Application and innovation of biomechanics-based energy consumption model for human movement in landscape planning
Abstract
Based on the principle of cell molecular biomechanics, this study delves into the human movement energy consumption model for landscape planning. Human movement is underpinned by muscle cell activities. Muscle cells' actin and myosin filaments, regulated by calcium and ATP, cause contractions. Integrating diverse data, a precise prediction model is built. It factors in cell molecular aspects like ATP consumption efficiency related to mitochondria and energy transduction pathways. Also considered are biomechanical stresses on muscle and connective tissues during movement and cellular responses to environmental elements. Applied to landscape cases, the model uncovers optimization strategies. By understanding cell molecular biomechanics, landscape designs can be tweaked to ease muscle cell workload, cutting energy use. This lessens muscle fatigue and potential cell damage, enhancing environmental comfort. The results prove the model boosts landscape planning's scientific and practical value. It offers strong theoretical and practical support for sustainable urban growth and public health, spotlighting its vast potential and broad application scope in landscape planning.
References
1. Belyaev V A. Towards realistic blood cell biomechanics in microvascular thrombosis simulations. Russian Journal of Numerical Analysis and Mathematical Modelling,2024,39(5):223-242.
2. Vanderlinden A, Carlat R, Vincent B, et al. Biomechanical and clinical outcomes after distal biceps tendon reattachment using an endo button technique and an interference screw. JSES Reviews, Reports, and Techniques,2024,4(4):743-749.
3. Fraipont M G, Beyer S R, McGarry H M, et al. Acromioclavicular joint biomechanics: a systematic review. JSES Reviews, Reports, and Techniques,2024,4(4):668-675.
4. Adams G B, Tran J, Voinier S, et al. Morrey Award 2023: radial head donor plug for capitellum osteochondral autograft transfer: a cadaveric biomechanical analysis. JSES International,2024,8(6):1157-1163.
5. Metsavaht L, Santos G L A, Mombello F. Biomechanical Problems Related to Lesser Toes Dysfunction and Amputation. Foot and Ankle Clinics of North America,2024,29(4):753-765.
6. Vecchio DJJ, Pastor D M .Anatomy, Biomechanics, and Pathogenesis of the Lesser Toes Deformities. Foot and Ankle Clinics of North America,2024,29(4):557-569.
7. Paulon MG, Sudeesh S, Wei HL, et al. Firefighter helmets and cervical intervertebral Kinematics: An OpenSim-Based biomechanical study. Journal of Biomechanics,2024,176112364-112364.
8. Guo J, Krehl K, Safraou Y, et al. Pregnancy alters fatty acid metabolism, glucose regulation, and detoxification of the liver in synchrony with biomechanical property changes. Heliyon,2024,10(20):e39674-e39674.
9. Pitarch P E, Ng K Y E. PREFACE: APPLICATION AND PROGRESS OF BIOMECHANICS IN MEDICINE — PART III. Journal of Mechanics in Medicine and Biology,2024,(prepublish):
10. Li J, Li Y, Zhang J, et al. A comparative study of the effect of facet tropism on the index-level kinematics and biomechanics after artificial cervical disc replacement (ACDR) with Prestige LP, Prodisc-C vivo, and Mobi-C: a finite element study. Journal of Orthopaedic Surgery and Research,2024,19(1):705-705.
11. Yin, N., & Zhang, B. (2024). Exploring human body dynamics to optimize spatial arrangements in interior and landscape design. Molecular & Cellular Biomechanics, 21(3), 532. https://doi.org/10.62617/mcb532
12. Gong, Y., Zoltán, E. S., & János, G. (2023). Healthy Dwelling: The Perspective of Biophilic Design in the Design of the Living Space. Buildings, 13(8), 2020. https://doi.org/10.3390/buildings13082020
13. Hady, S.I.M.A. Activating biophilic design patterns as a sustainable landscape approach. J. Eng. Appl. Sci. 68, 46 (2021). https://doi.org/10.1186/s44147-021-00031-x
14. Musacchio, L.R. The scientific basis for the design of landscape sustainability: A conceptual framework for translational landscape research and practice of designed landscapes and the six Es of landscape sustainability. Landscape Ecol 24, 993–1013 (2009). https://doi.org/10.1007/s10980-009-9396-y
15. Discher, D., Dong, C., Fredberg, J.J. et al. Biomechanics: Cell Research and Applications for the Next Decade. Ann Biomed Eng 37, 847–859 (2009). https://doi.org/10.1007/s10439-009-9661-x
16. Andreucci, M. B., Loder, A., Brown, M., & Brajković, J. (2021). Exploring Challenges and Opportunities of Biophilic Urban Design: Evidence from Research and Experimentation. Sustainability, 13(8), 4323. https://doi.org/10.3390/su13084323
17. Shan, G. (2024). Research on Biomechanics, Motor Control and Learning of Human Movements. Applied Sciences, 14(22), 10678. https://doi.org/10.3390/app142210678
18. Smith, J. A. B., Murach, K. A., Dyar, K. A., & Zierath, J. R. (2023). Exercise metabolism and adaptation in skeletal muscle. Nature reviews. Molecular cell biology, 24(9), 607–632. https://doi.org/10.1038/s41580-023-00606-x
19. Huertas, J. R., Casuso, R. A., Agustín, P. H., & Cogliati, S. (2019). Stay Fit, Stay Young: Mitochondria in Movement: The Role of Exercise in the New Mitochondrial Paradigm. Oxidative medicine and cellular longevity, 2019, 7058350. https://doi.org/10.1155/2019/7058350
Copyright (c) 2025 Author(s)
This work is licensed under a Creative Commons Attribution 4.0 International License.
Copyright on all articles published in this journal is retained by the author(s), while the author(s) grant the publisher as the original publisher to publish the article.
Articles published in this journal are licensed under a Creative Commons Attribution 4.0 International, which means they can be shared, adapted and distributed provided that the original published version is cited.
Submit a Paper
