Biogeotechnics is an interdisciplinary journal that bridges the gap between bioengineering,bionics and earth science engineering,particularly in the areas of bio-mediated design such as biomineralization,soil bioengin...Biogeotechnics is an interdisciplinary journal that bridges the gap between bioengineering,bionics and earth science engineering,particularly in the areas of bio-mediated design such as biomineralization,soil bioengineering using vegetation and fungi and bio-inspired design in the applications of geotechnical engineering.The journal aims to publish original studies on the experimental and theoretical aspects of bio-mediated and bio-inspired solutions in the geotechnical system,including laboratory and field testing,computational methods,design principles and site investigation.展开更多
Biogeotechnics is an interdisciplinary journal that bridges the gap between bioengineering,bionics and earth science engineering,particularly in the areas of bio-mediated design such as biomineralization,soil bioengin...Biogeotechnics is an interdisciplinary journal that bridges the gap between bioengineering,bionics and earth science engineering,particularly in the areas of bio-mediated design such as biomineralization,soil bioengineering using vegetation and fungi and bio-inspired design in the applications of geotechnical engineering.展开更多
The biomimetic materials that replicate the mechanical gradient transitions from muscle to tendon to bone remain a significant challenge in tissue engineering,particularly through simple and environmentally friendly a...The biomimetic materials that replicate the mechanical gradient transitions from muscle to tendon to bone remain a significant challenge in tissue engineering,particularly through simple and environmentally friendly approaches.This mechanical gradient is crucial for applications such as rotator cuff and Achilles tendon repair patches,which prevent stress shielding and ensure uniform stress distribution,addressing the stress concentration issues common in traditional repairs.Here,we present a strategy that achieves high strength even at high water content,enabling programmable modulus/structural gradients with broad applicability.Using rotator cuff tendon repair as a model system,we demonstrate successful in vivo tissue regeneration with integrated real-time sensing capabilities,providing quantitative data for rehabilitation protocols.The hydrogels exhibit precisely controlled regional mechanical properties and seamless interface transitions,mimicking the hierarchical structure of native tissue.This approach not only improves healing outcomes compared to conventional methods but also establishes a quantitative standard for rehabilitation training.展开更多
文摘Biogeotechnics is an interdisciplinary journal that bridges the gap between bioengineering,bionics and earth science engineering,particularly in the areas of bio-mediated design such as biomineralization,soil bioengineering using vegetation and fungi and bio-inspired design in the applications of geotechnical engineering.The journal aims to publish original studies on the experimental and theoretical aspects of bio-mediated and bio-inspired solutions in the geotechnical system,including laboratory and field testing,computational methods,design principles and site investigation.
文摘Biogeotechnics is an interdisciplinary journal that bridges the gap between bioengineering,bionics and earth science engineering,particularly in the areas of bio-mediated design such as biomineralization,soil bioengineering using vegetation and fungi and bio-inspired design in the applications of geotechnical engineering.
基金supported by the Fundamental Research Funds for the Central Universities(No.2022JC013)National NaturalScience Foundation of China(Grant No.12204271)+1 种基金Natural Science Foundation of Shandong Province of China(No.ZR2021MH023)National Natural Science Foundation of China(No.62401343).
文摘The biomimetic materials that replicate the mechanical gradient transitions from muscle to tendon to bone remain a significant challenge in tissue engineering,particularly through simple and environmentally friendly approaches.This mechanical gradient is crucial for applications such as rotator cuff and Achilles tendon repair patches,which prevent stress shielding and ensure uniform stress distribution,addressing the stress concentration issues common in traditional repairs.Here,we present a strategy that achieves high strength even at high water content,enabling programmable modulus/structural gradients with broad applicability.Using rotator cuff tendon repair as a model system,we demonstrate successful in vivo tissue regeneration with integrated real-time sensing capabilities,providing quantitative data for rehabilitation protocols.The hydrogels exhibit precisely controlled regional mechanical properties and seamless interface transitions,mimicking the hierarchical structure of native tissue.This approach not only improves healing outcomes compared to conventional methods but also establishes a quantitative standard for rehabilitation training.
