Three-dimensional computational model simulating the fracture healing process with both biphasic poroelastic finite element analysis and fuzzy logic control
Abstract A dynamic model regulated by both biphasic poroelastic finite element analysis and fuzzy logic control was established. Fuzzy logic control was an easy and comprehensive way to simulate the tissue differentiation process, and it is convenient for researchers and medical experts to communica...
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Nature Portfolio
2018
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oai:doaj.org-article:d9437519dd5e4f47b1393bec42cdc3212021-12-02T15:08:34ZThree-dimensional computational model simulating the fracture healing process with both biphasic poroelastic finite element analysis and fuzzy logic control10.1038/s41598-018-25229-72045-2322https://doaj.org/article/d9437519dd5e4f47b1393bec42cdc3212018-04-01T00:00:00Zhttps://doi.org/10.1038/s41598-018-25229-7https://doaj.org/toc/2045-2322Abstract A dynamic model regulated by both biphasic poroelastic finite element analysis and fuzzy logic control was established. Fuzzy logic control was an easy and comprehensive way to simulate the tissue differentiation process, and it is convenient for researchers and medical experts to communicate with one another to change the fuzzy logic rules and improve the simulation of the tissue differentiation process. In this study, a three-dimensional fracture healing model with two different interfragmentary movements (case A: 0.25 mm and case B: 1.25 mm) was analysed with the new set-up computational model. As the healing process proceeded, both simulated interfragmentary movements predicted a decrease and the time that the decrease started for case B was later than that for case A. Compared with experimental results, both cases corresponded with experimental data well. The newly established dynamic model can simulate the healing process under different mechanical environments and has the potential to extend to the multiscale healing model, which is essential for reducing the animal experiments and helping to characterise the complex dynamic interaction between tissue differentiations within the callus region.Monan WangNing YangNature PortfolioarticleMedicineRScienceQENScientific Reports, Vol 8, Iss 1, Pp 1-13 (2018) |
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Medicine R Science Q |
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Medicine R Science Q Monan Wang Ning Yang Three-dimensional computational model simulating the fracture healing process with both biphasic poroelastic finite element analysis and fuzzy logic control |
| description |
Abstract A dynamic model regulated by both biphasic poroelastic finite element analysis and fuzzy logic control was established. Fuzzy logic control was an easy and comprehensive way to simulate the tissue differentiation process, and it is convenient for researchers and medical experts to communicate with one another to change the fuzzy logic rules and improve the simulation of the tissue differentiation process. In this study, a three-dimensional fracture healing model with two different interfragmentary movements (case A: 0.25 mm and case B: 1.25 mm) was analysed with the new set-up computational model. As the healing process proceeded, both simulated interfragmentary movements predicted a decrease and the time that the decrease started for case B was later than that for case A. Compared with experimental results, both cases corresponded with experimental data well. The newly established dynamic model can simulate the healing process under different mechanical environments and has the potential to extend to the multiscale healing model, which is essential for reducing the animal experiments and helping to characterise the complex dynamic interaction between tissue differentiations within the callus region. |
| format |
article |
| author |
Monan Wang Ning Yang |
| author_facet |
Monan Wang Ning Yang |
| author_sort |
Monan Wang |
| title |
Three-dimensional computational model simulating the fracture healing process with both biphasic poroelastic finite element analysis and fuzzy logic control |
| title_short |
Three-dimensional computational model simulating the fracture healing process with both biphasic poroelastic finite element analysis and fuzzy logic control |
| title_full |
Three-dimensional computational model simulating the fracture healing process with both biphasic poroelastic finite element analysis and fuzzy logic control |
| title_fullStr |
Three-dimensional computational model simulating the fracture healing process with both biphasic poroelastic finite element analysis and fuzzy logic control |
| title_full_unstemmed |
Three-dimensional computational model simulating the fracture healing process with both biphasic poroelastic finite element analysis and fuzzy logic control |
| title_sort |
three-dimensional computational model simulating the fracture healing process with both biphasic poroelastic finite element analysis and fuzzy logic control |
| publisher |
Nature Portfolio |
| publishDate |
2018 |
| url |
https://doaj.org/article/d9437519dd5e4f47b1393bec42cdc321 |
| work_keys_str_mv |
AT monanwang threedimensionalcomputationalmodelsimulatingthefracturehealingprocesswithbothbiphasicporoelasticfiniteelementanalysisandfuzzylogiccontrol AT ningyang threedimensionalcomputationalmodelsimulatingthefracturehealingprocesswithbothbiphasicporoelasticfiniteelementanalysisandfuzzylogiccontrol |
| _version_ |
1718388091939454976 |