Organ-on-a-chip stands as a pivotal platform for skeletal muscle research while constructing 3D skeletal muscle tissues that possess both macroscopic and microscopic structures remains a considerable challenge.This st...Organ-on-a-chip stands as a pivotal platform for skeletal muscle research while constructing 3D skeletal muscle tissues that possess both macroscopic and microscopic structures remains a considerable challenge.This study draws inspiration from LEGO-like assembly,employing a modular approach to construct muscle tissue that integrates biomimetic macroscopic and microscopic structures.Modular LEGO-like hybrid nanofibrous scaffold bricks were fabricated by the combination of 3D printing and electrospinning techniques.Skeletal muscle cells cultured on these modular scaffold bricks exhibited a highly orientated nanofibrous structure.A variety of construction of skeletal muscle tissues further enabled development by various assembling processes.Moreover,skeletal muscle-on-a-chip(SMoC)was further assembled as a functional platform for electrical or perfusion stimuli investigation.The electrical stimulus was conveniently applied and tuned in such a SMoC platform to significantly enhance the differentiation of skeletal muscle tissues.Additionally,the effect of perfusion stimulation on skeletal muscle vascularization within the SMoC platform was also demonstrated.These findings highlight the potential of these assembled SMoCs as functional ex vivo platforms for skeletal tissue engineering and drug research applications,and such a LEGO-like assembly strategy could also be applied to the other engineering organ-on-chips fabrication,which facilitates the development of bionic functional platforms for various biomedical research applications.展开更多
基金supported by the National Natural Science Foundation of China(32271423,32000955)the National Key R&D Program of China(2022YFB4600600)the Guangdong Basic and Applied Basic Research Foundation(2024A1515013273).
文摘Organ-on-a-chip stands as a pivotal platform for skeletal muscle research while constructing 3D skeletal muscle tissues that possess both macroscopic and microscopic structures remains a considerable challenge.This study draws inspiration from LEGO-like assembly,employing a modular approach to construct muscle tissue that integrates biomimetic macroscopic and microscopic structures.Modular LEGO-like hybrid nanofibrous scaffold bricks were fabricated by the combination of 3D printing and electrospinning techniques.Skeletal muscle cells cultured on these modular scaffold bricks exhibited a highly orientated nanofibrous structure.A variety of construction of skeletal muscle tissues further enabled development by various assembling processes.Moreover,skeletal muscle-on-a-chip(SMoC)was further assembled as a functional platform for electrical or perfusion stimuli investigation.The electrical stimulus was conveniently applied and tuned in such a SMoC platform to significantly enhance the differentiation of skeletal muscle tissues.Additionally,the effect of perfusion stimulation on skeletal muscle vascularization within the SMoC platform was also demonstrated.These findings highlight the potential of these assembled SMoCs as functional ex vivo platforms for skeletal tissue engineering and drug research applications,and such a LEGO-like assembly strategy could also be applied to the other engineering organ-on-chips fabrication,which facilitates the development of bionic functional platforms for various biomedical research applications.
