Biomimetic 3D aligned conductive tubular cryogel scaffolds with mechanical anisotropy for 3D cell alignment, differentiation and in vivo skeletal muscle regeneration

Developing 3D conductive aligned cryogels has great potential for skeletal muscle trauma treatment because they can mimic anisotropic structure, conductivity, and recoverable cyclic compression of the microenvironment of native skeletal muscle. In this work, a series of cryogels possessing 3D aligned morphology, conductivity, and excellent anisotropic mechanical compression property based on gelatin (GT) and polydopamine coated carbon nanotubes (PCNTs) were fabricated as skeletal muscle tissue scaffolds by using unidirectional freeze casting technology. The aligned microstructure of cryogels depended on gelatin concentration, and GT7.5 (with the gelatin content of 7.5% w/v) showed excellent aligned structure. Interestingly, the mechanical property of the aligned cryogels was similar to that of native skeletal muscle in terms of the dynamic contraction behavior and the anisotropic compression property due to the internal anisotropy structure. The aligned cryogel GT7.5 with good biocompatibility significantly promoted the alignment and elongation of C2C12 myoblasts. Moreover, the introduction of PCNTs enhanced the mechanical properties of cryogel GT7.5 and had a positive effect on myogenic differentiation of C2C12 cells. The aligned conductive GT7.5C2 cryogel significantly promoted new born muscle tissue generation compared to non-aligned group (GT7.5C2N) and non-conductive group (GT7.5) in a rat tibialis anterior muscle defect model. These data suggested that the 3D aligned conductive cryogel with conductivity and anisotropic compression property is a promising scaffold candidate for skeletal muscle tissue engineering.

Automated summary

Developing 3D conductive aligned cryogels has great potential for skeletal muscle trauma treatment as they can mimic the anisotropic structure and conductivity of native skeletal muscle. These cryogels possess excellent mechanical properties and promote muscle tissue regeneration, making them promising scaffold candidates for skeletal muscle tissue engineering.