Development of a Novel Flow Channel Apparatus and its Use in Testing the Adhesion Strength of Two Common New Zealand Algae

Adhesives produced by marine organisms are fascinating in that they often possess an ability to adsorb rapidly and robustly to a range of substrates, in a range of environmental conditions and in the presence of significant surface contamination. On top of this, they undergo curing while in contact...

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Bibliographic Details
Main Author: Mather, Anton Victor
Language:English
Published: University of Canterbury. School of Biological Sciences 2015
Subjects:
bioadhesion
algae
seaweed
glue
biofouling
New Zealand
Antarc*
Antarctica
Online Access:http://hdl.handle.net/10092/11360
https://doi.org/10.26021/7724
id ftunivcanter:oai:ir.canterbury.ac.nz:10092/11360
record_format openpolar
spelling ftunivcanter:oai:ir.canterbury.ac.nz:10092/11360 2023-05-15T13:49:26+02:00 Development of a Novel Flow Channel Apparatus and its Use in Testing the Adhesion Strength of Two Common New Zealand Algae Mather, Anton Victor 2015 application/pdf http://hdl.handle.net/10092/11360 https://doi.org/10.26021/7724 en eng University of Canterbury. School of Biological Sciences NZCU http://hdl.handle.net/10092/11360 http://dx.doi.org/10.26021/7724 Copyright Anton Victor Mather https://canterbury.libguides.com/rights/theses bioadhesion algae seaweed glue biofouling 2015 ftunivcanter https://doi.org/10.26021/7724 2022-09-08T13:36:50Z Adhesives produced by marine organisms are fascinating in that they often possess an ability to adsorb rapidly and robustly to a range of substrates, in a range of environmental conditions and in the presence of significant surface contamination. On top of this, they undergo curing while in contact with water. Many of the properties that make marine bioadhesives so effective remain elusive to engineers designing synthetic adhesives. An increased understanding of marine bioadhesives would allow for the design of effective, biologically-inspired adhesives with applications in the engineering, maritime and health sectors. Conversely, better understanding of the adhesives produced by fouling organisms could help with the design of new fouling-resistant surfaces. One essential element for characterising a bioadhesive is to assess its adhesion strength to the substrate. In this thesis, I present a novel flow channel apparatus for testing the adhesion strength of marine organisms to help characterise their associated adhesives. The flow channel was used with Hormosira banksii and Durvillaea antarctica, two marine macroalgae endemic to New Zealand, and assessments of adhesion strength are made with substrates of varied chemistry and topography. H. banksii zygotes were found to exhibit a settlement-time dependent increase in adhesion strength across all of the biomedical substrates, which included poly(methyl methacrylate) (PMMA) and three hydrogels, two of which were gelatin-based approximations of human skin. H. banksii did not exhibit any substrate-dependent variation in adhesive strength, suggesting an adhesive that is able to interact with a range of substrate types. D. antarctica exhibited more rapid adhesion to glass, PMMA, PTFE and stainless steel than did H. banksii, forming a particularly strong bond with stainless steel. On substrates with simple, defined topographies, H. banksii zygotes were found to adhere most effectively to a surface with a feature size slightly larger than the size of the zygote. A ... Other/Unknown Material Antarc* Antarctica University of Canterbury, Christchurch: UC Research Repository New Zealand
institution Open Polar
collection University of Canterbury, Christchurch: UC Research Repository
op_collection_id ftunivcanter
language English
topic bioadhesion
algae
seaweed
glue
biofouling
spellingShingle bioadhesion
algae
seaweed
glue
biofouling
Mather, Anton Victor
Development of a Novel Flow Channel Apparatus and its Use in Testing the Adhesion Strength of Two Common New Zealand Algae
topic_facet bioadhesion
algae
seaweed
glue
biofouling
description Adhesives produced by marine organisms are fascinating in that they often possess an ability to adsorb rapidly and robustly to a range of substrates, in a range of environmental conditions and in the presence of significant surface contamination. On top of this, they undergo curing while in contact with water. Many of the properties that make marine bioadhesives so effective remain elusive to engineers designing synthetic adhesives. An increased understanding of marine bioadhesives would allow for the design of effective, biologically-inspired adhesives with applications in the engineering, maritime and health sectors. Conversely, better understanding of the adhesives produced by fouling organisms could help with the design of new fouling-resistant surfaces. One essential element for characterising a bioadhesive is to assess its adhesion strength to the substrate. In this thesis, I present a novel flow channel apparatus for testing the adhesion strength of marine organisms to help characterise their associated adhesives. The flow channel was used with Hormosira banksii and Durvillaea antarctica, two marine macroalgae endemic to New Zealand, and assessments of adhesion strength are made with substrates of varied chemistry and topography. H. banksii zygotes were found to exhibit a settlement-time dependent increase in adhesion strength across all of the biomedical substrates, which included poly(methyl methacrylate) (PMMA) and three hydrogels, two of which were gelatin-based approximations of human skin. H. banksii did not exhibit any substrate-dependent variation in adhesive strength, suggesting an adhesive that is able to interact with a range of substrate types. D. antarctica exhibited more rapid adhesion to glass, PMMA, PTFE and stainless steel than did H. banksii, forming a particularly strong bond with stainless steel. On substrates with simple, defined topographies, H. banksii zygotes were found to adhere most effectively to a surface with a feature size slightly larger than the size of the zygote. A ...
author Mather, Anton Victor
author_facet Mather, Anton Victor
author_sort Mather, Anton Victor
title Development of a Novel Flow Channel Apparatus and its Use in Testing the Adhesion Strength of Two Common New Zealand Algae
title_short Development of a Novel Flow Channel Apparatus and its Use in Testing the Adhesion Strength of Two Common New Zealand Algae
title_full Development of a Novel Flow Channel Apparatus and its Use in Testing the Adhesion Strength of Two Common New Zealand Algae
title_fullStr Development of a Novel Flow Channel Apparatus and its Use in Testing the Adhesion Strength of Two Common New Zealand Algae
title_full_unstemmed Development of a Novel Flow Channel Apparatus and its Use in Testing the Adhesion Strength of Two Common New Zealand Algae
title_sort development of a novel flow channel apparatus and its use in testing the adhesion strength of two common new zealand algae
publisher University of Canterbury. School of Biological Sciences
publishDate 2015
url http://hdl.handle.net/10092/11360
https://doi.org/10.26021/7724
geographic New Zealand
geographic_facet New Zealand
genre Antarc*
Antarctica
genre_facet Antarc*
Antarctica
op_relation NZCU
http://hdl.handle.net/10092/11360
http://dx.doi.org/10.26021/7724
op_rights Copyright Anton Victor Mather
https://canterbury.libguides.com/rights/theses
op_doi https://doi.org/10.26021/7724
_version_ 1766251357802594304

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