In the human body, microfibril structures can be found in several types of tissue, such as muscles, nerves, and even tendons. In particular, muscle tissues have uniaxially-aligned microfibrous structures.
The team (first author: Won Jin KIM) led by Geun Hyung KIM (Department of Biomechatronics Engineering at Sungkyunkwan University) fabricated a structure composed of bundled poly (e-caprolactone) (PCL) microfibers coated with collagen. To obtain the bundle of uniaxially-aligned (PCL) microfibers, 4D printing methods using a poly (vinyl alcohol) (PVA) fibrillation/leaching process were used. PVA was dissolved in distilled water to fibrillate the PVA. Then, PCL was added to the PVA solution and mixed. After mixing, the PVA/PCL mixture was printed using a 3D printer. The fabricated 3D structure was immersed in water to leach the fibrillated PVA. By using this simple fabricating method, a uniaxially micropatterned/fibrous PCL bundle was achieved. The fabricated structure was supplemented with collagen to increase the biocompatibility of the PCL bundle. The hybrid microfibrillated structure promoted myoblast proliferation and myogenic differentiation.
¡°Due to the 4D printing process, it was able to have high efficiency in the fabrication of 3D scaffolds with highly aligned microfibrous bundles. In addition, a variety of designs and complex microscale-patterned 3D structures were constructed because of a highly versatile 3D printing method,¡± Prof. KIM said.
Published article:
W. Kim, M. Kim, G. H. Kim, Adv. Funct. Mater. 2018, 1800405.
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