Polymer microarrays rapidly identify competitive adsorbents of virus-like particles

Blok, Andrew J.; Gurnani, Pratik; Xenopoulos, Alex; Burroughs, Laurence; Duncan, Joshua; Urbanowicz, Richard A.; Tsoleridis, Theocharis; M�ller-Kr�uter, Helena; Strecker, Thomas; Ball, Jonathan K.; Alexander, Cameron; Alexander, Morgan R.

doi:10.1116/6.0000586

Polymer microarrays rapidly identify competitive adsorbents of virus-like particles

Blok, Andrew J.; Gurnani, Pratik; Xenopoulos, Alex; Burroughs, Laurence; Duncan, Joshua; Urbanowicz, Richard A.; Tsoleridis, Theocharis; M�ller-Kr�uter, Helena; Strecker, Thomas; Ball, Jonathan K.; Alexander, Cameron; Alexander, Morgan R.

Authors

Andrew J. Blok

Pratik Gurnani

Alex Xenopoulos

Laurence Burroughs

Joshua Duncan

Richard A. Urbanowicz

Theocharis Tsoleridis

Helena M�ller-Kr�uter

Thomas Strecker

Jonathan K. Ball

Professor CAMERON ALEXANDER CAMERON.ALEXANDER@NOTTINGHAM.AC.UK
PROFESSOR OF POLYMER THERAPEUTICS

Professor MORGAN ALEXANDER MORGAN.ALEXANDER@NOTTINGHAM.AC.UK
PROFESSOR OF BIOMEDICAL SURFACES

Abstract

The emergence of SARS-CoV-2 highlights the global need for platform technologies to enable the rapid development of diagnostics, vaccines, treatments, and personal protective equipment (PPE). However, many current technologies require the detailed mechanistic knowledge of specific material-virion interactions before they can be employed, for example, to aid in the purification of vaccine components or in the design of a more effective PPE. Here, we show that an adaption of a polymer microarray method for screening bacterial-surface interactions allows for the screening of polymers for desirable material-virion interactions. Nonpathogenic virus-like particles including fluorophores are exposed to the arrays in an aqueous buffer as a simple model of virions carried to the surface in saliva/sputum. Competitive binding of Lassa and Rubella virus-like particles is measured to probe the relative binding properties of a selection of copolymers. This provides the first step in the development of a method for the discovery of novel materials with promise for viral binding, with the next being development of this method to assess absolute viral adsorption and assessment of the attenuation of the activity of live virus, which we propose would be part of a material scale up step carried out in high containment facilities, alongside the use of more complex media to represent biological fluids.

Citation

Blok, A. J., Gurnani, P., Xenopoulos, A., Burroughs, L., Duncan, J., Urbanowicz, R. A., Tsoleridis, T., Müller-Kräuter, H., Strecker, T., Ball, J. K., Alexander, C., & Alexander, M. R. (2020). Polymer microarrays rapidly identify competitive adsorbents of virus-like particles. Biointerphases, 15(6), Article 061005. https://doi.org/10.1116/6.0000586

Journal Article Type	Article
Acceptance Date	Oct 15, 2020
Online Publication Date	Nov 17, 2020
Publication Date	Nov 17, 2020
Deposit Date	Nov 23, 2020
Publicly Available Date	Nov 25, 2020
Journal	Biointerphases
Print ISSN	1934-8630
Electronic ISSN	1559-4106
Publisher	American Institute of Physics
Peer Reviewed	Peer Reviewed
Volume	15
Issue	6
Article Number	061005
DOI	https://doi.org/10.1116/6.0000586
Keywords	General Biochemistry, Genetics and Molecular Biology; General Physics and Astronomy; General Materials Science; General Chemistry
Public URL	https://nottingham-repository.worktribe.com/output/5064613
Publisher URL	https://avs.scitation.org/doi/10.1116/6.0000586
Additional Information	Received: 2020-08-27; Accepted: 2020-10-15; Published: 2020-11-17