gender, age, and side of specimen were recorded. The distance between the tip of the medial malleolus and the muscle origin was measured. Mobile tendon length, muscle origin, foot length, tibial length, and position of ankle were also noted. The mean mobile tendon length was 11.1 (range 10.7–11.4) cm and the distance between the tip of the medial malleolus and the muscle origin was 6.8 (range 6.5–7.0) cm. The mean foot length was 22.2 cm (range 21.7–22.7), tibial length was 31.5 cm (range 30.8–32.2), and muscle origin was 23.7 cm (range 21.0–26.3). The mean angle position was 46 degrees plantar flexion (range 43–49). In subgroup analysis by gender, the mobile tendon length, distance between the tip of the medial malleolus and the muscle origin, and tibial length, were significantly greater in males than females. In conclusion, for anterior transfer of the tibialis posterior tendon, an incision 7.1 cm above the medial malleolus in the male and 6.4 cm above it in the female provides the longest mobile tendon without injury to its origin. Clin. Anat. 30:1083–1086, 2017.

The new intra-articular calcaneal fracture classification system in term of sustentacular fragment configurations and incorporation of posterior calcaneal facet fractures with fracture components of the calcaneal body

Objective The aim of this study was to develop a new calcaneal fracture classification system which will consider sustentacular fragment configuration and relation of posterior calcaneal facet to calcaneal body. Methods The new classification system used sustentacular fragment configuration and relation of posterior calcaneal facet fracture with fracture components of calcaneal body as key aspects of main types and subtypes. Between 2000 and 2014, 126 intraarticular calcaneal fractures were classified according to the new classification system by using computed tomography images. The new classification system was studied in term of reliability, correlation to choices of treatment, implant fixation and quality of fracture reduction. Results Types of sustentacular fragment comprised type A, B and C. Type A sustentacular fragment included sustentacular tali containing middle calcaneal facet. In Type B and C fractures sustentacular fragment included medial aspect and entire posterior calcaneal facet as a single unit, respectively. The fractures with type A, B and C sustentacular fragments were classified as main type A, B and C intra-articular calcaneal fractures. The main type A and B comprised 4 subtypes. Subtypes A1, A3, B1, and B3 associated with avulsion and bending fragments of calcaneal body. Subtype A2, B2, and B4 associated with burst calcaneal body. Subtype B4 was not found in the study. Main type C had no subtype and associated with burst calcaneal body. The data showed good reliability. Conclusion The study showed that our new intra-articular calcaneal fracture classification system correlates to choices of treatment, implant fixation and quality of fracture reduction. Level of Evidence: Level IV, Study of Diagnostic Test

Acetabular roof arc angles and anatomic biomechanical superior acetabular weight bearing area

Background: Acetabular fracture involves whether superior articular weight bearing area and stability of the hip are assessed by acetabular roof arc angles comprising medial, anterior and posterior. Many previous studies, based on clinical, biomechanics and anatomic superior articular surface of acetabulum showed different degrees of the angles. Anatomic biomechanical superior acetabular weight bearing area (ABSAWBA) of the femoral head can be identified as radiographic subchondral bone density at superior acetabular dome. The fracture passes through ABSAWBA creating traumatic hip arthritis. Therefore, acetabular roof arc angles of ABSAWBA were studied in order to find out that the most appropriate degrees of recommended acetabular roof arc angles in the previous studies had no ABSAWBA involvement. Materials and Methods: ABSAWBA of femoral head was identified 68 acetabular fractures and 13 isolated pelvic fractures without unstable pelvic ring injury were enrolled. Acetabular roof arc angle was measured on anteroposterior, obturator and iliac oblique view radiographs of normal contralateral acetabulum using programmatic automation controller digital system and measurement tools. Results: Average medial, anterior and posterior acetabular roof arc angles of the ABSAWBA of 94 normal acetabulum were 39.09 (7.41), 42.49 (8.15) and 55.26 (10.08) degrees, respectively. Conclusions: Less than 39°, 42° and 55° of medial, anterior and posterior acetabular roof arc angles involve ABSAWBA of the femoral head. Application of the study results showed that 45°, 45° and 62° from the previous studies are the most appropriate medial, anterior and posterior acetabular roof arc angles without involvement of the ABSAWBA respectively.