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Short Talk
ST 78

Fabrication of functional, biocompatible and biodegradable biomaterials by 3D printing of cellulose nanofiber-filled chitosan hydrogel constructs for tissue engineering applications

Termin

Datum: 16.09.2023

Zeit: 09:30 – 09:45

Redezeit: 10 Min.

Diskussionszeit: 5 Min.

Ort / Stream:

Lecture hall 7

Session

Biofabrication / Hydrogels

Themen

Additive manufacturing (e. g. 3D printing)
Biofabrication

Mitwirkende

Abstract

Abstract text (incl. figure legends and references)

Introduction

The tissue engineering field favors the development of biomaterials that can support cell growth and regeneration, while being biocompatible, mechanically functional, biodegradable. Hydrogel biomaterials have lots of biomedical applications, like in wound healing, cartilage repair, organ regeneration.

Objectives

We aim to develop functional hydrogels, which mimic tissue extracellular matrix by combining cellulose nanofibers (CNF) and chitosan (CHI) hydrogel in extrusion 3D printing.

Materials & methods

The flow behavior of CNF-filled CHI suspensions was investigated by rheology. The mechanical properties of the printed CHI/CNF hydrogels was study by tensile testing. Fibroblast cells viability was assessed by LIVE/DEAD assays. CNF biodegradation was enzymatically studied during cell culture.

Results

CNFs improved the extrudability of CHI-based inks, resolution, stability of printed constructs. The Newtonian viscosity of CHI-based inks increased at adding the CNFs. The nanofibers improved gelation and mechanical properties of printed hydrogels, in systems of low CHI and CNF concentrations. Young"s modulus and strength as high as 3.0 MPa and 1.5 MPa, respectively, were achieved for hydrogels of c(CHI) of 2% and CNF content of 0.4%. Cell adhesion, proliferation and 3D cell growth was observed within the constructs. Cellulase-laden CHI/CNF scaffolds were also printed, allowing controlled biodegradation of hydrogels. The CNF biodegradation contributed to the sustained formation of pores in the CHI/CNF constructs, allowing cells for controlled infiltration and enhanced 3D cell growth.

Conclusion

The results are promising for the successful engineering of functional tissues. Design strategies for natural smart biomaterials, which are mechanically-performant, biocompatible, presenting controlled degradability for 3D cell growth were proposed. The developed biomaterials are expected to significantly impact tissue engineering and regenerative medicine.