Your search keyword '"Stephan Haudum"' showing total 4 results

1. 3D Inkjet Printing of Biomaterials with Solvent‐Free, Thiol‐Yne‐Based Photocurable Inks

Author

Michael Kainz, Stephan Haudum, Elena Guillén, Oliver Brüggemann, Rita Höller, Heike Frommwald, Tilo Dehne, Michael Sittinger, Disha Tupe, Zoltan Major, Gerald Stubauer, Thomas Griesser, and Ian Teasdale

Subjects

3D inkjet printing, degradable polymers, phosphoramidates, tissue engineering scaffolds, Materials of engineering and construction. Mechanics of materials, TA401-492, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Abstract 3D inkjet printing is a fast, reliable, and non‐contact bottom–up approach to printing small and large models and is one of the fastest additive manufacturing technologies available. These attributes position inkjet printing as a promising tool for the additive manufacturing of biomaterials, for example, tissue engineering scaffolds. However, due to the stringent technical rheological requirements of current inkjet technologies, there is a lack of photopolymer resins suitable for the inkjet printing of biomaterials. Hence, a novel ink engineered for 3D piezoelectric inkjet printing of biomaterials is designed and developed. The novel resin leverages a biodegradable amino acid phosphorodiamidate matrix copolymerized with a dialkyne ether to modulate the viscosity. Copolymerization with commercially available thiols facilitates the photochemical thiol‐yne curing reaction. The ink exhibits optimal viscosity, eliminating the need for solvents, as well as reliable jetting and sufficiently swift curing kinetics. Furthermore, the formulation is successfully demonstrated in an industrial inkjet printhead. Notably, the resulting materials have low cytotoxicity and, hence, have significant promise in advancing the applications of 3D inkjet printing of biological scaffolds.

Published

2024

2. Amino acid-based polyphosphorodiamidates with hydrolytically labile bonds for degradation-tuned photopolymers

Author

Stephan Haudum, Stefan Lenhart, Stefanie M. Müller, Disha Tupe, Christoph Naderer, Tilo Dehne, Michael Sittinger, Zoltan Major, Thomas Griesser, Oliver Brüggemann, Jaroslaw Jacak, and Ian Teasdale

Subjects

Inorganic Chemistry, Polymers and Plastics, Organic Chemistry, Materials Chemistry

Abstract

Photochemical additive manufacturing technologies can produce complex geometries in short production times and thus have considerable potential as a tool to fabricate medical devices such as individualised patient-specific implants, prosthetics and tissue engineering scaffolds. However, most photopolymer resins degrade only slowly under the mild conditions required for many biomedical applications. Herein we report novel amino acid-based polyphosphorodiamidate (APdA) monomers with hydrolytically cleavable bonds. The substituent on the α-amino acid can be used as a handle for facile control of hydrolysis rates of the monomers into their endogenous components, namely phosphate and the corresponding amino acid. Furthermore, monomer hydrolysis is considerably accelerated at lower pH values. The monomers underwent thiol-yne photopolymerization and could be 3D structured via multi-photon lithography. Copolymerization with commonly used hydrophobic thiols demonstrates not only their ability to regulate the ambient degradation rate of thiol-yne polyester photopolymer resins but also rare but highly desirable surface erosion behaviour. Such degradation profiles, in the appropriate timeframes in suitably mild conditions, combined with their good cytocompatibility and 3D printability, render these novel photomonomers of significant interest for a wide range of biomaterial applications.

Published

2023

3. <scp>Post‐polymerization</scp> modification of aromatic polyimides via Diels‐Alder cycloaddition

Author

Oliver Brüggemann, Ian Teasdale, Markus Himmelsbach, George S. Pappas, Stephan Haudum, Matthias Bechmann, Doris Cristurean, and Stephan Schaumüller

Subjects

Materials science, Polymers and Plastics, Materials Chemistry, Diels alder, Organic chemistry, Physical and Theoretical Chemistry, Post polymerization, Cycloaddition

Published

2021

4. Diels–Alder cycloaddition polymerization of highly aromatic polyimides and their multiblock copolymers

Author

Ian Teasdale, Paul Strasser, Stephan Haudum, Oliver Brüggemann, Doris Cristurean, Matthias Bechmann, Markus Himmelsbach, and Stephan Schaumüller

Subjects

chemistry.chemical_classification, Materials science, Nanostructure, Polymers and Plastics, Organic Chemistry, Multiblock copolymer, Bioengineering, Polymer, Biochemistry, Combinatorial chemistry, Cycloaddition, Polymerization, chemistry, Phenylene, Copolymer, Dynamic equilibrium

Abstract

The ability to prepare block, multiblock and segmented polymers is an essential and established tool in polymer chemistry to tailor the properties of materials and steer the formation of complex nanostructures. The preparation of segmented or block copolymers with pre-defined block lengths is, however, inherently difficult for polyimides, one of the most important and versatile high-performance polymers. The most accessible route to polyimides, a step-growth polyamic acid formation between diamines and dianhydrides, is in dynamic equilibrium, which leads to chain scrambling of attempted block copolymers. We provide herein a solution to this by utilizing a Diels–Alder reaction on phenylethynyl end-functionalized oligomers containing pre-formed, ring-closed imides. The reaction of the alkynes with a bistetraphenylcyclopentadienone chain extender undergoes a chelotropic evolution of CO gas at high temperatures forming phenylene segments and polymerizing the chains in the process. Furthermore, we could use this reaction for the chain extension of different phenylethynyl functionalized telechelic oligoimides and thus produce random multiblock copolymers. Importantly the reaction is also demonstrated to enable chain extension reactions with insoluble oligoimides, considerably expanding the scope of potential as many important polyimides are either insoluble, or poorly soluble, in common organic solvents. This Diels–Alder polymerization is thus demonstrated to be a highly versatile route to prepare novel polyimides with wide-ranging possibilities and considerable potential to prepare advanced materials ranging from electronic applications to high-performance materials.

Published

2021