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ObjectiveTo review the classification of orthopedic insoles, common techniques of 3D printing orthopedic insoles, common materials and their application for flatfoot. MethodsLiteratures were retrieved from PubMed, Web of Science, CNKI and Wanfang Data from 2012 to 2022, and the relevant contents were summarized. ResultsA total of ten studies were finally included, from 5 countries, involving 290 participants, which published from 2019 to 2022. Orthotic insoles were classified as prefabricated, semi-custom, and custom, while custom ones were classified as traditional custom and 3D printed custom. 3D printed orthotic insoles were often made with selective laser sintering, fused deposition modeling (FDM) and PolyJet printing technologies, and commonly used materials included ethylene-vinyl acetate (EVA), polylactic acid, thermoplastic polyurethane, polyamide, and polypropylene. For flatfoot, 3D printed orthotic insoles could improve plantar pressure, relieve foot pain and the combined use of insole posting could control rearfoot valgus. Conclusion3D printed custom insoles can be made more efficiently and accurately than traditional custom insoles. The printing technologies and materials often chosen for 3D printed orthotic insoles are mainly FDM and EVA. 3D printed orthotic insoles is effective on plantar pressure, comfort and foot movement function of flatfoot.
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Objective To design a kind of customized insole with zonal gradient hardness for people with high arch foot in need of plantar decompression. Methods A functional gradient structure was designed and applied to the customized insole. Porous elements with corresponding elastic modulus were used in different areas of insole. The relationship between structural element parameters and modulus was studied through mechanical tests. The foot geometry and plantar pressure distribution data of volunteers were collected, and the plantar region was divided according to the pressure contour line, so as to assemble the structural unit. Four kinds of customized insoles were designed: ordinary flat insole, optimized flat insole, ordinary full contact insole and optimized full contact insole. Through plantar pressure test experiment, the optimization design of sub region was verified. Results The designed insole could reduce the peak pressure of high arch foot by 52.8% in static standing state and 18.43% in gait condition. Conclusions This method can be used to design customized insoles, such as functional insoles for patients with diabetes and high arch feet, by providing better decompression function. The research findings provide references for conservative treatment of foot diseases with decompression needs.
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[Objective] To explore the characteristics of the plantar pressure data of the patients with adolescent idiopathic scoliosis (AIS).[Methods] 56 AIS patients who were diagnosed from October 2015 to March 2017 in the East branch of the First Affiliated Hospital of Sun Yat-sen University divided into 3 groups,18 cases in spinal lateral bending to right,18 cases in spinal lateral bending to left,20 cases in type S who were thoracolumbar scoliosis.Another 19 healthy persons were as the control group.The left and right foot pressure,half foot pressure and other biomechanical data were compared.The changes of the plantar pressure and the Cobb angle were analyzed with the patients who wore orthopedic insoles.[Results] Compared with the control group,the mean pressure of the left foot and the pressure of the left anterior half of the right bending group were less than those of the control group,and the right half foot pressure were greater than those of the control group (P < 0.017).To the left bending group,the mean pressure of right anterior half foot were less than those of the control group,and the right rear half foot pressure was greater than that of the control group (P < 0.017).The pressure of the left anterior half foot of the S type scoliosis group was less than that of the control group.To the right bending group,the left foot average pressure (44.7%±6.0%) was significantly less than the average pressure of right foot (55.4% ± 6.0%).There was no difference in bilateral plantar pressure of the left bending group,S type group and control group.There was difference with the plantar pressure distribution in patients with only one curve after they wore orthotic insoles,but there was no difference in patients with type S.There was no significant difference in the Cobb angle after the patients wearing the orthotic insoles (P =0.102).[Conclusions] The right and left foot pressure symmetry of the right bending patients is poor,but the left and right plantar pressure in the patients with type S is symmetrical.The orthotic insole can be used to adjust the plantar pressure distribution in patients with a single curved scoliosis (left or right),but their effect on the patient's spinal lateral curvature should be further observed.
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Objective To study the effect from different structures and material hardness of orthopedic insoles on flatfoot correction. Methods The contours of flatfoot under weight-bearing and non-weight-bearing conditions were scanned by Infoot system. The 3 kinds of medial longitudinal arch height (typeⅠ, Ⅱ, Ⅲ) and 3 kinds of material hardness (30°, 35°, 42°) from orthopedic insoles were used to compare their effects on flatfoot by the embedded insole test system. Results TypeⅠorthopedic insoles could significantly restore the anatomical position by improving the height of navicular bone, and redistribute the concentrated plantar pressure and increase the loading area of medial longitudinal arch with material hardness of 35°. Conclusions The appropriate insole shows a favorable orthopedic effect to ameliorate the foot deformity of flatfoot patients. The research findings lay a theoretical basis on design of the personalized orthopedic insoles.