Spiegelberg B, Parratt T, Dheerendra SK, Khan WS, Jennings R, Marsh DR. Ilizarov principles of deformity correction. Ann R Coll Surg. 2010;92(2):101–5.
Article
Google Scholar
Shi BW, Ji GQ, Cai CK. Gradual correction of proximal tibia deformity for Blount disease in adolescent and young adults. J Orthop Surg. 2020;28(1):1–8.
Google Scholar
Bliven EK, Greinwald M, Hackl S, Augat P. External fixation of the lower extremities: biomechanical perspective and recent innovations. Injury. 2019;50(1):S10–7.
Article
Google Scholar
Moolenaar JZ, Tumer N, Checa S. Computer-assisted preoperative planning of bone fracture fixation surgery: a state-of-the-art review. Front Bioeng Biotechnol. 2022;10:1–24.
Article
Google Scholar
Davidson RS, The MAC. (multi-axial correcting) monolateral external fixation system (Biomet/EBI) technique: an easier way to correct deformity. Oper Tech Orthop. 2011;21(2):113–24.
Article
Google Scholar
Tan B, Shanmugam R, Gunalan R, Chua Y, Hossain G, Saw A. A biomechanical comparison between Taylor’s spatial frame and Ilizarov external fixator. Malays Orthop J. 2014;8(2):35–9.
Article
Google Scholar
Leaver T, Johnson B, Lampard J, Aarvold A, Uglow M. The risks following the exposure to radiation associated with the surgical correction of limb deformities in children are minimal. Bone Jt J. 2019;101(B3):241–5.
Article
Google Scholar
Messner J, Chhina H, Davidson S, Abad J, Cooper A. Clinical outcomes in pediatric tibial lengthening and deformity correction: a comparison of the Taylor spatial frame with the orthex hexapod system. J Child Orthop. 2021;15(10):1–8.
Google Scholar
Çınar BM, Güler ÜÖ. Supramalleolar osteotomy with a hexapod type external fixator for the treatment of ankle joint three planar deformity: case report. Jt Dis Relat Surg. 2020;31(2):372–6.
Google Scholar
Eren I, Eralp L, Kocaoglu M. Comparative clinical study on deformity correction accuracy of different external fixators. Int Orthop. 2013;37:2247–52.
Article
Google Scholar
Seide K, Wolnack J, Weinrich N, Jürgens C. The hexapod external fixator theory and software. Bio Technolo. 2003;47:326–33.
Google Scholar
Aydin A, Avar E, Akçalı İD, Ün MK, Ibrikci T, Mutlu H, Bicer O, Özkan C, Durmaz A. Displacement analysis of robotic frames for reliable and versatile use as external fixator. In: Proc. Cyber Technology in Automation, Control, and Intelligent Systems (CYBER) 2014;180–5.
Simpson AL, Ma B, Slagel B, Borschneck DP, Ellis R. Computer-assisted distraction osteogenesis by Ilizarov’s method. Int J Med Robot Comp. 2010;4:310–20.
Article
Google Scholar
Ghasemi SA, Zhang DT, Fragomen A, Rozbruch SR. Proximal tibial osteotomy for genu varum: radiological evaluation of deformity correction with a plate vs external fixator. World J Orthop. 2021;12(3):140–51.
Article
Google Scholar
Meselhy MA, Elhammady AS. Role of Ilizarov external fixator in the treatment of long-standing knee flexion deformity in adults: a prospective cohort study. Curr Orthop Pract. 2020;31(2):173–8.
Article
Google Scholar
Paley D. History and science behind the six-axis correction external fixation devices in orthopaedic surgery. Oper Tech Orthop. 2011;21(2):125–8.
Article
MathSciNet
Google Scholar
Jung HJ, Cho TJ, Choi IH, Chung CY, Yoo WJ, Park MS, Bae JY. Change in effective leg length after angular deformity correction by hemiepiphyseal stapling. Clin Orthop Surg. 2010;2(2):85–9.
Article
Google Scholar
Kim SE, Han HS. Robotic-assisted unicompartmental knee arthroplasty: historical perspectives and current innovations. Biomed Eng Lett. 2023;12:543–52.
Article
Google Scholar
Li G, Li J, Dong M, Zuo S. An interference inspection algorithm of limb and hexapod frame in the treatment of lower limb deformity. J Bio Eng. 2022;144(7): 071011.
Article
Google Scholar
Li G, Tang X, Li J, Dong M. Error identification and compensation regarding the kinematic parameter of the MD-PEF for tibial deformity correction. Comput Biol Med. 2023;158(2): 106813.
Article
Google Scholar
Ganadhiepan G, Miramini S, Patel M, Mendis P, Zhang L. Bone fracture healing under Ilizarov fixator: influence of fixator configuration, fracture geometry, and loading. Int J Numer Methods Biomed Eng. 2019;35(9): e3199.
Article
Google Scholar
Moazen M, Calder P, Koroma P, Wright J, Taylor S, Blunn G. An experimental evaluation of fracture movement in two alternative tibial fracture fixation models using a vibrating platform. P I Mech Eng H. 2019;233(5):595–9.
Article
Google Scholar
Zuo S, Li J, Dong M, Jiao R, Wang S, Ju J, Wang Y. Design of composite parallel external fixator for multisegment foot and ankle deformity correction: a correction requirement-dominated approach. IEEE/ASME T Mech. 2023;99:1–11.
Google Scholar
Buschbaum J, Fremd R, Pohlemann T, Kristen A. Introduction of a computer-based method for automated planning of reduction paths under consideration of simulated muscular forces. Int J Comput Assist Radiol Surg. 2017;12(3):1–13.
Google Scholar
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