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Short Talk
ST 54

Wet spinning of silk fibroin fibers and fiber-based additive manufacturing of 3D scaffolds for regenerative medicin

Appointment

Date: 15/09/2023

Time: 11:45 – 12:00

Talk time: 10 Min.

Discussion time: 5 Min.

Location / Stream:

Lecture hall 7

Session

Biofabrication / Scaffolds

Topics

Additive manufacturing (e. g. 3D printing)
Tissue regeneration/regenerated medicine

Authors

Dr. Michael Wöltje (Dresden, DE), Kristin Isenberg (Dresden, DE), Patrik Neubauer (Dresden, DE), Dr. Dilbar Aibibu (Dresden, DE), Prof. Dr. Chokri Cherif (Dresden, DE)

Abstract

Abstract text (incl. figure legends and references)

Introduction

Silk ﬁbroin combines properties such as high mechanical strength, biocompatibility, and biodegradability in vivo. The possibility of using ﬁbroin in a wide variety of formats (ﬁlms, scaffolds, hydrogels, and micro- or nanoparticles for drug delivery), has led to many interesting applications in medical research. In addition, extensive effort has been focused on producing man-made silk fibers by wet spinning. However, due to degradation of fibroin molecules during isolation from cocoons only high percentage solutions of regenerated silk (13-32 % w/v) show sufficient viscosity needed for fiber spinning.

Objectives

The main objective was to develop a novel wet spinning process to generate silk fibers and to process those fibers into 3D open porous scaffolds applying textile fiber-based additive manufacturing.

Materials & methods

Regenerated silk solution was isolated from Bombyx mori cocoons applying mild degumming and dissolution in ZnCl2. The resulting solution was freeze-dried and re-dissolved for wet spinning. Wet spun silk fibers were processed into staple fibers and then assembled into open porous 3D scaffolds applying fiber-based additive manufacturing.

Results

In contrast to all previously published spinning processes, a solvent/coagulation bath combination was developed, which enables continuously spinning of endless fibers from only 4 % (w/v) silk solution. Compared to other approaches the solid content to tensile strength ratio achieved was twice that of the highest process to date. Applying fiber-based additive manufacturing, those wet spun silk fibroin fibers were processed into 3D open porous scaffolds.

Conclusion

A novel process was developed enabling wet spinning of fibers from only 4 % (w/v) fibroin solution, which could be processed into 3D scaffolds with a fiber-based additive manufacturing technology.

Acknowledgements

This research was funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation)-437213841.