Your search keyword '"Coad BR"' showing total 35 results

1. Morphology control in polymerised high internal phase emulsion templated via macro-RAFT agent composition: visualizing surface chemistry

Author

Bryan R. Coad, R. D. Arrua, Stuart C. Thickett, Aminreza Khodabandeh, Takuji Ohigashi, Nobuhiro Kosugi, Thomas Rodemann, Emily F. Hilder, Khodabandeh, A, Arrua, RD, Coad, BR, Rodemann, T, Ohigashi, T, Kosugi, N, Thickett, SC, and Hilder, EF

Subjects

emulsion, Polymers and Plastics, Organic Chemistry, surface chemistry, Bioengineering, 02 engineering and technology, Raft, polymerized high internal phase emulsion (polyHIPE), 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Biochemistry, 0104 chemical sciences, Styrene, chemistry.chemical_compound, Chemical engineering, chemistry, Polymerization, Amphiphile, Emulsion, Surface modification, Fourier transform infrared spectroscopy, 0210 nano-technology, macro-RAFT agent, Acrylic acid

Abstract

A series of polymerized high internal phase emulsion (polyHIPE) materials have been prepared by using a water in oil emulsion stabilized by a macro-RAFT agent, 2-(butylthiocarbonothioylthio)-2-poly(styrene)-b-poly(acrylic acid), acting as a polymeric surfactant. The pore structures of the formed polyHIPEs were closed. By removing the RAFT-endgroup of the amphiphilic macro-RAFT agent, the obtained polyHIPEs possessed an open structure with voids. The effect of the RAFT-endgroup of the amphiphilic macro-RAFT agent on the surface chemistry of the polyHIPEs is discussed. The obtained polyHIPEs via this surfactant-assisted functionalization strategies were characterized by FTIR spectroscopy, FTIR mapping, SEM, SEM-EDX, TEM, XPS as well as synchrotron-based scanning transmission X-ray microscopy (STXM). The latter technique revealed the surface chemistry of the obtained polyHIPEs and macro-RAFT agent multicomponents with a surface spatial resolution of the order of 30-100 nm. Refereed/Peer-reviewed

Published

2018

2. Candida auris susceptibility on surfaces coated with the antifungal drug caspofungin.

Author

Lamont-Friedrich SJ, Kidd SE, Giles C, Griesser HJ, and Coad BR

Subjects

Animals, Drug Resistance, Fungal, Infection Control, Antifungal Agents pharmacology, Candida auris drug effects, Caspofungin pharmacology

Abstract

Candida auris is known to survive for weeks on solid material surfaces. Its longevity contributes to medical device contamination and spread through healthcare facilities. We fabricated antifungal surface coatings by coating plastic and glass surfaces with a thin polymer layer to which the antifungal drug caspofungin was covalently conjugated. Caspofungin-susceptible and -resistant C. auris strains were inhibited on these surfaces by 98.7 and 81.1%, respectively. Cell viability studies showed that this inhibition was fungicidal. Our findings indicate that C. auris strains can be killed on contact when exposed to caspofungin that is reformulated as a covalently-bound surface layer., Lay Summary: Candida auris is pathogenic, multidrug resistant yeast with the ability to survive on surfaces and remain transmissible for long periods of time in healthcare settings. In this study, we have prepared an antifungal surface coating and demonstrated its ability to kill adhering C. auris cells on contact., (© The Author(s) 2021. Published by Oxford University Press on behalf of The International Society for Human and Animal Mycology.)

Published

2021

3. Assessment of nonreleasing antifungal surface coatings bearing covalently attached pharmaceuticals.

Author

Naderi J, Griesser HJ, and Coad BR

Subjects

Anidulafungin, Echinocandins, Lipopeptides, Micafungin, Microbial Sensitivity Tests, Antifungal Agents pharmacology, Pharmaceutical Preparations

Abstract

There are many reports of antimicrobial coatings bearing immobilized active agents on surfaces; however, strong analytical evidence is required to verify that the agents are indeed covalently attached to the surface. In the absence of such evidence, antimicrobial activity could result from a release of active agents. We report a detailed assessment of antifungal surface coatings prepared using covalent attachment chemistries, with the aim of establishing a set of instrumental and biological evidence required to convincingly demonstrate antimicrobial activity due to nonreleasing, surface active compounds and to exclude the alternate possibility of activity due to release. The strongest biological evidence initially supporting permanent antifungal activity was the demonstration of the ability to reuse samples in multiple, sequential pathogen challenges. However, additional supporting evidence from washing studies and instrumental analysis is also required to probe the possibility of gradual desorption of strongly physisorbed compounds versus covalently attached compounds. Potent antifungal surface coatings were prepared from approved pharmaceutical compounds from the echinocandin drug class (caspofungin, anidulafungin, and micafungin) and assessed by microbiological tests and instrumental methods. Carbonyl diimidazole linking chemistry enabled covalent attachment of caspofungin, anidulafungin, and micafungin to plasma polymer surfaces, with antifungal surface activity likely caused by molecular orientations that present the lipophilic tail toward interfacing fungal cells. This study demonstrates the instrumental and biological evidence required to convincingly ascertain activity due to nonreleasing, surface active compounds and summarize these as three criteria for assessing other reports on surface-immobilized antimicrobial compounds.

Published

2021

4. Candida albicans Can Survive Antifungal Surface Coatings on Surfaces with Microcone Topography.

Author

Chakraborty A, Jasieniak M, Coad BR, and Griesser HJ

Subjects

Biofilms, Humans, Hyphae, Microscopy, Electron, Scanning, Antifungal Agents pharmacology, Candida albicans

Abstract

This study demonstrates the ability of Candida albicans , a medically significant human fungal pathogen, to minimize contact with an antifungal surface coating that on a flat surface is lethal on contact by growing on and between micron-sized surface topographical features, thus minimizing the contact area. Scanning electron microscopy showed that cells contacting the "floor" between microcones were killed, whereas cells attached to microcones survived and formed hyphal filaments. These spanned space between cones and avoided contact with the flat surface in-between cones. Thus, fungal cells managed to attach and grow despite the antifungal coating. This ability of Candida albicans to exploit topography features to minimize surface contact yet utilize the solid surface for anchoring reduces the effectiveness of the grafted antifungal surface coating. This suggests that biomedical devices with rough surfaces might be more challenging to protect against fungal biofilm formation via application of an antifungal coating.

Published

2021

5. Crowdsourced analysis of fungal growth and branching on microfluidic platforms.

Author

Hopke A, Mela A, Ellett F, Carter-House D, Peña JF, Stajich JE, Altamirano S, Lovett B, Egan M, Kale S, Kronholm I, Guerette P, Szewczyk E, McCluskey K, Breslauer D, Shah H, Coad BR, Momany M, and Irimia D

Subjects

Ascomycota growth & development, Basidiomycota growth & development, Biological Phenomena, Fungi classification, Hyphae classification, Hyphae growth & development, Species Specificity, Crowdsourcing methods, Fungi growth & development, Microfluidic Analytical Techniques instrumentation

Abstract

Fungal hyphal growth and branching are essential traits that allow fungi to spread and proliferate in many environments. This sustained growth is essential for a myriad of applications in health, agriculture, and industry. However, comparisons between different fungi are difficult in the absence of standardized metrics. Here, we used a microfluidic device featuring four different maze patterns to compare the growth velocity and branching frequency of fourteen filamentous fungi. These measurements result from the collective work of several labs in the form of a competition named the "Fungus Olympics." The competing fungi included five ascomycete species (ten strains total), two basidiomycete species, and two zygomycete species. We found that growth velocity within a straight channel varied from 1 to 4 μm/min. We also found that the time to complete mazes when fungal hyphae branched or turned at various angles did not correlate with linear growth velocity. We discovered that fungi in our study used one of two distinct strategies to traverse mazes: high-frequency branching in which all possible paths were explored, and low-frequency branching in which only one or two paths were explored. While the high-frequency branching helped fungi escape mazes with sharp turns faster, the low-frequency turning had a significant advantage in mazes with shallower turns. Future work will more systematically examine these trends., Competing Interests: The authors have read the journal’s policy and have the following competing interests: Paul Guerette, Edyta Szewczyk, Kevin McCluskey, and David Breslauer are paid employees of Bolt Threads, Inc. There are no patents, products in development or marketed products associated with this research to declare. This does not alter our adherence to PLOS ONE policies on sharing data and materials.

Published

2021

6. Combatting fungal biofilm formation by diffusive release of fluconazole from heptylamine plasma polymer coating.

Author

Naderi J, Giles C, Saboohi S, Griesser HJ, and Coad BR

Subjects

Amines chemistry, Antifungal Agents chemistry, Antifungal Agents metabolism, Candida albicans physiology, Diffusion, Fluconazole chemistry, Fluconazole pharmacology, Microbial Sensitivity Tests, Polymers metabolism, Surface Properties, Antifungal Agents pharmacology, Biofilms drug effects, Fluconazole metabolism, Plasma Gases chemistry, Polymers chemistry

Abstract

A drug-eluting coating applied onto biomedical devices and implants is an appropriate way to ensure that an inhibitory concentration of antimicrobial drugs is present at the device surface, thus preventing surface colonization and subsequent biofilm formation. In this study, a thin polymer coating was applied to materials, and it acted as a drug-delivery reservoir capable of surface delivery of the antifungal drug fluconazole to amounts up to 21 μg/cm 2 . The release kinetics into aqueous solution were quantified by UV spectroscopy and conformed to the Ritger-Peppas and Korsmeyer-Peppas model. Complementary microbiological assays were used to determine effectiveness against Candida albicans attachment and biofilm formation, and against the control heptylamine plasma polymer coating without drug loading, on which substantial fungal growth occurred. Fluconazole release led to marked antifungal activity in all assays, with log 1.6 reduction in CFUs/cm 2 . Cell viability assays and microscopy revealed that fungal cells attached to the fluconazole-loaded coating remained rounded and did not form hyphae and biofilm. Thus, in vitro screening results for fluconazole-releasing surface coatings showed efficacy in the prevention of the formation of Candida albicans biofilm.

Published

2020

7. The Physics of Plasma Ion Chemistry: A Case Study of Plasma Polymerization of Ethyl Acetate.

Author

Saboohi S, Short RD, Coad BR, Griesser HJ, and Michelmore A

Abstract

Deposition chemistry from plasma is highly dependent on both the chemistry of the ions arriving at surfaces and the ion energy. Typically, when measuring the energy distribution of ions arriving at surfaces from plasma, it is assumed that the distributions are the same for all ionic species. Using ethyl acetate as a representative organic precursor molecule, we have measured the ion chemistry and ion energy as a function of pressure and power. We show that at low pressure (<2 Pa) this assumption is valid; however, at elevated pressures ion-molecule collisions close to the deposition surface affect both the energy and chemistry of these ions. Smaller ions are formed close to the surface and have lower energy than larger ionic species which are formed in the bulk of the plasma. The changes in plasma chemistry therefore are closely linked to the physics of the plasma-surface interface.

Published

2019

8. Visualizing Biomaterial Degradation by Candida albicans Using Embedded Luminescent Molecules To Report on Substrate Digestion and Cellular Uptake of Hydrolysate.

Author

Coad BR, Michl TD, Bader CA, Baranger J, Giles C, Gonçalves GC, Nath P, Lamont-Friedrich SJ, Johnsson M, Griesser HJ, and Plush SE

Abstract

Microbial pathogens use hydrolases as a virulence strategy to spread disease through tissues and colonize medical device surfaces; however, visualizing this process is a technically challenging problem. To better understand the role of secreted fungal hydrolases and their role in Candida albicans virulence, we developed an in situ model system using luminescent Re(I) and Ir(III) containing probe molecules embedded in a biodegradable (poly(lactic- co -glycolic acid), PLGA) polymer and tracked their uptake using epifluorescent imaging. We found that secretion of esterases can explain how physically embedded probes are acquired by fungal cells through the degradation of PLGA since embedded probes could not be liberated from nonbiodegradable polystyrene (PS). It was important to verify that epifluorescent imaging captured the fate of probe molecules rather than naturally occurring fungal autofluorescence. For this, we exploited the intense luminescent signals and long spectral relaxation times of the Re and Ir containing probe molecules, resolved in time using a gated imaging system. Results provide a visual demonstration of a key virulence trait of C. albicans : the use of hydrolases as a means to degrade materials and acquire hydrolysis products during fungal growth and hyphal development. These results help to explain the role of nonspecific hydrolases using a degradable material that is relevant to the study of fungal pathogenesis on biotic (tissues) surfaces. Additionally, understanding how fungal pathogens condition surfaces by using nonspecific hydrolases is important to the study of fungal attachment on abiotic surfaces, the first step in biofilm formation on medical devices.

Published

2019

9. Antifungal Activity in Compounds from the Australian Desert Plant Eremophila alternifolia with Potency Against Cryptococcus spp.

Author

Hossain MA, Biva IJ, Kidd SE, Whittle JD, Griesser HJ, and Coad BR

Abstract

Plant metabolites that have shown activity against bacteria and/or environmental fungi represent valuable leads for the identification and development of novel drugs against clinically important human pathogenic fungi. Plants from the genus Eremophila were highly valued in traditional Australian Aboriginal medicinal practices, and E. alternifolia was the most prized among them. As antibacterial activity of extracts from E. alternifolia has been documented, this study addresses the question whether there is also activity against infectious fungal human pathogens. Compounds from leaf-extracts were purified and identified by 1- and 2-D NMR. These were then tested by disk diffusion and broth microdilution assays against ten clinically and environmentally relevant yeast and mould species. The most potent activity was observed with the diterpene compound, 8,19-dihydroxyserrulat-14-ene against Cryptococcus gattii and Cryptococcus neoformans, with minimum inhibition concentrations (MIC) comparable to those of Amphotericin B. This compound also exhibited activity against six Candida species. Combined with previous studies showing an antibacterial effect, this finding could explain a broad antimicrobial effect from Eremophila extracts in their traditional medicinal usage. The discovery of potent antifungal compounds from Eremophila extracts is a promising development in the search for desperately needed antifungal compounds particularly for Cryptococcus infections., Competing Interests: The authors declare no conflict of interest.

Published

2019

10. Structure, Mechanism, and Inhibition of Aspergillus fumigatus Thioredoxin Reductase.

Author

Marshall AC, Kidd SE, Lamont-Friedrich SJ, Arentz G, Hoffmann P, Coad BR, and Bruning JB

Subjects

Aspergillus fumigatus growth & development, Crystallography, X-Ray, Drug Resistance, Fungal, Humans, Isoindoles, Microbial Sensitivity Tests, Molecular Conformation, Molecular Docking Simulation, Thioredoxin-Disulfide Reductase physiology, Antifungal Agents pharmacology, Aspergillus fumigatus drug effects, Aspergillus fumigatus enzymology, Azoles pharmacology, Organoselenium Compounds pharmacology, Thioredoxin-Disulfide Reductase antagonists & inhibitors

Abstract

Aspergillus fumigatus infections are associated with high mortality rates and high treatment costs. Limited available antifungals and increasing antifungal resistance highlight an urgent need for new antifungals. Thioredoxin reductase (TrxR) is essential for maintaining redox homeostasis and presents as a promising target for novel antifungals. We show that ebselen [2-phenyl-1,2-benzoselenazol-3(2H)-one] is an inhibitor of A. fumigatus TrxR ( K i = 0.22 μM) and inhibits growth of Aspergillus spp., with in vitro MIC values of 16 to 64 µg/ml. Mass spectrometry analysis demonstrates that ebselen interacts covalently with a catalytic cysteine of TrxR, Cys148. We also present the X-ray crystal structure of A. fumigatus TrxR and use in silico modeling of the enzyme-inhibitor complex to outline key molecular interactions. This provides a scaffold for future design of potent and selective antifungal drugs that target TrxR, improving the potency of ebselen toward inhbition of A. fumigatus growth., (Copyright © 2019 American Society for Microbiology.)

Published

2019

11. Surface coatings with covalently attached anidulafungin and micafungin prevent Candida albicans biofilm formation.

Author

Naderi J, Giles C, Saboohi S, Griesser HJ, and Coad BR

Subjects

Candida albicans physiology, Immobilized Proteins pharmacology, Surface Properties, Anidulafungin pharmacology, Antifungal Agents pharmacology, Biofilms drug effects, Candida albicans drug effects, Micafungin pharmacology

Abstract

Objectives: Fungal biofilms caused by Candida spp. are a major contributor to infections originating from infected biomaterial implants. Since echinocandin-class molecules interfere with the integrity of the fungal cell wall, it was hypothesized that surface-immobilized anidulafungin and micafungin could play a role in preventing fungal adhesion and biofilm formation on surfaces., Methods: Anidulafungin and micafungin were covalently coupled to biomaterial surfaces and washed. Surface-sensitive instrumental analysis quantitatively and qualitatively confirmed their presence. Analysis after washing experiments provided evidence of their covalent immobilization. The in vitro antifungal properties of surfaces were confirmed using static biofilm assays and fluorescence microscopy kinetic studies., Results: Antifungal surface coatings eliminated 106 cfu/cm2 inoculations of Candida albicans and prevented biofilm formation and hyphal development on coated surfaces. Surfaces were successively exposed to fresh inoculum and were effective for at least five challenges in eliminating adherent yeasts., Conclusions: We have observed antifungal and anti-biofilm activity of surfaces bearing conjugated echinocandins, which operate through surface contact. The analytical and biological evidence suggests an antifungal mechanism for echinocandins that does not rely upon freely diffusing molecules.

Published

2019

12. Surface-grafted antimicrobial drugs: Possible misinterpretation of mechanism of action.

Author

Naderi J, Giles C, Saboohi S, Griesser HJ, and Coad BR

Subjects

Antifungal Agents pharmacokinetics, Candida albicans growth & development, Colony Count, Microbial, Photoelectron Spectroscopy, Polyenes pharmacokinetics, Polyenes pharmacology, Spectrometry, Mass, Secondary Ion, Antifungal Agents pharmacology, Candida albicans drug effects, Coated Materials, Biocompatible chemistry, Surface Properties

Abstract

Antimicrobial surface coatings that act through a contact-killing mechanism (not diffusive release) could offer many advantages to the design of medical device coatings that prevent microbial colonization and infections. However, as the authors show here, to prevent arriving at an incorrect conclusion about their mechanism of action, it is essential to employ thorough washing protocols validated by surface analytical data. Antimicrobial surface coatings were fabricated by covalently attaching polyene antifungal drugs to surface coatings. Thorough washing (often considered to be sufficient to remove noncovalently attached molecules) was used after immobilization and produced samples that showed a strong antifungal effect, with a log 6 reduction in Candida albicans colony forming units. However, when an additional washing step using surfactants and warmed solutions was used, more firmly adsorbed compounds were eluted from the surface as evidenced by XPS and ToF-SIMS, resulting in reduction and complete elimination of in vitro antifungal activity. Thus, polyene molecules covalently attached to surfaces appear not to have a contact-killing effect, probably because they fail to reach their membrane target. Without additional stringent washing and surface analysis, the initial favorable antimicrobial testing results could have been misinterpreted as evidencing activity of covalently grafted polyenes, while in reality activity arose from desorbing physisorbed molecules. To avoid unintentional confirmation bias, they suggest that binding and washing protocols be analytically verified by qualitative/quantitative instrumental methods, rather than relying on false assumptions of the rigors of washing/soaking protocols.

Published

2018

13. Promiscuous hydrogen in polymerising plasmas.

Author

Saboohi S, Griesser HJ, Coad BR, Short RD, and Michelmore A

Abstract

Historically, there have been two opposing views regarding deposition mechanisms in plasma polymerisation, radical growth and direct ion deposition, with neither being able to fully explain the chemistry of the resultant coating. Deposition rate and film chemistry are dependent on the chemistry of the plasma phase and thus the activation mechanisms of species in the plasma are critical to understanding the relative contributions of various chemical and physical routes to plasma polymer formation. In this study, we investigate the roles that hydrogen plays in activating and deactivating reactive plasma species. Ethyl trimethylacetate (ETMA) is used as a representative organic precursor, and additional hydrogen is added to the plasma in the form of water and deuterium oxide. Optical emission spectroscopy confirms that atomic hydrogen is abundant in the plasma. Comparison of the plasma phase mass spectra of ETMA/H 2 O and ETMA/D 2 O reveals that (1) proton transfer from hydronium is a common route to charging precursors in plasma, and (2) hydrogen abstraction (activation) and recombination (deactivation) processes are much more dynamic in the plasma than previously thought. Consideration of the roles of hydrogen in plasma chemistry may then provide a more comprehensive view of deposition processes and bridge the divide between the two disparate schools of thought.

Published

2018

14. The importance of fungal pathogens and antifungal coatings in medical device infections.

Author

Giles C, Lamont-Friedrich SJ, Michl TD, Griesser HJ, and Coad BR

Subjects

Animals, Humans, Mice, Antifungal Agents pharmacology, Antifungal Agents therapeutic use, Catheter-Related Infections drug therapy, Catheter-Related Infections microbiology, Coated Materials, Biocompatible, Fungi drug effects, Fungi pathogenicity, Mycoses drug therapy, Mycoses microbiology, Prosthesis-Related Infections drug therapy, Prosthesis-Related Infections microbiology

Abstract

In recent years, increasing evidence has been collated on the contributions of fungal species, particularly Candida, to medical device infections. Fungal species can form biofilms by themselves or by participating in polymicrobial biofilms with bacteria. Thus, there is a clear need for effective preventative measures, such as thin coatings that can be applied onto medical devices to stop the attachment, proliferation, and formation of device-associated biofilms. However, fungi being eukaryotes, the challenge is greater than for bacterial infections because antifungal agents are often toxic towards eukaryotic host cells. Whilst there is extensive literature on antibacterial coatings, a far lesser body of literature exists on surfaces or coatings that prevent attachment and biofilm formation on medical devices by fungal pathogens. Here we review strategies for the design and fabrication of medical devices with antifungal surfaces. We also survey the microbiology literature on fundamental mechanisms by which fungi attach and spread on natural and synthetic surfaces. Research in this field requires close collaboration between biomaterials scientists, microbiologists and clinicians; we consider progress in the molecular understanding of fungal recognition of, and attachment to, suitable surfaces, and of ensuing metabolic changes, to be essential for designing rational approaches towards effective antifungal coatings, rather than empirical trial of coatings., (Copyright © 2017 Elsevier Inc. All rights reserved.)

Published

2018

15. Caspofungin on ARGET-ATRP grafted PHEMA polymers: Enhancement and selectivity of prevention of attachment of Candida albicans.

Author

Michl TD, Giles C, Mocny P, Futrega K, Doran MR, Klok HA, Griesser HJ, and Coad BR

Subjects

Biofilms drug effects, Biofilms growth & development, Candida albicans physiology, Caspofungin, Coated Materials, Biocompatible chemical synthesis, Antifungal Agents pharmacology, Candida albicans drug effects, Cell Adhesion drug effects, Coated Materials, Biocompatible chemistry, Drug Carriers, Echinocandins pharmacology, Lipopeptides pharmacology, Polyhydroxyethyl Methacrylate chemistry

Abstract

There is a need for coatings for biomedical devices and implants that can prevent the attachment of fungal pathogens while allowing human cells and tissue to appose without cytotoxicity. Here, the authors study whether a poly(2-hydroxyethylmethacrylate) (PHEMA) coating can suppress attachment and biofilm formation by Candida albicans and whether caspofungin terminally attached to surface-tethered polymeric linkers can provide additional benefits. The multistep coating scheme first involved the plasma polymerization of ethanol, followed by the attachment of α-bromoisobutyryl bromide (BiBB) onto surface hydroxyl groups of the plasma polymer layer. Polymer chains were grafted using surface initiated activators regenerated by electron transfer atom transfer radical polymerization with 2-hydroxyethylmethacrylate, yielding PHEMA layers with a dry thickness of up to 89 nm in 2 h. Hydroxyl groups of PHEMA were oxidized to aldehydes using the Albright-Goldman reaction, and caspofungin was covalently immobilized onto them using reductive amination. While the PHEMA layer by itself reduced the growth of C. albicans biofilms by log 1.4, the addition of caspofungin resulted in a marked further reduction by >4 log units to below the threshold of the test. The authors have confirmed that the predominant mechanism of action is caused by antifungal drug molecules that are covalently attached to the surface, rather than out-diffusing from the coating. The authors confirm the selectivity of surface-attached caspofungin in eliminating fungal, not mammalian cells by showing no measurable toxicity toward the myeloid leukaemia suspension cell line KG-1a.

Published

2017

16. Synthesis of highly functionalised plasma polymer films from protonated precursor ions via the plasma α-γ transition.

Author

Saboohi S, Coad BR, Griesser HJ, Michelmore A, and Short RD

Abstract

Chemically functionalized surfaces may be produced via plasma polymerization, however a high degree of functional group retention is often difficult to achieve. Here, the plasma polymerization of three structurally related ester precursors, ethyl isobutyrate (EIB), methyl isobutyrate (MIB) and ethyl trimethylacetate (ETMA) is compared at low and high pressure. In moving from a low pressure to higher pressure regime, significant changes in the plasma chemistry and resulting plasma polymer deposit were observed with much higher retention of chemical functionality at the higher pressure observed. Until now these changes would have been attributed to a decrease in the energy/molecule, however we show by direct measurement of the chemistry and physics of the plasma that there is fundamental shift in the properties of the plasma and surface interactions which explain the results. At low pressure (α regime) precursor fragmentation and neutral deposition dominate resulting in poor functional group retention. Increasing the pressure such that the sheath region close to surfaces becomes collisional (γ regime) favours production of protonated precursor ions which retain functionality and dominate the deposition process rather than radical species.

Published

2017

17. Hyperthermal Intact Molecular Ions Play Key Role in Retention of ATRP Surface Initiation Capability of Plasma Polymer Films from Ethyl α-Bromoisobutyrate.

Author

Saboohi S, Coad BR, Michelmore A, Short RD, and Griesser HJ

Abstract

We report a systematic study of the plasma polymerization of ethyl α-bromoisobutyrate (EBIB) to produce thin film coatings capable of serving as ATRP initiation surfaces, for which they must contain α-bromoisobutyryl functional groups. In the deposition of polymeric coatings by plasma polymerization there generally occurs considerable fragmentation of precursor ("monomer") molecules in the plasma; and the retention of larger structural elements is challenging, particularly when they are inherently chemically labile. Empirical principles such as low plasma power and low pressure are usually utilized. However, we show that the α-bromoisobutyryl structural moiety is labile in a plasma gas phase and in low pressure plasma conditions, below the collisional threshold, there is little retention. At higher pressure, in contrast, fragmentation of this structural motif appears to be reduced substantially, and coatings useful for ATRP initiation were obtained. Mass spectrometry analysis of the composition of the plasma phase revealed that the desired structural moiety can be retained through the plasma, if the plasma conditions are steered toward ions of the precursor molecule. Whereas at low pressure the plasma polymer assembles mainly from various neutral (radical) fragments, at higher pressure the deposition occurs from hyperthermal ions, among which the protonated intact molecular ion is the most abundant. At higher pressure, a substantial population of ions has low kinetic energy, leading to "soft landing" and thus less fragmentation. This study demonstrates that relatively complex structural motifs in precursor molecules can be retained in plasma polymerization if the chemical and physical processes occurring in the plasma phase are elucidated and controlled such that desirable larger structural elements play a key role in the film deposition.

Published

2016

18. Anti-infective Surface Coatings: Design and Therapeutic Promise against Device-Associated Infections.

Author

Coad BR, Griesser HJ, Peleg AY, and Traven A

Subjects

Biofilms growth & development, Humans, Anti-Infective Agents pharmacology, Biofilms drug effects, Prosthesis-Related Infections prevention & control

Published

2016

19. "Thunderstruck": Plasma-Polymer-Coated Porous Silicon Microparticles As a Controlled Drug Delivery System.

Author

McInnes SJ, Michl TD, Delalat B, Al-Bataineh SA, Coad BR, Vasilev K, Griesser HJ, and Voelcker NH

Subjects

Antineoplastic Agents chemistry, Drug Carriers chemistry, Humans, Microscopy, Electron, Scanning, Particle Size, Polymers chemistry, Polymers therapeutic use, Porosity, Silicon chemistry, Silicon therapeutic use, Antineoplastic Agents therapeutic use, Camptothecin therapeutic use, Drug Carriers therapeutic use, Drug Delivery Systems, Neuroblastoma drug therapy

Abstract

Controlling the release kinetics from a drug carrier is crucial to maintain a drug's therapeutic window. We report the use of biodegradable porous silicon microparticles (pSi MPs) loaded with the anticancer drug camphothecin, followed by a plasma polymer overcoating using a loudspeaker plasma reactor. Homogenous "Teflon-like" coatings were achieved by tumbling the particles by playing AC/DC's song "Thunderstruck". The overcoating resulted in a markedly slower release of the cytotoxic drug, and this effect correlated positively with the plasma polymer coating times, ranging from 2-fold up to more than 100-fold. Ultimately, upon characterizing and verifying pSi MP production, loading, and coating with analytical methods such as time-of-flight secondary ion mass spectrometry, scanning electron microscopy, thermal gravimetry, water contact angle measurements, and fluorescence microscopy, human neuroblastoma cells were challenged with pSi MPs in an in vitro assay, revealing a significant time delay in cell death onset.

Published

2016

20. ToF-SIMS multivariate analysis of surface-grafted small bioactive molecules.

Author

Jasieniak M, Coad BR, and Griesser HJ

Subjects

Multivariate Analysis, Spectrometry, Mass, Secondary Ion, Biological Products analysis, Coated Materials, Biocompatible chemistry, Surface Properties

Abstract

In the development of bioactive coatings on biomaterials, it is essential to characterize the successful fabrication and the uniformity of intended coatings by sensitive surface analytical techniques, so as to ensure reliable interpretation of observed biointerfacial responses. This can, however, be challenging when small bioactive molecules are grafted onto biomaterials surfaces at sub- and near-monolayer densities. Time-of-flight secondary ion mass spectrometry (ToF-SIMS) provides the required sensitivity, but ion signals from small grafted molecules may still be dominated by fragment ions from the underlying polymer. In such cases, multivariate analysis provides valuable enhancement of spectral data, as illustrated here by examples comprising the surface grafting of bioactive serrulatane molecules, the peptide GRGDSP, the oligonucleotide 15-thymidine, and the antifungal compound Amphotericin B. The authors also show how ToF-SIMS plus principal component analysis can distinguish between covalent grafting and physisorption of the antibiotics caspofungin and micafungin.

Published

2015

21. Antifungal coatings by caspofungin immobilization onto biomaterials surfaces via a plasma polymer interlayer.

Author

Griesser SS, Jasieniak M, Coad BR, and Griesser HJ

Subjects

Adsorption, Antifungal Agents chemistry, Biofilms drug effects, Biofilms growth & development, Candida drug effects, Candida physiology, Caspofungin, Echinocandins chemistry, Humans, Lipopeptides, Photoelectron Spectroscopy, Spectrometry, Mass, Secondary Ion, Aldehydes chemistry, Antifungal Agents pharmacology, Biocompatible Materials chemistry, Echinocandins pharmacology, Polymers chemistry, Surface Properties

Abstract

Not only bacteria but also fungal pathogens, particularly Candida species, can lead to biofilm infections on biomedical devices. By covalent grafting of the antifungal drug caspofungin, which targets the fungal cell wall, onto solid biomaterials, a surface layer can be created that might be able to provide long-term protection against fungal biofilm formation. Plasma polymerization of propionaldehyde (propanal) was used to deposit a thin (∼20 nm) interfacial bonding layer bearing aldehyde surface groups that can react with amine groups of caspofungin to form covalent interfacial bonds for immobilization. Surface analyses by x-ray photoelectron spectroscopy and time-of-flight secondary ion mass spectrometry confirmed the intended grafting and uniformity of the coatings, and durability upon extended washing. Testing for fungal cell attachment and ensuing biofilm formation showed that caspofungin retained activity when covalently bound onto surfaces, disrupting colonizing Candida cells. Mammalian cytotoxicity studies using human primary fibroblasts indicated that the caspofungin-grafted surfaces were selective in eliminating fungal cells while allowing attachment and spreading of mammalian cells. These in vitro data suggest promise for use as antifungal coatings, for example, on catheters, and the use of a plasma polymer interlayer enables facile transfer of the coating method onto a wide variety of biomaterials and biomedical devices.

Published

2015

22. Comparison of Plasma Polymerization under Collisional and Collision-Less Pressure Regimes.

Author

Saboohi S, Jasieniak M, Coad BR, Griesser HJ, Short RD, and Michelmore A

Abstract

While plasma polymerization is used extensively to fabricate functionalized surfaces, the processes leading to plasma polymer growth are not yet completely understood. Thus, reproducing processes in different reactors has remained problematic, which hinders industrial uptake and research progress. Here we examine the crucial role pressure plays in the physical and chemical processes in the plasma phase, in interactions at surfaces in contact with the plasma phase, and how this affects the chemistry of the resulting plasma polymer films using ethanol as the gas precursor. Visual inspection of the plasma reveals a change from intense homogeneous plasma at low pressure to lower intensity bulk plasma at high pressure, but with increased intensity near the walls of the chamber. It is demonstrated that this occurs at the transition from a collision-less to a collisional plasma sheath, which in turn increases ion and energy flux to surfaces at constant RF power. Surface analysis of the resulting plasma polymer films show that increasing the pressure results in increased incorporation of oxygen and lower cross-linking, parameters which are critical to film performance. These results and insights help to explain the considerable differences in plasma polymer properties observed by different research groups using nominally similar processes.

Published

2015

23. Surface coatings with covalently attached caspofungin are effective in eliminating fungal pathogens.

Author

Coad BR, Lamont-Friedrich SJ, Gwynne L, Jasieniak M, Griesser SS, Traven A, Peleg AY, and Griesser HJ

Abstract

In this work we have prepared surface coatings formulated with the antifungal drug caspofungin, an approved pharmaceutical lipopeptide compound of the echinocandin drug class. Our hypothesis was to test whether an antifungal drug with a known cell-wall disrupting effect could be irreversibly tethered to surface coatings and kill (on contact) biofilm-forming fungal human pathogens from Candida spp. The first aim of the study was to use surface analysis to prove that the chemical binding to the surface polymer interlayer was through specific and irreversible bonds (covalent) and not due to non-specific adsorption through weak forces that could be later reversed (physisorption). Secondly, we quantified the antifungal nature of these coatings in a biological assay showing excellent killing against C. albicans and C. tropicalis and moderate killing against C. glabrata and C. parapsilosis. We concluded that caspofungin retains antifungal activity even when it is irreversibly immobilized on a surface, providing a new insight into its mechanism of action. Thus, surface coatings that have echinocandins permanently bound will be useful in preventing the establishment of fungal biofilms on materials.

Published

2015

24. Nitric oxide releasing plasma polymer coating with bacteriostatic properties and no cytotoxic side effects.

Author

Michl TD, Coad BR, Doran M, Osiecki M, Kafshgari MH, Voelcker NH, Hüsler A, Vasilev K, and Griesser HJ

Subjects

Anti-Bacterial Agents adverse effects, Anti-Bacterial Agents chemistry, Anti-Bacterial Agents pharmacology, Humans, Polymers adverse effects, Drug Carriers chemistry, Drug Liberation, Nitric Oxide chemistry, Plasma Gases chemistry, Polymers chemistry, Polymers pharmacology

Abstract

We report a stable plasma polymer coating, using isopentyl nitrite as a volatile precursor, which releases nitric oxide at bacteriostatic concentrations when contacted with water, inhibiting bacterial growth without cytotoxic side effects to human mesenchymal stem/stromal cells.

Published

2015

25. Polymer brush gradients grafted from plasma-polymerized surfaces.

Author

Coad BR, Bilgic T, and Klok HA

Abstract

A new method for generating a surface density gradient of polymer chains is presented. A substrate-independent polymer deposition technique was used to coat materials with a chemical gradient based on plasma copolymerization of 1,7-octadiene and allylamine. This provided a uniform chemical gradient to which initiators for atom transfer radical polymerization (ATRP) were immobilized. After surface-initiated atom transfer radical polymerization (SI-ATRP), poly(2-hydroxyethyl methacrylate) (PHEMA) chains were grafted from the surface and the measured thickness profiles provided direct evidence for how surface crowding provides an entropic driving force resulting in chain extension away from the surface. Film thicknesses were found to increase with the position along the gradient surface, reflecting the gradual transition from collapsed to more extended surface-tethered polymer chains as the grafting density increased. The method described is novel in that the approach provides covalent linkages from the polymer coating to the substrate and is not limited to a particular surface chemistry of the starting material.

Published

2014

26. One step ATRP initiator immobilization on surfaces leading to gradient-grafted polymer brushes.

Author

Coad BR, Styan KE, and Meagher L

Abstract

A method is described that allows potentially any surface to be functionalized covalently with atom transfer radical polymerization (ATRP) initiators derived from ethyl-2-bromoisobutyrl bromide in a single step. In addition, the initiator surface density was variable and tunable such that the thickness of polymer chain grafted from the surface varied greatly on the surfaces providing examples, across the surface of a substrate, of increased chain stretching due to the entropic nature of crowded polymer chains leading toward polymer brushes. An initiator gradient of increasing surface density was deposited by plasma copolymerization of an ATRP initiator (ethyl 2-bromoisobutyrate) and a non-ATRP reactive diluent molecule (ethanol). The deposited plasma polymer retained its chemical ability to surface-initiate polymerization reactions as exemplified by N,N'-dimethyl acrylamide and poly(ethylene glycol) methyl ether methacrylate polymerizations, illustrating linear and bottle-brush-like chains, respectively. A large variation in graft thickness was observed from the low to high chain-density side suggesting that chains were forced to stretch away from the surface interface--a consequence of entropic effects resulting from increased surface crowding. The tert-butyl bromide group of ethyl 2-bromoisobutyrate is a commonly used initiator in ATRP, so a method for covalent linkage to any substrate in a single step desirably simplifies the multistep surface activation procedures currently used.

Published

2014

27. Biomaterials surfaces capable of resisting fungal attachment and biofilm formation.

Author

Coad BR, Kidd SE, Ellis DH, and Griesser HJ

Subjects

Surface Properties, Antifungal Agents chemistry, Antifungal Agents pharmacology, Biocompatible Materials chemistry, Biocompatible Materials pharmacology, Biofilms drug effects, Biofilms growth & development, Fungi drug effects, Fungi growth & development

Abstract

Microbial attachment onto biomedical devices and implants leads to biofilm formation and infection; such biofilms can be bacterial, fungal, or mixed. In the past 15 years, there has been an increasing research effort into antimicrobial surfaces but the great majority of these publications present research on bacteria, with some reports also testing resistance to fungi. Very few studies have focused exclusively on antifungal surfaces. However, with increasing recognition of the importance of fungal infections to human health, particularly related to infections at biomaterials, it would seem that the interest in antifungal surfaces is disproportionately low. In studies of both bacteria and fungi, fungi tend to be the minor focus with hypothesized antibacterial mechanisms of action often generalized to also explain the antifungal effect. Yet bacteria and fungi represent two Distinct biological Domains and possess substantially different cellular physiology and structure. Thus it is questionable whether these generalizations are valid. Here we review the scientific literature focusing on surface coatings prepared with antifungal agents covalently attached to the biomaterial surface. We present a critical analysis of generalizations and their evidence. This review should be of interest to researchers of "antimicrobial" surfaces by addressing specific issues that are key to designing and understanding antifungal biomaterials surfaces and their putative mechanisms of action., (© 2013.)

Published

2014

28. Surface grafting of electrospun fibers using ATRP and RAFT for the control of biointerfacial interactions.

Author

Ameringer T, Ercole F, Tsang KM, Coad BR, Hou X, Rodda A, Nisbet DR, Thissen H, Evans RA, Meagher L, and Forsythe JS

Subjects

Polymerization, Surface Properties, Biocompatible Materials chemistry, Methacrylates chemistry, Polyethylene Glycols chemistry, Polymers chemistry

Abstract

Background: The ability to present signalling molecules within a low fouling 3D environment that mimics the extracellular matrix is an important goal for a range of biomedical applications, both in vitro and in vivo. Cell responses can be triggered by non-specific protein interactions occurring on the surface of a biomaterial, which is an undesirable process when studying specific receptor-ligand interactions. It is therefore useful to present specific ligands of interest to cell surface receptors in a 3D environment that minimizes non-specific interactions with biomolecules, such as proteins., Method: In this study, surface-initiated atom transfer radical polymerization (SI-ATRP) of poly(ethylene glycol)-based monomers was carried out from the surface of electrospun fibers composed of a styrene/vinylbenzyl chloride copolymer. Surface initiated radical addition-fragmentation chain transfer (SI-RAFT) polymerisation was also carried out to generate bottle brush copolymer coatings consisting of poly(acrylic acid) and poly(acrylamide). These were grown from surface trithiocarbonate groups generated from the chloromethyl styrene moieties existing in the original synthesised polymer. XPS was used to characterise the surface composition of the fibers after grafting and after coupling with fluorine functional XPS labels., Results: Bottle brush type coatings were able to be produced by ATRP which consisted of poly(ethylene glycol) methacrylate and a terminal alkyne-functionalised monomer. The ATRP coatings showed reduced non-specific protein adsorption, as a result of effective PEG incorporation and pendant alkynes groups existing as part of the brushes allowed for further conjugation of via azide-alkyne Huisgen 1,3-dipolar cycloaddition. In the case of RAFT, carboxylic acid moieties were effectively coupled to an amine label via amide bond formation. In each case XPS analysis demonstrated that covalent immobilisation had effectively taken place., Conclusion: Overall, the studies presented an effective platform for the preparation of 3D scaffolds which contain effective conjugation sites for attachment of specific bioactive signals of interest, as well as actively reducing non-specific protein interactions.

Published

2013

29. Functionality of proteins bound to plasma polymer surfaces.

Author

Coad BR, Scholz T, Vasilev K, Hayball JD, Short RD, and Griesser HJ

Abstract

The deposition of a thin film layer by plasma polymerization enables the surface functionalization of a wide range of substrate materials for biointerfacial interactions. Plasma polymers can surface-bind proteins specifically via covalent linkages or nonspecifically through other irreversible adsorption mechanisms; key questions are whether covalent chemisorption has indeed occurred, and whether the protein retains functionality. Here the mode of surface binding of streptavidin and the biotin binding functionality of the bound streptavidin layer are studied on plasma polymer (pp) surfaces deposited using propionaldehyde and ethanol that were plasma polymerized at different powers (P) to investigate possible mechanisms for protein binding to a range of different surface chemistries. As expected, with pp surfaces composed principally of aldehyde groups, protein conjugation appears to be specific (chemisorption) allowing the immobilization of streptavidin (SAV) molecules retaining the ability to bind biotinylated probes. To contrast with this, we present the first study of protein adsorption to ethanol pp surfaces prepared at different P. This provides an investigation into retention of the hydroxyl functionality in the pp at low P and its effect on protein adsorption. Adsorption of human serum albumin (HSA) to ethanol pp was similar to that on propionaldehyde pp except at low P (5 W) where hydroxyl group retention and hydration presumably has a role in reducing protein adsorption. Although we observed SAV adsorption to ethanol pp surfaces at all P, interestingly, the protein lost its ability to bind biotinylated probes. Thus we suggest that irreversible, nonspecific adsorption of protein on ethanol pp surfaces results in apparent protein denaturation despite the hydrophilic nature of the ethanol pp surface. We conclude by making inferences between the pp structure as measured by X-ray photoelectron spectroscopy (XPS) and the related protein adsorption mechanisms.

Published

2012

30. Substrate-independent method for growing and modulating the density of polymer brushes from surfaces by ATRP.

Author

Coad BR, Lu Y, Glattauer V, and Meagher L

Abstract

We describe a method for grafting PEG-based polymer chains of variable surface density using a substrate independent approach, allowing grafting from virtually any material substrate. The approach relies upon initial coupling of a macroinitiator to plasma polymer treated surfaces. The macroinitiator is a novel random terpolymer containing ATRP initiator residues, strongly negatively charged groups, and carboxylic acid moieties that facilitate covalent surface anchoring. Surface-initiated ATRP (SI-ATRP) using polyethylene glycol methyl ether methacrylate (PEGMA) at different concentrations led to grafted surfaces of controlled thickness in either the "brush" or "mushroom" morphology, which was controlled by the abundance of initiator residues in the macroinitiator. Grafted polymer layer structure was investigated via direct interaction force measurements using colloid probe atomic force microscopy (AFM). Equilibrium, hydrated graft layer thicknesses inferred from the highly repulsive AFM force data suggest that the polymer brush graft layer contained polymer chains which were fully stretched. Since the degree of stretching resulted in layer thicknesses approaching the polymer contour length, the polymer brushes studied must be very close to maximum graft density. Grafted layers where the polymer molecules were in the mushroom regime resulted in much thinner layers but the chains had greater chain entropic freedom as indicated by strongly attractive bridging interactions between tethered chains and the silica colloid probe. Use of this experimental methodology would be suitable for preparing grafted polymer layers of a preferred density free from substrate-specific linking chemistries.

Published

2012

31. Immobilized streptavidin gradients as bioconjugation platforms.

Author

Coad BR, Vasilev K, Diener KR, Hayball JD, Short RD, and Griesser HJ

Subjects

Biotinylation, Humans, Serum Albumin chemistry, Surface Properties, Biotin chemistry, Polymers chemistry, Streptavidin chemistry

Abstract

Surface density gradients of streptavidin (SAV) were created on solid surfaces and demonstrated functionality as a bioconjugation platform. The surface density of immobilized streptavidin steadily increased in one dimension from 0 to 235 ng cm(-2) over a distance of 10 mm. The density of coupled protein was controlled by its immobilization onto a polymer surface bearing a gradient of aldehyde group density, onto which SAV was covalently linked using spontaneous imine bond formation between surface aldehyde functional groups and primary amine groups on the protein. As a control, human serum albumin was immobilized in the same manner. The gradient density of aldehyde groups was created using a method of simultaneous plasma copolymerization of ethanol and propionaldehyde. Control over the surface density of aldehyde groups was achieved by manipulating the flow rates of these vapors while moving a mask across substrates during plasma discharge. Immobilized SAV was able to bind biotinylated probes, indicating that the protein retained its functionality after being immobilized. This plasma polymerization technique conveniently allows virtually any substrate to be equipped with tunable protein gradients and provides a widely applicable method for bioconjugation to study effects arising from controllable surface densities of proteins.

Published

2012

32. A substrate-independent method for surface grafting polymer layers by atom transfer radical polymerization: reduction of protein adsorption.

Author

Coad BR, Lu Y, and Meagher L

Subjects

Acrylamides chemical synthesis, Acrylamides chemistry, Adsorption, Animals, Chromatography, Gel, Europium chemistry, Humans, Photoelectron Spectroscopy, Quartz Crystal Microbalance Techniques, Silicon chemistry, Solutions, Surface Properties, Materials Testing methods, Polymerization, Polymers chemical synthesis, Polymers chemistry, Serum Albumin chemistry

Abstract

A general method for producing low-fouling biomaterials on any surface by surface-initiated grafting of polymer brushes is presented. Our procedure uses radiofrequency glow discharge thin film deposition followed by macro-initiator coupling and then surface-initiated atom transfer radical polymerization (SI-ATRP) to prepare neutral polymer brushes on planar substrates. Coatings were produced on substrates with variable interfacial composition and mechanical properties such as hard inorganic/metal substrates (silicon and gold) or flexible (perfluorinated poly(ethylene-co-propylene) film) and rigid (microtitre plates) polymeric materials. First, surfaces were functionalized via deposition of an allylamine plasma polymer thin film followed by covalent coupling of a macro-initiator composed partly of ATRP initiator groups. Successful grafting of a hydrophilic polymer layer was achieved by SI-ATRP of N,N'-dimethylacrylamide in aqueous media at room temperature. We exemplified how this method could be used to create surface coatings with significantly reduced protein adsorption on different material substrates. Protein binding experiments using labelled human serum albumin on grafted materials resulted in quantitative evidence for low-fouling compared to control surfaces., (Crown Copyright © 2011. Published by Elsevier Ltd. All rights reserved.)

Published

2012

33. Synthesis of novel size exclusion chromatography support by surface initiated aqueous atom transfer radical polymerization.

Author

Coad BR, Kizhakkedathu JN, Haynes CA, and Brooks DE

Subjects

Catalysis, Copper chemistry, Molecular Structure, Molecular Weight, Silicon chemistry, Spectroscopy, Fourier Transform Infrared, Thermodynamics, Trientine analogs & derivatives, Trientine chemistry, Acrylamides chemical synthesis, Chromatography, Gel methods, Free Radicals chemistry, Water chemistry

Abstract

We report the use of aqueous surface-initiated atom transfer radical polymerization (SI-ATRP) to grow polymer brushes from a "gigaporous" polymeric chromatography support for use as a novel size exclusion chromatography medium. Poly(N,N-dimethylacrylamide) (PDMA) was grown from hydrolyzable surface initiators via SI-ATRP catalyzed by 1,1,4,7,10,10-hexamethyltriethylenetetramine (HMTETA)/CuCl. Grafted polymer was characterized semiquantitatively by ATR-FTIR and also cleaved and quantitatively characterized for mass, molecular weight, and polydispersity via analytical SEC/MALLS. The synthesis provides control over graft density and allows the creation of dense brushes. Incorporation of negative surface charge was found to be crucial for improving the initiation efficiency. As polymer molecular weight and density could be controlled through reaction conditions, the resulting low-polydispersity grafted polymer brush medium is shown to be suitable for use as a customizable size exclusion chromatography medium for investigating the principals of entropic interaction chromatography. All packed media investigated showed size-dependent partitioning of solutes, even for low graft density systems. Increasing the molecular weight of the grafts allowed solutes more access to the volume fraction in the column available for partitioning. Compared to low graft density media, increased graft density caused eluted solute probes to be retained less within the column and allowed for greater size discrimination of probes whose molecular weights were less than 10(4) kDa.

Published

2007

34. The influence of grafted polymer architecture and fluid hydrodynamics on protein separation by entropic interaction chromatography.

Author

Coad BR, Steels BM, Kizhakkedathu JN, Brooks DE, and Haynes CA

Subjects

Entropy, Models, Chemical, Chromatography, Gel methods, Liquid Crystals chemistry, Polymers chemistry, Proteins chemistry, Proteins isolation & purification

Abstract

Entropic interaction chromatography (EIC) provides efficient size-based separation of protein mixtures through the entropy change associated with solute partitioning into a layer of hydrophilic homopolymer that has been end-grafted within the pores of a macroporous chromatography support. In this work, surface-initiated atom-transfer radical polymerization (ATRP) is used to prepare a library of EIC stationary phases covering a wide range of grafted-chain densities and molecular weights. Exhaustive chain cleavage and analysis by saponification and GPC-MALLS, respectively, show that the new ATRP synthesis procedure allows for excellent control over graft molecular weight and polydispersity. The method is used to prepare high-density grafts (up to 0.164 +/- 0.005 chains/nm(2)) that extend the range of EIC applications to include efficient buffer-exchange and desalting of protein preparations. Reducing the graft density allows for greater partitioning of high molecular weight solutes, extending the linear range of the selectivity curve. Increasing graft molecular weight also alters selectivity, but more directly affects column capacity by increasing the volume of the grafted layer. Protein partitioning in high-density EIC columns is found to decrease with mobile-phase velocity (u). Although solute mass transfer resistances leading to an increase in plate height can explain this effect, pressure drop data across the column are indicative of weak convective flow through at least a fraction of the grafted architecture. Modeling of the grafted brush properties in the presence of solvent flow by subjecting a self-consistent-field theory representation of the brush to a viscous shear force predicts that the grafted chains will tilt and elongate in the direction of flow. The shear force may therefore act to reduce the number of conformations available to chains, increasing their rigidity without significantly altering the thickness of the grafted layer. A reduction in protein partitioning is then predicted when the dependence on u of the solute entropy loss is stronger than that of the grafted polymer, a condition met at high graft densities.

Published

2007

35. Entropic interaction chromatography: separating proteins on the basis of size using end-grafted polymer brushes.

Author

Pang P, Koska J, Coad BR, Brooks DE, and Haynes CA

Subjects

Computer Simulation, Particle Size, Acrylamides chemistry, Chromatography, Gel methods, Models, Chemical, Polymers chemistry, Proteins chemistry, Proteins isolation & purification

Abstract

Partitioning of a macromolecule into the interfacial volume occupied by a grafted polymer brush decreases the configurational entropy (DeltaSbrush(c)) of the terminally attached linear polymer chains due to a loss of free volume. Self-consistent field theory (SCF) calculations are used to show that DeltaSbrush(c) is a strong function of both the size (MWp) of the partitioning macromolecule and the depth of penetration into the brush volume. We further demonstrate that the strong dependence of DeltaSbrush(c) on MWp provides a novel and powerful platform, which we call entropic interaction chromatography (EIC), for efficiently separating mixtures of proteins on the basis of size. Two EIC columns, differing primarily in polymer grafting density, were prepared by growing a brush of poly(methoxyethyl acrylamide) chains on the surface of a wide-pore (1,000-A pores, 64-microm diameter rigid beads) resin (Toyopearl AF-650M) bearing surface aldehyde groups. Semipreparative 0.1-L columns packed with either EIC resin provide reduced-plate heights of 2 or less for efficient separation of globular protein mixtures over at least three molecular-weight decades. Protein partitioning within these wide-pore EIC columns is shown to be effectively modeled as a thermodynamically controlled process, allowing partition coefficients (K(P)) and elution chromatograms to be accurately predicted using a column model that combines SCF calculation of K(P) values with an equilibrium-dispersion type model of solute transport through the column. This model is used to explore the dependence of column separation efficiency on brush properties, predicting that optimal separation of proteins over a broad MWp range is achieved at low to moderate grafting densities and intermediate chain lengths., (Copyright (c) 2005 Wiley Periodicals, Inc.)

Published

2005