Analysis of Domestic and International Biomechanics Research Trends in Shoes: Focusing on Research Published in 2015-2019
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Back, Heeyoung
(Division of Kinesiology & Sports Studies, College of Science and Industry Convergence, Ehwa Womans University)
Yi, Kyungock (Division of Kinesiology & Sports Studies, College of Science and Industry Convergence, Ehwa Womans University) Lee, Jusung (Department of sport science, Kangwon National University) Kim, Jieung (Department of Physical Education, Sangmyung University) Moon, Jeheon (Department of Sport Science, Korea Institute of Sport Science) |
1 | Rahemi, H., Nguyen, H., Lee, H. & Najafi, B. (2018). Toward smart footwear to track frailty phenotypes-using propulsion performance to determine frailty. Sensors, 18(6), 1763. DOI |
2 | Sadigursky, D., Santos, N. A. M., Queiroz, G. C. D., Oliveira, L., Souza, M. P. D., Carneiro, R. J. F. & Colavolpe, P. O. (2017). Customized footwear for motion control to treat anterior knee pain among runners. Medical Express, 4(2), 1-7. |
3 | Sayer, T. A., Hinman, R. S., Paterson, K. L., Bennell, K. L., Fortin, K., Kasza, J. & Bryant, A. L. (2019). Differences and mechanisms underpinning a change in the knee flexion moment while running in stability and neutral footwear among young females. Journal of Foot and Ankle Research, 12(1), 1-9. DOI |
4 | Shin, H. S., Lee, K. K., Kim, M. S. & Park, J. H. (2007). The effects of shoes with curved out-sole on the variations of static posture and EMG of calf. Journal of the Ergonomics Society of Korea, 267-277. |
5 | Shinde, M. R. A., Nalbalwar, S. L. & Singh, S. (2019). Smart Shoes: Walking Towards a Better Future. International Journal of Engineering Research & Technology, 8(7), 328-330. |
6 | Sinclair, J. & Sant, B. (2017). The effects of cross-fit footwear on the kinetics and kinematics of running. Footwear Science, 9(1), 41-48. DOI |
7 | Sinclair, J. & Sant, B. (2018). Effects of High-and Low-Cut Footwear on the Kinetics and 3D Kinematics of Basketball Specific Motions. Journal of Mechanics in Medicine and Biology, 18(1), 1-26. |
8 | Sinclair, J., Bottoms, L., Taylor, P. J. & Mahmood, K. (2017). Effects of shoes on kinetics and kinematics of the squash forward lunge in male players. Kinesiology: International Journal of Fundamental and Applied Kinesiology, 49(2), 178-184. DOI |
9 | Sinclair, J., Brooks, D. & Stainton, P. (2019). Biomechanical effects of a lightweight, sock-style minimalist footwear design during running: a musculoskeletal simulation and statistical parametric mapping approach. Footwear Science, 11(2), 71-83. DOI |
10 | Sinclair, J., Chockalingam, N., Naemi, R. & Vincent, H. (2015). The effects of sport-specific and minimalist footwear on the kinetics and kinematics of three netball-specific movements. Footwear Science, 7(1), 31-36. DOI |
11 | Sinclair, J., Rooney, E., Naemi, R., Atkins, S. & Chockalingam, N. (2017). Effects of footwear variations on three-dimensional kinematics and tibial accelerations of specific movements in American football. Journal of Mechanics in Medicine and Biology, 17(02), 1-16. |
12 | Sinclair, J., Toth, J. & Hobbs, S. J. (2015). The influence of energy return and minimalist footwear on the kinetics and kinematics of depth jumping in relation to conventional trainers. Kinesiology: International Journal of Fundamental and Applied Kinesiology, 47(1), 11-18. |
13 | Song, J. H., Lee, J. H. & Sung, B. J. (2008). A Comparative Analysis in Kinetics between Spring Shoes and Normal Shoes. Korean Journal of Sport Science, 19(1), 1-8. DOI |
14 | Talaty, M., Patel, S. & Esquenazi, A. (2016). A Randomized Comparison of the Biomechanical Effect of Two Commercially Available Rocker Bottom Shoes to a Conventional Athletic Shoe During Walking in Healthy Individuals. The Journal of Foot and Ankle Surgery, 55(4), 772-776. DOI |
15 | Dames, K. D. & Smith, J. D. (2016). Effects of load carriage and footwear on lower extremity kinetics and kinematics during overground walking. Gait Posture, 50, 207-211. DOI |
16 | Burns, G. T. & Tam, N. (2019). Is it the shoes? A simple proposal for regulating footwear in road running. British Journal of Sports Medicine, 1(1), 1-2 DOI |
17 | Byun, K. S. (2010). Biomechanical analysis of different outsole types of functional walking shoes. Unpublished Master's degree thesis, Graduate School of Sungkyunkwan University. |
18 | Cheng, W. K., Lam, H. L., Lin, F. & Ge, M. (2019). A customizable smart shoes with location tracking function for the elderly. Materials Today: Proceedings, 16, 1423-1430. DOI |
19 | Cho, H. S. & Chae, S. W. (2017). The Effect of Masai Shoes on Lumbar Disc using Motion Capture and FEM. Korean Society for Precision Engineering, 628-628. |
20 | Choi, K. J. (2003). Biomechanical differences between general walking shoe and MBT functional walking shoe. published Doctor's Dissertation. Unpublished Graduate School of Sungkyunkwan University. |
21 | Fredericks, W., Swank, S., Teisberg, M., Hampton, B., Ridpath, L. & Hanna, J. B. (2015). Lower extremity biomechanical relationships with different speeds in traditional, minimalist, and barefoot footwear. Journal of Sports Science and Medicine, 14(2), 276-283. |
22 | Firminger, C. R. & Edwards, W. B. (2016). The influence of minimalist footwear and stride length reduction on lowerextremity running mechanics and cumulative loading. Journal of Science and Medicine in Sport, 19(12), 975-979. DOI |
23 | Firminger, C. R., Fung, A., Loundagin, L. L. & Edwards, W. B. (2017). Effects of footwear and stride length on metatarsal strains and failure in running. Clinical Biomechanics, 49(1), 8-15. DOI |
24 | Franklin, S., Grey, M. J., Heneghan, N., Bowen, L. & Li, F. X. (2015). Barefoot vs common footwear: a systematic review of the kinematic, kinetic and muscle activity differences during walking. Gait & Posture, 42(3), 230-239. DOI |
25 | Fu, L., Gu, Y., Mei, Q., Baker, J. S. & Fernandez, J. (2019). A kinematics analysis of the lower limb during running with different sports shoes. Proceedings of the Institution of Mechanical Engineers, Part P: Journal of Sports Engineering and Technology, 233(1), 46-52. |
26 | Wegener, C., Greene, A., Burns, J., Hunt, A. E., Vanwanseele, B. & Smith, R. M. (2015). In-shoe multi-segment foot kinematics of children during the propulsive phase of walking and running. Human Movement Science, 39(1), 200-211. DOI |
27 | Fuller, J. T., Bellenger, C. R., Thewlis, D., Tsiros, M. D. & Buckley, J. D. (2015). The effect of footwear on running performance and running economy in distance runners. Sports Medicine, 45(3), 411-422. DOI |
28 | Hoerzer, S., Federolf, P. A., Maurer, C., Baltich, J. & Nigg, B. M. (2015). Footwear Decreases Gait Asymmetry during Running. PloS One, 10(10), 1-12. |
29 | Hunter, I., McLeod, A., Valentine, D., Low, T., Ward, J. & Hager, R. (2019). Running economy, mechanics, and marathon racing shoes. Journal of Sports Sciences, 37(20), 2367-2373. DOI |
30 | Udofa, A. B., Clark, K. P., Ryan, L. J. & Weyand, P. G. (2019). Running ground reaction forces across footwear conditions are predicted from the motion of two body mass components. Journal of Applied Physiology, 126(5), 1315-1325. DOI |
31 | Wei, Q., Wang, Z., Woo, J., Liebenberg, J., Park, S. K., Ryu, J. & Lam, W. K. (2018). Kinetics and perception of basketball landing in various heights and footwear cushioning. PloS One, 13(8), 1-9. |
32 | Yeo, M. W., Lee, S. D. & Lee, B. H. (2006). Comparison of functionality through ergonomic evaluation of functional momentum increased shoes. Journal of the Ergonomics Society of Korea, 537-540. |
33 | Kim, Y. J. & Park, J. W. (2016). The Influence of Unstable Shoes on Kinematics and Kinetics of the Lower limb Joints during Sit-to-stand task. The Journal of Korean Physical Therapy, 28(1), 14-21. DOI |
34 | Hutchison, L., Scharfbillig, R., Uden, H. & Bishop, C. (2015). The effect of footwear and foot orthoses on transverse plane knee motion during running-A pilot study. Journal of Science and Medicine in Sport, 18(6), 748-752. DOI |
35 | Jeong, N. S., Hackett, E. G., Lee, J. Y. & Sazonov, E. (2019). Loosely Coupled Wireless Charging of Footwear-based Sensor System. IEEE 20th Wireless and Microwave Technology Conference, 1-3. |
36 | Jun, S. P., Yoo, Y. W. & Park, S B. (2018). The Pre-Study of Development of Smart Shoe with Musculoskeletal Injury Prevention and Monitoring System: Selection of Plantar Pressure Sensor Location and Development of Prototype. Journal of the Ergonomics Society of Korea, 37(2), 101-110. |
37 | Kim, H. S., Lee, U. H. & Kim, J. C. (2016). Development of an IoT-Based Small Wearable Device Attachable to Shoes for Healthcare. The Korean Institute of Broadcast and Media Engineers, 1(2), 154-156. |
38 | Kim, K. I. (2015). Forecast of rapid market growth due to convergence with smart shoes and health care systems. Kisti Market Report, 1(1), 3-6. |
39 | Kim, T. S. & Kwon, S. R. (2017). Real Time Healthcare System using Smart Shoes. The Institute of Electronics and Information Engineers, 1(1), 1372-1373. |
40 | Kim, Y. J. & Chae, W. S. (2007). The Plantar Pressure Comparison between the Curved Rear Balance Shoes and Normal Shoes. Korean Journal of Sport Biomechanics, 17(3), 173-180. DOI |
41 | Langley, B., Cramp, M. & Morrison, S. C. (2019). The Influence of Motion Control, Neutral, and Cushioned Running Shoes on Lower Limb Kinematics. Journal of Applied Biomechanics, 35(3), 216-222. DOI |
42 | Kulmala, J. P., Kosonen, J., Nurminen, J. & Avela, J. (2018). Running in highly cushioned shoes increases leg stiffness and amplifies impact loading. Scientific Reports, 8(1), 17496. DOI |
43 | Kwak, C. S. & Yoon, J. S. (2017). The Effects of Minimal Shoe on Lower Extremity Biomechanics and Safety During Running. Korean Journal of Teacher Education, 33(1), 113-130. |
44 | Lacirignola, J., Weston, C., Byrd, K., Metzger, E., Singh, N., Davis, S. ... & Richter, M. (2017). Instrumented footwear inserts: a new tool for measuring forces and biomechanical state changes during dynamic movements. IEEE 14th International Conference on Wearable and Implantable Body Sensor Networks (BSN). 119-124. |
45 | Landorf, K. B. & Keenan, A. M. (2002). An evaluation of two foot-specific, health-related quality-of-life measuring instruments. Foot & ankle International, 23(6), 538-546. DOI |
46 | Langley, B., Cramp, M. & Morrison, S. C. (2018). The influence of running shoes on inter-segmental foot kinematics. Footwear Science, 10(2), 83-93. DOI |
47 | Li, G., Liu, T., Yi, J., Wang, H., Li, J. & Inoue, Y. (2016). The lower limbs kinematics analysis by wearable sensor shoes. IEEE Sensors Journal, 16(8), 2627-2638. DOI |
48 | Nam, H. C., Moon, G. H. & Choi, Y. J. (2016). Changes in Balance and Gait Patterns with Different Heel Heights Among Women in Their 20's. Journal of The Korean Society of Integrative Medicine, 4(1), 49-56. DOI |
49 | McHenry, R. D., Arnold, G. P., Wang, W. & Abboud, R. J. (2015). Footwear in rock climbing: Current practice. The Foot (Edinb), 25(3), 152-158. DOI |
50 | Moon, K. S. & Song, H. S. (2017). A shoe structure for function implementation of a smart shoe. Korean Society for Precision Engineering, 617-617. |
51 | Park, J. J., Kim, K. H. & Park, S. B. (2015). The Analysis of Foot Pressure and Lap Time for the Development of Korean Bobsleigh Shoes. Korean Journal of Sport Biomechanics, 25(4), 465-474. DOI |
52 | Nam, K. J., Lee, J. H. & Kim, J. P. (2015). The Review of Biomechanical Analysis of Functional shoes for invent a nurses shoes. Korean Journal of Sports Science, 24(3), 1617-1627. |
53 | Nigg, B. M. (1986). Some comments forerunners. In Biomechanics of running shoes, N.M.nigg (ed), champaign: Human Kinemetics Publishers, 1(1), 162-165. |
54 | Papalia, R., Di Pino, G., Tecame, A., Vadala, G., Formica, D., Di Martino, A. & Denaro, V. (2015). Biomechanical and neural changes evaluation induced by prolonged use of nonstable footwear: a systematic review. Musculoskeletal Surgery, 99(3), 179-187. DOI |
55 | Park, J. J. & Park, S. B. (2015). Biomechanical Anlaysis for the Development of Windlass Mechanism for Trail-walking Shoe, Korean Journal of Sport Biomechanics, 25(4), 489-498. DOI |
56 | Park, S. B., Lee, K. D., Kim, D. W., Yoo, J. H., Jung, J. M., Park, K. H. & Kim, J. H. (2016b). An Analysis of Lower Extremity of Range of Motion and Forefoot Bending Angle in Bobsleigh Start by Bobsleigh Shoe. Journal of the Korean Society for Precision Engineering, 589-590. DOI |
57 | Park, S. B. (2006). A Biomechanical Footwear Research & Analysis in Korea and Past, Present and Future in International Research Trend. Journal of the Ergonomics Society of Korea, 77-82. |
58 | Park, S. B., Kim, C. H. & Joo, J. P. (2006). A Biomechanical Research in functional footwear development for Degenerative Osteoarthritis Patients. Journal of the Ergonomics Society of Korea, 83-89. |
59 | Park, S. B., Lee, K. D., Kim, D. W., Yoo, J. H., Jung, J. M., Park, K. H. & Ryu, W. H. (2016a). Development of biomechanicsbased sports climbing shoes with excellent sweat absorption and quick drying through plantar pressure analysis. Journal of the Ergonomics Society of Korea, 414-414. |
60 | Park, S. B., Lee, K. D., Kim, D. W., Yoo, J. H., Jung, J. M., Park, K. H. & Ryu, W. H. (2017a). Current status of footwear development using 3D printing. Journal of the Ergonomics Society of Korea, 232-232. |
61 | Park, S. B., Lee, K. D., Kim, D. W., Yoo, J. H., Jung, J. M., Park, K. H. & Ryu, W. H. (2017b). Current status and prospect of smart shoes technology development. Journal of the Ergonomics Society of Korea, 219-219. |
62 | Pham, C., Diep, N. N. & Phuong, T. M. (2017). e-Shoes: Smart shoes for unobtrusive human activity recognition. In 2017 9th International Conference on Knowledge and Systems Engineering, 269-274. |
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