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Development of a solvent-free polylactide/calcium carbonate composite for selective laser sintering of bone tissue engineering scaffolds

: Gayer, Christoph; Ritter, Jessica; Bullemer, Martin; Grom, Stephanie; Meiners, Wilhelm; Pfister, Andreas; Reinauer, Frank; Vučak, Marijan; Wissenbach, Konrad; Fischer, Horst; Poprawe, Reinhart; Schleifenbaum, Johannes Henrich; Jauer, Lucas

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Materials Science and Engineering, C. Biomimetic and supramolecular systems Biomimetic materials, sensors and systems 101 (2019), S.660-673
ISSN: 0928-4931
ISSN: 1873-0191
Bundesministerium für Bildung und Forschung BMBF (Deutschland)
13N12129; ActiveBone
Zeitschriftenaufsatz, Elektronische Publikation
Fraunhofer ILT ()
polylactic acid; additive manufacturing; laser powder bed fusion; selective laser melting (SLM); biogredable polymer implant

Since large bone defects cannot be healed by the body itself, continuous effort is put into the development of 3D scaffolds for bone tissue engineering. One method to fabricate such scaffolds is selective laser sintering (SLS). However, there is a lack of solvent-free prepared microparticles suitable for SLS. Hence, the aim of this study was to develop a solvent-free polylactide/calcium carbonate composite powder with tailored material properties for SLS. Four composite powders with a composition of approximately 75 wt% polylactide (PLLA as well as PDLLA) and 25 wt% calcium carbonate (calcite) were prepared by a milling process based on GMP standards. Four different grades of polylactide were chosen to cover a broad inherent viscosity range of 1.0–3.6 dl/g. The composite material with the lowest inherent viscosity (1.0 dl/g) showed the best processability by SLS. This was caused by the small polymer particle diameter (50 μm) and the small zero-shear melt viscosity (400 Pa·s), which led to fast sintering. The SLS process parameters were developed to achieve low micro-porosity (approx. 2%) and low polymer degradation (no measurable decrease of the inherent viscosity). A biaxial bending strength of up to 75 MPa was achieved. Cell culture assays indicated good viability of MG-63 osteoblast-like cells on the SLS specimens. Finally, the manufacture of 3D scaffolds with interconnected pore structure was demonstrated. After proving the biocompatibility of the material, the developed scaffolds could have great potential to be used as patient-specific bone replacement implants.