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Interview mit dem Soziologen Christian Stegbauer: Der Soziologe Prof. Christian Stegbauer beschäftigt sich als Netzwerkforscher auch mit Kommunikation in Social Media. Dass sich Menschen lieber in einer Blase gleichdenkender Akteure aufhalten, anstatt sich mit anderen Meinungen und Denkformen zu beschäftigen, war seiner Ansicht nach der digitalen Kommunikation von Anfang an inhärent. Viele der utopischen Vorstellungen von einer digitalen Partizipationskultur hält er für übertrieben.
As a network researcher, sociologist Professor Christian Stegbauer also deals with communication in social media. That people prefer to stay in a bubble with like-minded others rather than get to grips with different opinions and ways of thinking was in his view inherent to digital communication from the outset. He considers many of the utopian ideas of a digital culture of participation to be exaggerated.
In Bone Tissue Engineering (BTE), autologous bone-regenerative cells are combined with a scaffold for large bone defect treatment (LBDT). Microporous, polylactic acid (PLA) scaffolds showed good healing results in small animals. However, transfer to large animal models is not easily achieved simply by upscaling the design. Increasing diffusion distances have a negative impact on cell survival and nutrition supply, leading to cell death and ultimately implant failure. Here, a novel scaffold architecture was designed to meet all requirements for an advanced bone substitute. Biofunctional, porous subunits in a load-bearing, compression-resistant frame structure characterize this approach. An open, macro- and microporous internal architecture (100 µm–2 mm pores) optimizes conditions for oxygen and nutrient supply to the implant’s inner areas by diffusion. A prototype was 3D-printed applying Fused Filament Fabrication using PLA. After incubation with Saos-2 (Sarcoma osteogenic) cells for 14 days, cell morphology, cell distribution, cell survival (fluorescence microscopy and LDH-based cytotoxicity assay), metabolic activity (MTT test), and osteogenic gene expression were determined. The adherent cells showed colonization properties, proliferation potential, and osteogenic differentiation. The innovative design, with its porous structure, is a promising matrix for cell settlement and proliferation. The modular design allows easy upscaling and offers a solution for LBDT.