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Biofabrication is an advancing new research field that might, one day, lead to complex products like tissue replacements or tissue analogues for drug testing. Although great progress was made during the last years, there are still major hurdles like new types of materials and advanced processing techniques. The main focus of this thesis was to help overcoming this hurdles by challenging and improving existing fabrication processes like extrusion-based bioprinting but also by developing new techniques. Furthermore, this thesis assisted in designing and processing materials from novel building blocks like recombinant spider silk proteins or inks loaded with charged nanoparticles.
A novel 3D printing technique called Melt Electrospinning Writing (MEW) was used in Chapter 3 to create tubular constructs from thin polymer fibers (roughly 12 μm in diameter) by collecting the fibers onto rotating and translating cylinders. The main focus was put on the influence of the collector diameter and its rotation and translation on the morphology of the constructs generated by this approach. In a first step, the collector was not moving and the pattern generated by these settings was analyzed. It could be shown that the diameter of the stationary collectors had a big impact on the morphology of the constructs. The bigger the diameter of the mandrel (smallest collector diameters 0.5 mm, biggest 4.8 mm) got, the more the shape of the generated footprint converged into a circular one known from flat collectors. In a second set of experiments the mandrels were only rotated. Increasing the rotational velocity from 4.2 to 42.0 rpm transformed the morphology of the constructs from a figure-of-eight pattern to a sinusoidal and ultimately to a straight fiber morphology. It was possible to prove that the transformation of the pattern was comparable to what was known from increasing the speed using flat collectors and that at a critical speed, the so called critical translation speed, straight fibers would appear that were precisely stacking on top of each other. By combining rotation and translation of the mandrel, it was possible to print tubular constructs with defined winding angles. Using collections speeds close to the critical translation speed enabled higher control of fiber positioning and it was possible to generate precisely stacked constructs with winding angles between 5 and 60°.
In Chapter 4 a different approach was followed. It was based on extrusion-based bioprinting in combination with a hydrogel ink system. The ink was loaded with nanoparticles and the nanoparticle release was analyzed. In other words, two systems, a printable polyglycidol/hyaluronic acid ink and mesoporous silica nanoparticles (MSN), were combined to analyze charge driven release mechanism that could be fine-tuned using bioprinting. Thorough rheological evaluations proved that the charged nanoparticles, both negatively charged MSN-COOH and positively charged MSN-NH2, did not alter the shear thinning properties of the ink that revealed a negative base charge due to hyaluronic acid as one of its main components. Furthermore, it could be shown that the particles did also not have a negative effect on the recovery properties of the material after exposure to high shear. During printing, the observations made via rheological testing were supported by the fact that all materials could be printed at the same settings of the bioprinter. Using theses inks, it was possible to make constructs as big as 12x12x3 mm3 composed of 16 layers. The fiber diameters produced were about 627±31 μm and two-component constructs could be realized utilizing the two hydrogel print heads of the printer to fabricate one hybrid construct. The particle distribution within those constructs was homogeneous, both from a microscopic and a macroscopic point of view. Particle release from printed constructs was tracked over 6 weeks and revealed that the print geometry had an influence on the particle release. Printed in a geometry with direct contact between the strands containing different MSN, the positively charged particles quickly migrated into the strand previously containing only negatively charged MSN-COOH. The MSN-COOH seemed to be rather released into the surrounding liquid and also after 6 weeks no MSN-COOH signal could be detected in the strand previously only containing MSN-NH2. In case of a geometry without direct contact between the strands, the migration of the positively charged nanoparticles into the MSN-COOH containing strand was strongly delayed. This proved that the architecture of the printed construct can be used to fine-tune the particle release from nanoparticle containing printable hydrogel ink systems.
Chapter 5 discusses an approach using hydrogel inks based on recombinant spider silk proteins processed via extrusion-based bioprinting. The ink could be applied for printing at protein concentrations of 3 % w/v without the addition of thickeners or any post process crosslinking. Both, the recombinant protein eADF4(C16) and a modification introducing a RGD-sequence to the protein (eADF4(C16)-RGD), could be printed revealing a very good print fidelity. The RGD modification had positive effect on the adhesion of cells seeded onto printed constructs. Furthermore, human fibroblasts encapsulated in the ink at concentrations of 1.2 million cells per mL did not alter the print fidelity and did not interfere with the crosslinking mechanism of the ink. This enabled printing cell laden constructs with a cell survival rate of 70.1±7.6 %. Although the cell survival rate needs to be improved in further trials, the approach shown is one of the first leading towards the shift of the window of biofabrication because it is based on a new material that does not need potentially harmful post-process crosslinking and allows the direct encapsulation of cells staying viable throughout the print process.
In this thesis, non-modified POx, namely PnPrOx and PcycloPrOx, with an LCST in the physiological range between 20 and 37°C have been utilized as materials for three different biofabrication approaches. Their thermoresponsive behavior and processability were exploited to establish an easy-to-apply coating for cell sheet engineering, a novel method to create biomimetic scaffolds based on aligned fibrils via Melt Electrowriting (MEW) and the application of melt electrowritten sacrificial scaffolds for microchannel creation for hydrogels.
Chapter 3 describes the establishment of a thermoresponsive coating for tissue culture plates. Here, PnPrOx was simply dissolved in water and dried in well plates and petri dishes in an oven. PnPrOx adsorbed to the surface, and the addition of warm media generated a cell culture compatible coating. It was shown that different cell types were able to attach and proliferate. After confluency, temperature reduction led to the detachment of cell sheets. Compared to standard procedures for surface coating, the thermoresponsive polymer is not bound covalently to the surface and therefore does not require specialized equipment and chemical knowledge. However, it should be noted that the detachment of the cell layer requires the dissolution of the PnPrOx-coating, leading to possible polymer contamination. Although it is only a small amount of polymer dissolved in the media, the detached cell sheets need to be washed by media exchange for further processing if required. ...
Biofabrication technologies must address numerous parameters and conditions to reconstruct tissue complexity in vitro. A critical challenge is vascularization, especially for large constructs exceeding diffusion limits. This requires the creation of artificial vascular structures, a task demanding the convergence and integration of multiple engineering approaches. This doctoral dissertation aims to achieve two primary objectives: firstly, to implement and refine engineering methods for creating artificial microvascular structures using Melt Electrowriting (MEW)-assisted sacrificial templating, and secondly, to deepen the understanding of the critical factors influencing the printability of bioink formulations in 3D extrusion bioprinting.
In the first part of this dissertation, two innovative sacrificial templating techniques using MEW are explored. Utilizing a carbohydrate glass as a fugitive material, a pioneering advancement in the processing of sugars with MEW with a resolution under 100 microns was made. Furthermore, by introducing the “print-and-fuse” strategy as a groundbreaking method, biomimetic branching microchannels embedded in hydrogel matrices were fabricated, which can then be endothelialized to mirror in vivo vascular conditions.
The second part of the dissertation explores extrusion bioprinting. By introducing a simple binary bioink formulation, the correlation between physical properties and printability was showcased. In the next step, employing state-of-the-art machine-learning approaches revealed a deeper understanding of the correlations between bioink properties and printability in an extended library of hydrogel formulations.
This dissertation offers in-depth insights into two key biofabrication technologies. Future work could merge these into hybrid methods for the fabrication of vascularized constructs, combining MEW's precision with fine-tuned bioink properties in automated extrusion bioprinting.