Your search keyword '"Dundas, Adam A."' showing total 19 results

1. Microwave synthesis of novel methacrylate monomers designed to reduce biofilm formation to surfaces

Author

Dundas, Adam Alastair

Subjects

QR100 Microbial ecology, R855 Medical technology. Biomedical engineering. Electronics

Abstract

Rational design of biomaterials is hindered by the lack of quantitative structure-activity relationships (QSAR). Here we report the use of a QSAR to guide experimentation into a new chemical space; we predict and synthesize molecular structures for novel monomers that will reduce biofilm formation, and so identifying the lowest biofilm attachment polymer discovered to date. Cyclododecyl methacrylate was shown to reduce the formation of P. aeruginosa and P. mirabilis biofilms by up to 96 % and 97 % respectively compared to commercially available catheters. We believe that this is the first instance of a biomaterials screening program extending beyond the domain covered by the initial screen to predict a novel chemical entity with improved properties. This validates the QSAR approach for identifying polymers that resist biofilm formation beyond its chemical training domain. High throughput discovery of the non-commercially available material space is hindered by the ability to synthesize large numbers of materials in a controlled reaction process to keep up with supply demands. In this thesis we also present the production of a microwave single-well reactor capable of synthesizing novel methacrylate monomers using a transesterification process, where the design of the reactor has shown to outperform both conventional and standard microwave heating techniques. Powers as low as 40 W have been used to achieve reaction temperatures of 160 ˚C, showing great scale-out potential. With the approach of using QSAR for identifying potential biomaterials, monomer libraries can be judiciously chosen and then synthesised to enable high throughput discovery programs to have unprecedented access to the non-commercially available space.

Published

2018

2. Microparticles Decorated with Cell‐Instructive Surface Chemistries Actively Promote Wound Healing.

Author

Latif, Arsalan, Fisher, Leanne E., Dundas, Adam A., Cuzzucoli Crucitti, Valentina, Imir, Zeynep, Lawler, Karen, Pappalardo, Francesco, Muir, Benjamin W, Wildman, Ricky, Irvine, Derek J., Alexander, Morgan R, and Ghaemmaghami, Amir M.

Published

2024

3. Screening of Oligomeric (Meth)acrylate Vaccine Adjuvants Synthesized via Catalytic Chain Transfer Polymerization

Author

Hege, Cordula S., primary, Stimpson, Amy, additional, Sefton, Joseph, additional, Summers, James, additional, Henke, Helena, additional, Dundas, Adam A., additional, Phan, Tony, additional, Kinsey, Robert, additional, Guderian, Jeffrey A., additional, Sivananthan, Sandra J., additional, Mohamath, Raodoh, additional, Lykins, William R., additional, Ramer-Denisoff, Gabi, additional, Lin, Susan, additional, Fox, Christopher B., additional, and Irvine, Derek J., additional

Published

2023

4. Ring opening polymerisation of ɛ-caprolactone with novel microwave magnetic heating and cyto-compatible catalyst

Author

Wang, Kaiyang, primary, Ni, Ming, additional, Dundas, Adam A., additional, Dimitrakis, Georgios, additional, and Irvine, Derek J., additional

Published

2023

5. Discovery of a polymer resistant to bacterial biofilm, swarming, and encrustation

Author

Dubern, Jean-Frédéric, primary, Hook, Andrew L., additional, Carabelli, Alessandro M., additional, Chang, Chien-Yi, additional, Lewis-Lloyd, Christopher A., additional, Luckett, Jeni C., additional, Burroughs, Laurence, additional, Dundas, Adam A., additional, Humes, David J., additional, Irvine, Derek J., additional, Alexander, Morgan R., additional, and Williams, Paul, additional

Published

2023

6. Predictive Molecular Design and Structure–Property Validation of Novel Terpene-Based, Sustainably Sourced Bacterial Biofilm-Resistant Materials

Author

Cuzzucoli Crucitti, Valentina, primary, Ilchev, Aleksandar, additional, Moore, Jonathan C., additional, Fowler, Harriet R., additional, Dubern, Jean-Frédéric, additional, Sanni, Olutoba, additional, Xue, Xuan, additional, Husband, Bethany K., additional, Dundas, Adam A., additional, Smith, Sean, additional, Wildman, Joni L., additional, Taresco, Vincenzo, additional, Williams, Paul, additional, Alexander, Morgan R., additional, Howdle, Steven M., additional, Wildman, Ricky D., additional, Stockman, Robert A., additional, and Irvine, Derek J., additional

Published

2023

7. Microparticles Decorated with Cell‐Instructive Surface Chemistries Actively Promote Wound Healing

Author

Latif, Arsalan, primary, Fisher, Leanne E., additional, Dundas, Adam A., additional, Cuzzucoli Crucitti, Valentina, additional, Imir, Zeynep, additional, Lawler, Karen, additional, Pappalardo, Francesco, additional, Muir, Benjamin W, additional, Wildman, Ricky, additional, Irvine, Derek J., additional, Alexander, Morgan R, additional, and Ghaemmaghami, Amir M., additional

Published

2022

8. A new particle mounting method for surface analysis

Author

Dundas, Adam A., primary, Kern, Stefanie, additional, Cuzzucoli Crucitti, Valentina, additional, Scurr, David J., additional, Wildman, Ricky, additional, Irvine, Derek J., additional, and Alexander, Morgan R., additional

Published

2021

9. Generation and Characterization of a Library of Novel Biologically Active Functional Surfactants (Surfmers) Using Combined High-Throughput Methods

Author

Cuzzucoli Crucitti, Valentina, primary, Contreas, Leonardo, additional, Taresco, Vincenzo, additional, Howard, Shaun C., additional, Dundas, Adam A., additional, Limo, Marion J., additional, Nisisako, Takasi, additional, Williams, Philip M., additional, Williams, Paul, additional, Alexander, Morgan R., additional, Wildman, Ricky D., additional, Muir, Benjamin W., additional, and Irvine, Derek J., additional

Published

2021

10. Droplet Microfluidic Optimisation Using Micropipette Characterisation of Bio-Instructive Polymeric Surfactants

Author

Henshaw, Charlotte A., primary, Dundas, Adam A., additional, Cuzzucoli Crucitti, Valentina, additional, Alexander, Morgan R., additional, Wildman, Ricky, additional, Rose, Felicity R. A. J., additional, Irvine, Derek J., additional, and Williams, Philip M., additional

Published

2021

11. Achieving Microparticles with Cell‐Instructive Surface Chemistry by Using Tunable Co‐Polymer Surfactants

Author

Dundas, Adam A., primary, Cuzzucoli Crucitti, Valentina, additional, Haas, Simon, additional, Dubern, Jean‐Frédéric, additional, Latif, Arsalan, additional, Romero, Manuel, additional, Sanni, Olutoba, additional, Ghaemmaghami, Amir M., additional, Williams, Paul, additional, Alexander, Morgan R., additional, Wildman, Ricky, additional, and Irvine, Derek J., additional

Published

2020

12. A new particle mounting method for surface analysis.

Author

Dundas, Adam A., Kern, Stefanie, Cuzzucoli Crucitti, Valentina, Scurr, David J., Wildman, Ricky, Irvine, Derek J., and Alexander, Morgan R.

Subjects

*SURFACE analysis, *SECONDARY ion mass spectrometry, *SURFACE chemistry, *MASKING (Chemistry), *ANALYTICAL chemistry, *X-ray photoelectron spectroscopy, *PARTICLE analysis

Abstract

The chemical analysis of microparticles is challenging due to the need to mount the particles on a substrate for analysis; double‐sided adhesive tape is often used (sometimes conductive), however that is usually coated with poly (dimethyl siloxane) (PDMS) that is often used as a release agent. PDMS is a common surface contamination that can mask surface chemistries and hinder material performance where it is dependent on this contaminated interface. It is known that PDMS contains a very mobile oligomeric fraction that readily diffuses across surfaces resulting in the contamination of mounted particulate samples before and during surface chemistry analysis. This makes it impossible to determine whether the PDMS has arisen from the analysis procedure or from the sample itself. A new sample preparation method is proposed where polymer microparticles are mounted on a poly (hydroxyethyl methacrylate) (pHEMA) polymer solution, which we compare with particles that have been mounted on adhesive discs using time‐of‐flight secondary ion mass spectrometry (ToF‐SIMS) and 3D OrbiSIMS analysis. Particles mounted on the pHEMA substrate results in a reduction of PDMS signal by 99.8% compared with microparticles mounted on adhesive discs. This illustrates how a simple, quick and inexpensive polymer solution can be used to adhere particles for analysis by ToF‐SIMS, or other surface chemical analysis techniques such as X‐ray photoelectron spectroscopy (XPS), without introduction of large amounts of silicone contaminant. [ABSTRACT FROM AUTHOR]

Published

2022

13. Prediction of Broad-Spectrum Pathogen Attachment to Coating Materials for Biomedical Devices

Author

Mikulskis, Paulius, Hook, Andrew, Dundas, Adam, Irvine, Derek, Sanni, Olutoba, Anderson, Daniel, Langer, Robert, Alexander, Morgan R., Williams, Paul, Winkler, David A., and Dundas, Adam A.

Subjects

machine learning, antimicrobial surfaces, broad spectrum, polymer arrays, medical devices

Abstract

© 2017 American Chemical Society. Bacterial infections in healthcare settings are a frequent accompaniment to both routine procedures such as catheterization and surgical site interventions. Their impact is becoming even more marked as the numbers of medical devices that are used to manage chronic health conditions and improve quality of life increases. The resistance of pathogens to multiple antibiotics is also increasing, adding an additional layer of complexity to the problems of employing safe and effective medical procedures. One approach to reducing the rate of infections associated with implanted and indwelling medical devices is the use of polymers that resist the formation of bacterial biofilms. To significantly accelerate the discovery of such materials, we show how state of the art machine learning methods can generate quantitative predictions for the attachment of multiple pathogens to a large library of polymers in a single model for the first time. Such models facilitate design of polymers with very low pathogen attachment across different bacterial species that will be candidate materials for implantable or indwelling medical devices such as urinary catheters, cochlear implants, and pacemakers.

Published

2018

14. Validating a Predictive Structure–Property Relationship by Discovery of Novel Polymers which Reduce Bacterial Biofilm Formation

Author

Dundas, Adam A., primary, Sanni, Olutoba, additional, Dubern, Jean‐Frédéric, additional, Dimitrakis, Georgios, additional, Hook, Andrew L., additional, Irvine, Derek J., additional, Williams, Paul, additional, and Alexander, Morgan R., additional

Published

2019

15. Methodology for the synthesis of methacrylate monomers using designed single mode microwave applicators

Author

Dundas, Adam A., primary, Hook, Andrew L., additional, Alexander, Morgan R., additional, Kingman, Samuel W., additional, Dimitrakis, Georgios, additional, and Irvine, Derek J., additional

Published

2019

16. Fungal Attachment-Resistant Polymers for the Additive Manufacture of Medical Devices

Author

Yong, Ling Xin, Sefton, Joseph, Vallières, Cindy, Rance, Graham A., Hill, Jordan, Cuzzucoli Crucitti, Valentina, Dundas, Adam A., Rose, Felicity R. A. J., Alexander, Morgan R., Wildman, Ricky, He, Yinfeng, Avery, Simon V., and Irvine, Derek J.

Abstract

This study reports the development of the first copolymer material that (i) is resistant to fungal attachment and hence biofilm formation, (ii) operates via a nonkilling mechanism, i.e., avoids the use of antifungal actives and the emergence of fungal resistance, (iii) exhibits sufficient elasticity for use in flexible medical devices, and (iv) is suitable for 3D printing (3DP), enabling the production of safer, personalized medical devices. Candida albicans(C. albicans) can form biofilms on in-dwelling medical devices, leading to potentially fatal fungal infections in the human host. Poly(dimethylsiloxane) (PDMS) is a common material used for the manufacture of medical devices, such as voice prostheses, but it is prone to microbial attachment. Therefore, to deliver a fungal-resistant polymer with key physical properties similar to PDMS (e.g., flexibility), eight homopolymers and 30 subsequent copolymers with varying glass transition temperatures (Tg) and fungal antiattachment properties were synthesized and their materials/processing properties studied. Of the copolymers produced, triethylene glycol methyl ether methacrylate (TEGMA) copolymerized with (r)-α-acryloyloxy-β,β-dimethyl-γ-butyrolactone (AODMBA) at a 40:60 copolymer ratio was found to be the most promising candidate by meeting all of the above criteria. This included demonstrating the capability to successfully undergo 3DP by material jetting, via the printing of a voice prosthesis valve-flap using the selected copolymer.

Published

2024

17. Prediction of broad-spectrum pathogen attachment to coating materials for biomedical devices

Author

Mikulskis, Paulius, Hook, Andrew, Dundas, Adam, Irvine, Derek J., Sanni, Olutoba, Anderson, Daniel, Langer, Robert, Alexander, Morgan R., Williams, Paul, Winkler, David A., Mikulskis, Paulius, Hook, Andrew, Dundas, Adam, Irvine, Derek J., Sanni, Olutoba, Anderson, Daniel, Langer, Robert, Alexander, Morgan R., Williams, Paul, and Winkler, David A.

Abstract

Bacterial infections in healthcare settings are a frequent accompaniment to both routine procedures such as catheterization and surgical site interventions. Their impact is becoming even more marked as the numbers of medical devices that are used to manage chronic health conditions and improve quality of life increases. The resistance of pathogens to multiple antibiotics is also increasing, adding an additional layer of complexity to the problems of employing safe and effective medical procedures. One approach to reducing the rate of infections associated with implanted and indwelling medical devices is the use of polymers that resist the formation of bacterial biofilms. To significantly accelerate the discovery of such materials, we show how state of the art machine learning methods can generate quantitative predictions for the attachment of multiple pathogens to a large library of polymers in a single model for the first time. Such models facilitate design of polymers with very low pathogen attachment across different bacterial species that will be candidate materials for implantable or indwelling medical devices such as urinary catheters, cochlear implants and pacemakers.

18. Microwave synthesis of novel methacrylate monomers designed to reduce biofilm formation to surfaces

Author

Dundas, Adam Alastair and Dundas, Adam Alastair

Abstract

Rational design of biomaterials is hindered by the lack of quantitative structure-activity relationships (QSAR). Here we report the use of a QSAR to guide experimentation into a new chemical space; we predict and synthesize molecular structures for novel monomers that will reduce biofilm formation, and so identifying the lowest biofilm attachment polymer discovered to date. Cyclododecyl methacrylate was shown to reduce the formation of P. aeruginosa and P. mirabilis biofilms by up to 96 % and 97 % respectively compared to commercially available catheters. We believe that this is the first instance of a biomaterials screening program extending beyond the domain covered by the initial screen to predict a novel chemical entity with improved properties. This validates the QSAR approach for identifying polymers that resist biofilm formation beyond its chemical training domain. High throughput discovery of the non-commercially available material space is hindered by the ability to synthesize large numbers of materials in a controlled reaction process to keep up with supply demands. In this thesis we also present the production of a microwave single-well reactor capable of synthesizing novel methacrylate monomers using a transesterification process, where the design of the reactor has shown to outperform both conventional and standard microwave heating techniques. Powers as low as 40 W have been used to achieve reaction temperatures of 160 ˚C, showing great scale-out potential. With the approach of using QSAR for identifying potential biomaterials, monomer libraries can be judiciously chosen and then synthesised to enable high throughput discovery programs to have unprecedented access to the non-commercially available space.

19. Prediction of Broad-Spectrum Pathogen Attachment to Coating Materials for Biomedical Devices.

Author

Mikulskis P, Hook A, Dundas AA, Irvine D, Sanni O, Anderson D, Langer R, Alexander MR, Williams P, and Winkler DA

Subjects

Anti-Bacterial Agents, Biofilms, Coated Materials, Biocompatible, Polymers, Quality of Life, Biomedical Research

Abstract

Bacterial infections in healthcare settings are a frequent accompaniment to both routine procedures such as catheterization and surgical site interventions. Their impact is becoming even more marked as the numbers of medical devices that are used to manage chronic health conditions and improve quality of life increases. The resistance of pathogens to multiple antibiotics is also increasing, adding an additional layer of complexity to the problems of employing safe and effective medical procedures. One approach to reducing the rate of infections associated with implanted and indwelling medical devices is the use of polymers that resist the formation of bacterial biofilms. To significantly accelerate the discovery of such materials, we show how state of the art machine learning methods can generate quantitative predictions for the attachment of multiple pathogens to a large library of polymers in a single model for the first time. Such models facilitate design of polymers with very low pathogen attachment across different bacterial species that will be candidate materials for implantable or indwelling medical devices such as urinary catheters, cochlear implants, and pacemakers.

Published

2018