Scientists Construct High-strength Microtube by Coaxial Printing with Customized Biohybird Hydrogel Ink

Date:25-09-2020   |   【Print】 【close

Coaxial extrusion printing has been developing toward generating microtubes for mimicking tubular tissues these years. However, these generated microtubes with insufficient mechanical properties and uncontrollable inherent swelling attribute severely hinder their utilization as load-bearing tubular tissue.

Recently, a research team led by Dr. RUAN Changshun from the Shenzhen Institutes of Advanced Technology (SIAT) of the Chinese Academy of Sciences constructed a high-strength microtube by coaxial printing with a customized biohybird hydrogel ink (CNG ink).

The biohybird hydrogel ink is consisted of nanoclay, H-bonding monomer N-acryloyl glycinamide and gelatin methacryloyl. 

Thanks to the coexistence of physical interpenetration, chemical crosslinks and reversible Nacryloyl glycinamide (NAGA) hydrogen bonding interactions, the biohybird hydrogel ink demonstrated an excellent printability and self-supporting property, and could be printed into microtube continuously and stably with a long length and tunable diameter simply by regulating external/internal needle size in the coaxial nozzle. Moreover, this proposed strategy is suited for scale-up production of microtubes with variable diameters.  

The CNG hydrogel microtubes demonstrated swelling stability, high toughness, ultra-stretchability, compression resistance, rapid self-recovery property, excellent perfusion as well as controllable permeation. Additionally, it exhibited excellent biocompatibility and accelerated endothelialization, which suggested its appealing promise as tubular tissue grafts.  

The team believes that this study would open up a universal and facile method for scale-up fabrication of high-strength microtubes with a huge potential in regeneration of tube-like tissues. 

The study was published in Advanced Functional Materials. 

 

Schematic diagram of the fabrication and characterization of microtubes (Image by SIAT) 

Media Contact:
ZHANG Xiaomin
Email: xm.zhang@siat.ac.cn