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Understanding novel EGFP-Ubx protein-based film formation / VALERIA ITALIA

Swansea University Author: VALERIA ITALIA

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DOI (Published version): 10.23889/SUthesis.59805

Abstract

Protein-based materials are currently the subject of intense research interest since they have an extended range of potential applications, such as im-proved bio-membrane biocompatibility for implanted medical devices and the creation of platform materials for novel biosensors. Monomers from Ultrabi...

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Published: Swansea 2022
Institution: Swansea University
Degree level: Doctoral
Degree name: Ph.D
Supervisor: Meissner, Kenith E. ; Bertoncello, Paolo ; Martin, Donald ; Maccarini, Marco
URI: https://cronfa.swan.ac.uk/Record/cronfa59805
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Abstract: Protein-based materials are currently the subject of intense research interest since they have an extended range of potential applications, such as im-proved bio-membrane biocompatibility for implanted medical devices and the creation of platform materials for novel biosensors. Monomers from Ultrabithorax (Ubx) transcription factor are known to spontaneously self-assemble at an air-water interface to form a monolayer, which has then been used as a basis for forming biopolymeric ˝bers. Here we used the Lang-muir trough technique, Brewster angle microscopy (BAM), ellipsometry and neutron re˛ectometry (NR) to investigate the in˛uences of di˙erent exper-imental conditions on EGFP-Ubx monolayer formation and the impact on biopolymeric ˝ber structure. We varied protein concentration, bu˙er prop-erties and waiting times prior to forming biopolymeric ˝bers. Interestingly, we found 3 phases of material formation which brought us to a new protocol for forming ˝bers that reduced protein concentration by 5-fold and wait-ing times by 100-fold. Moreover, an in-house developed MATLAB code was used to analyze SEM images and obtain quantitative structural information about the biopolymeric ˝bers that were correlated directly to the surface ˝lm characteristics measured in the LB trough. These new insights into ˝ber formation and structure enhance the usefulness of the Ubx-based biopolymer for biomedical applications.
Keywords: Protein, neutron reflectometry, Langmuir trough, biopolymer
College: Faculty of Science and Engineering