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Abstract

This article reports on 3D bioprinting of dissolved cellulose to produce small feature structures with a tailored design of regenerated cellulose. The process consists of dissolving cellulose with different origins and molecular weight in an ionic liquid (1-ethyl-3-methylimidazolium acetate), controlled multilayered dispensing, and coagulation. The printability was examined by studying the viscosity of cellulose solutions and by varying the settings of the printer setup regarding flow rate and needle dimensions. Water was added as a nonsolvent, enabling a coagulation process to form a gel structure of the printed solutions. By printing on a coagulating gel, the printed solutions were regenerated within a few seconds. Rheology analysis showed that higher concentrations of cellulose and cellulose of a high molecular weight were shear thinning, providing favorable printing properties. Printing 3D structures of cellulose dissolved in an ionic liquid followed by coagulation by a nonsolvent was possible. Both complex patterns of 2D structures as well as multilayered prints were created to obtain 3D structures. This novel method allows for the production of spatially tailored 3D gels or membrane structures made from cellulose.

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References

Gross

, Erkal

, Lockwood

, et al. Evaluation of 3D printing and its potential impact on biotechnology and the chemical sciences. Anal Chem, 2014; 86:3240–3253.

Sachs

, Cima

, Williams

, et al. Three dimensional printing: rapid tooling and prototypes directly from a CAD model. J Eng Ind, 1992; 114:481–488.

Zein

, Hutmacher

, Tan

, et al. Fused deposition modeling of novel scaffold architectures for tissue engineering applications. Biomaterials, 2002; 23:1169–1185.

Kruth

, Wang

, Laoui

, et al. Lasers and materials in selective laser sintering. Assembly Automation, 2003; 23:357–371.

Bártolo

. Stereolithographic processes. In: Stereolithography. Springer US, 2011; pp.1–36.

Khaled

, Burley

, Alexander

, et al. Desktop 3D printing of controlled release pharmaceutical bilayer tablets. Int J Pharm, 2014; 461:105–111.

Kesner

, Howe

. Design principles for rapid prototyping forces sensors using 3-D printing. IEEE ASME Trans Mechatron, 2011; 16:866–870.

Rossiter

, Walters

, Stoimenov

. Proceedings of the 16th International Symposium on Smart Structures and Materials & Nondestructive Evaluation and Health Monitoring. March 9–12, 2009, San Diego, CA. Bellingham, WA: International Society for Optics and Photonics; 72870H-1 to 72870H-10.

Landers

, Pfister

, Hübner

, et al. Fabrication of soft tissue engineering scaffolds by means of rapid prototyping techniques. J Mater Sci, 2002; 37:3107–3116.

10.

Henke

, Treml

. Wood based bulk material in 3D printing processes for applications in construction. Eur J Wood Wood Prod, 2013; 71:139–141.

11.

Klemm

, Heublein

, Fink

, et al. Cellulose: fascinating biopolymer and sustainable raw material. Angew Chem Int Ed Engl, 2005; 44:3358–3393.

12.

Medronho

, Romano

, Miguel

, et al. Rationalizing cellulose (in)solubility: reviewing basic physicochemical aspects and role of hydrophobic interactions. Cellulose, 2012; 19:581–587.

13.

Medronho

, Lindman

. Competing forces during cellulose dissolution: from solvents to mechanisms. Curr Opin Colloid Interface Sci, 2014; 19:32–40.

14.

Swatloski

, Spear

, Holbrey

, et al. Dissolution of cellose with ionic liquids. J Am Chem Soc, 2002; 124:4974–4975.

15.

Cao

, Wu

, Zhang

, et al. Room temperature ionic liquids (RTILs): a new and versatile platform for cellulose processing and derivatization. Chem Eng J, 2009; 147:13–21.

16.

Sundberg

, Toriz

, Gatenholm

. Moisture induced plasticity of amorphous cellulose films from ionic liquid. Polymer, 2013; 54:6555–6560.

17.

Kosan

, Michels

, Meister

. Dissolution and forming of cellulose with ionic liquids. Cellulose, 2008; 15:59–66.

18.

Zhu

. Use of ionic liquids for the efficient utilization of lignocellulosic materials. J Chem Technol Biotechnol, 2008; 83:777–779.

19.

Pacquit

, Frisby

, Diamond

, et al. Development of a smart packaging for the monitoring of fish spoilage. Food Chem, 2007; 102:466–470.

20.

Kim

, Yun

, Ounaies

. Discovery of cellulose as a smart material. Macromolecules, 2006; 39:4202–4206.

21.

Zaborowska

, Bodin

, Bäckdahl

, et al. Microporous bacterial cellulose as a potential scaffold for bone regeneration. Acta Biomater, 2010; 6:2540–2547.

22.

Matsuoka

, Tsuchida

, Matsushita

, et al. A synthetic medium for bacterial cellulose production by Acetobacter xylinum subsp. sucrofermentans. Biosci Biotechnol Biochem, 1996; 60:575–579.

23.

Härdelin

, Thunberg

, Perzon

, et al. Electrospinning of cellulose nanofibers from ionic liquids: the effect of different cosolvents. J Appl Polym Sci, 2012; 125:1901–1909.

24.

Mäki-Arvela

, Anugwom

, Virtanen

, et al. Dissolution of lignocellulosic materials and its constituents using ionic liquids—a review. Ind Crops Prod, 2010; 32:175–201.

25.

Collyer

, Clegg

. Rheological Measurement, 2nd ed. Chapman & Hall, London, 1998.

26.

Goodwin

, Hughes

. Rheology for Chemists: An Introduction. Royal Society of Chemistry, Cambridge, United Kingdom, 2000.

27.

Gericke

, Schlufter

, Liebert

, et al. Rheological properties of cellulose/ionic liquid solutions: from dilute to concentrated states. Biomacromolecules, 2009; 10:1188–1194.

28.

Sescousse

, Le

, Ries

, et al. Viscosity of cellulose–imidazolium-based ionic liquid solutions. J Phys Chem B, 2010; 114:7222–7228.

29.

Kuang

Q-L

, Zhao

J-C

, Niu

Y-H

, et al. Celluloses in an ionic liquid: the rheological properties of the solutions spanning the dilute and semidilute regimes. J Phys Chem B, 2008; 112:10234–10240.

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3D Bioprinting of Cellulose Structures from an Ionic Liquid

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