Periodic Reporting for period 3 - 3DPartForm (3D-printing of PARTiculate FORMulations utilizing polymer microparticle-based voxels)
Período documentado: 2022-08-01 hasta 2024-01-31
The importance of the project for society lies in its broadness of applicability of the materials that can be developed by 3DPartForm’s unique combination of material basis and processing technology. Microgels have been chosen as building blocks due to their successful usage as platform for biosensing or as cell-like environment for cell-free protein synthesis and enzymatic cascades - all examples that have been explored by the PI’s research group. Building up hierarchical assemblies of such versatile building blocks will provide a path towards material composites or so-called cellular materials that make the jump to length scales that are significant for the important field of human-machine integration, intelligent biomedical systems, and hybrid tissue of artificial and natural entities, for instance. By implementing sensory molecules, nanoparticles and functional microgel building blocks, (bio-)chemical information and signals will be processable in such a complex, cross-scale environment and, in perspective, even provide the means to control system properties based on feedback loops. As a long-term perspective, the combination of cellular materials and sensing will form the basis for rational materials design and the development of biomedical systems that are optimally adapted to their environment and a user’s/patient’s needs.
As a basis in polymer material design, various inter-crosslinking mechanisms have been identified to yield optimal connectivity among multi-particle/multi-microgel assemblies. As a material basis for building block design, both natural and synthetic monomers and macromers have been explored. To further expand the material library, methods for fabricating microgels were developed, which enable processing fast-gelling precursors into homogeneous microgels via emulsion droplet coalescence, and extend the microgels' functionality by incorporation of various additives. For proof-of-concept and easier handling of material building blocks, initial studies were carried out using macroscopic hydrogel-based building blocks before down-scaling towards micron-sized building blocks to improve the local resolution of functionality and thus the degree of system integration. As both types of building block sizes could be successfully inter-crosslinked by hand, the focus has been then on a novel AM platform, allowing for the controlled, hierarchical assembly of the building blocks. Working towards these 2D and eventually 3D assemblies, the scale-up of hydrogel particle suspensions from milliliter- to liter-scale has been studied in depth developing parallelized microfluidics in 3D-printed microflow cells. For maximized signal transmission in hierarchical hydrogel particle assemblies, e.g. for the transmission of light, besides building block properties themselves as well as the inter-crosslinking stability as another factor, the size and interfacial area of the inter-crosslinked particle-particle interface needs to be considered. For this reason, with Stop-flow Lithography (SFL), a process is currently being established that, in contrast to conventional droplet microfluidics, allows for fabricating anisotropic hydrogel microparticles. The results and new insights gathered form a promising basis to successfully implement a new path in polymer material design and processing from which not only materials scientists, but also life science and engineering will greatly benefit.
Generally, the ERC project has been strongly application-driven. Thus, it is the aim to extend the focus of the project to also provide a general understanding and eventually guidelines for discontinuous soft matter design and its assembly (e.g. mechanical cohesion, information flow across building block interfaces, behavior of material assemblies upon local shrinkage, swelling, material ageing).