Your search keyword '"Wågberg, Lars"' showing total 3 results

1. Bacterial-growth inhibiting properties of multilayers formed with modified polyvinylamine

Author

Illergård, Josefin, Wågberg, Lars, and Ek, Monica

Subjects

*BACTERIAL growth, *MULTILAYERED thin films, *AMINES, *LEACHING, *ANTIBACTERIAL agents, *BACTERIAL cell surfaces, *HYDROPHOBIC surfaces, *POLYELECTROLYTES

Abstract

Abstract: New methods are needed to fight antibiotic-resistant bacteria. One alternative that has been proposed is non-leaching, permanently antibacterial surfaces. In this study, we test multilayers formed with antibacterial cationic polyvinylamine (PVAm) and polyacrylic acid (PAA) in a growth-inhibition assay. Both hydrophobically modified and native PVAm were investigated. Multilayers did reduce the bacterial growth, as compared to single layers. However, the sampling time in the assay was critical, as the treated surface area is a capacity-limiting factor. After 2h incubation, a maximal growth inhibition of more than 99% was achieved with multilayers. In contrast, after 8h we observed a maximal growth-inhibition of 40%. At longer incubation times, the surface becomes saturated, which explains the observed time-dependent effectiveness. The polymers giving multilayers with the strongest growth-inhibiting properties were native PVAm and PVAm modified with C8, which also were the polymers with highest charge density. We therefore conclude that this effect is mainly an electrostatically driven process. Viability staining using a fluorescent stain showed a high viability rate of the adhered bacteria. The multilayers are therefore more bacteriostatic than antibacterial. [Copyright &y& Elsevier]

Published

2011

2. Bacterial adhesion to polyvinylamine-modified nanocellulose films.

Author

Henschen, Jonatan, Larsson, Per A., Illergård, Josefin, Ek, Monica, and Wågberg, Lars

Subjects

*POLYACRYLIC acid, *POLYELECTROLYTES, *CELLULOSE, *BACTERIAL adhesion, *AMINES

Abstract

Cellulose nanofibril (CNF) materials have been widely studied in recent years and are suggested for a wide range of applications, e.g., medical and hygiene products. One property not very well studied is the interaction between bacteria and these materials and how this can be controlled. The current work studies how bacteria adhere to different CNF materials modified with polyelectrolyte multilayers. The tested materials were TEMPO-oxidized to have different surface charges, periodate-oxidized to vary the water interaction and hot-pressed to alter the surface structure. Then, multilayers were constructed using polyvinylamine (PVAm) and polyacrylic acid. Both the material surface charge and water interaction affect the amount of polymer adsorbed to the surfaces. Increasing the surface charge decreases the adsorption after the first PVAm layer, possibly due to conformational changes. Periodate-oxidized and crosslinked films have low initial polymer adsorptions; the decreased swelling prevents polymer diffusion into the CNF micropore structure. Microscopic analysis after incubating the samples with bacterial suspensions show that only the materials with the lowest surface charge enable bacteria to adhere to the surface because, when adsorbing up to 5 layers PVAm/PAA, the increased anionic surface charge appears to decrease the net surface charge. Both the amounts of PVAm and PAA influence the net surface charge and thus the bacterial adhesion. The structure generated by the hot-pressing of the films also strongly increases the number of bacteria adhering to the surfaces. These results indicate that the bacterial adhesion to CNF materials can be tailored using polyelectrolyte multilayers on different CNF substrates. [ABSTRACT FROM AUTHOR]

Published

2017

3. Contact-active antibacterial aerogels from cellulose nanofibrils.

Author

Henschen, Jonatan, Illergård, Josefin, Larsson, Per A., Ek, Monica, and Wågberg, Lars

Subjects

*AEROGELS, *ANTIBACTERIAL agents, *CELLULOSE nanocrystals, *POLYACRYLIC acid, *PHARMACODYNAMICS, *SURFACE area

Abstract

The use of cellulose aerogels as antibacterial materials has been investigated by applying a contact-active layer-by-layer modification to the aerogel surface. Studying the adsorption of multilayers of polyvinylamine (PVAm) and polyacrylic acid to aerogels comprising crosslinked cellulose nanofibrils and monitoring the subsequent bacterial adhesion revealed that up to 26 mg PVAm g aerogel −1 was adsorbed without noticeably affecting the aerogel structure. The antibacterial effect was tested by measuring the reduction of viable bacteria in solution when the aerogels were present. The results show that >99.9% of the bacteria adhered to the surface of the aerogels. Microscopy further showed adherence of bacteria to the surfaces of the modified aerogels. These results indicate that it is possible to create materials with three-dimensional cellulose structures that adsorb bacteria with very high efficiency utilizing the high specific surface area of the aerogels in combination with their open structure. [ABSTRACT FROM AUTHOR]

Published

2016