Topological characterization of a bacterial cellulose-acrylic acid polymeric matrix

This paper focuses on the micro- and nano-topological organization of a hydrogel, constituted by a mixture of bacterial cellulose and acrylic acid, and intended for biomedical applications. The presence of acrylic acid promotes the formation of two interpenetrated continuous phases: the primary &quo...

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Main Authors: N., Halib,, M. C. I., Amin,, I., Ahmad,, R., Lapasin,, M., Grassi,, M., Abrami,, S., Fiorentino,, R., Farra,, F., Musiani,
Format: Article
Language:en_US
Published: Elsevier Science Bv 2015
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Online Access:http://ddms.usim.edu.my/handle/123456789/8459
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spelling my.usim-84592015-12-29T08:30:50Z Topological characterization of a bacterial cellulose-acrylic acid polymeric matrix N., Halib, M. C. I., Amin, I., Ahmad, R., Lapasin, M., Grassi, M., Abrami, S., Fiorentino, R., Farra, F., Musiani, Low field NMR Rheology Drug release Mesh-size Porous gels This paper focuses on the micro- and nano-topological organization of a hydrogel, constituted by a mixture of bacterial cellulose and acrylic acid, and intended for biomedical applications. The presence of acrylic acid promotes the formation of two interpenetrated continuous phases: the primary "pores phase" (PP) containing only water and the secondary "polymeric network phase" (PNP) constituted by the polymeric network swollen by the water. Low field Nuclear Magnetic Resonance (LF NMR), rheology, Scanning Electron Microscopy (SEM) and release tests were used to determine the characteristics of the two phases. In particular, we found that this system is a strong hydrogel constituted by 81% (v/v) of PP phase the remaining part being occupied by the PNP phase. Pores diameters span in the range 10-100 pm, the majority of them (85%) falling in the range 30-90 mu m. The high PP phase tortuosity indicates that big pores are not directly connected to each other, but their connection is realized by a series of interconnected small pores that rend the drug path tortuous. The PNP is characterized by a polymer volume fraction around 0.73 while mesh size is around 3 nm. The theoretical interpretation of the experimental data coming from the techniques panel adopted, yielded to the micro- and nano-organization of our hydrogel. (C) 2014 Elsevier B.V. All rights reserved. 2015-06-19T06:46:35Z 2015-06-19T06:46:35Z 2014-01-01 Article 0928-0987 1879-0720 http://ddms.usim.edu.my/handle/123456789/8459 en_US Elsevier Science Bv
institution Universiti Sains Islam Malaysia
building USIM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universit Sains Islam i Malaysia
content_source USIM Institutional Repository
url_provider http://ddms.usim.edu.my/
language en_US
topic Low field NMR
Rheology
Drug release
Mesh-size
Porous gels
spellingShingle Low field NMR
Rheology
Drug release
Mesh-size
Porous gels
N., Halib,
M. C. I., Amin,
I., Ahmad,
R., Lapasin,
M., Grassi,
M., Abrami,
S., Fiorentino,
R., Farra,
F., Musiani,
Topological characterization of a bacterial cellulose-acrylic acid polymeric matrix
description This paper focuses on the micro- and nano-topological organization of a hydrogel, constituted by a mixture of bacterial cellulose and acrylic acid, and intended for biomedical applications. The presence of acrylic acid promotes the formation of two interpenetrated continuous phases: the primary "pores phase" (PP) containing only water and the secondary "polymeric network phase" (PNP) constituted by the polymeric network swollen by the water. Low field Nuclear Magnetic Resonance (LF NMR), rheology, Scanning Electron Microscopy (SEM) and release tests were used to determine the characteristics of the two phases. In particular, we found that this system is a strong hydrogel constituted by 81% (v/v) of PP phase the remaining part being occupied by the PNP phase. Pores diameters span in the range 10-100 pm, the majority of them (85%) falling in the range 30-90 mu m. The high PP phase tortuosity indicates that big pores are not directly connected to each other, but their connection is realized by a series of interconnected small pores that rend the drug path tortuous. The PNP is characterized by a polymer volume fraction around 0.73 while mesh size is around 3 nm. The theoretical interpretation of the experimental data coming from the techniques panel adopted, yielded to the micro- and nano-organization of our hydrogel. (C) 2014 Elsevier B.V. All rights reserved.
format Article
author N., Halib,
M. C. I., Amin,
I., Ahmad,
R., Lapasin,
M., Grassi,
M., Abrami,
S., Fiorentino,
R., Farra,
F., Musiani,
author_facet N., Halib,
M. C. I., Amin,
I., Ahmad,
R., Lapasin,
M., Grassi,
M., Abrami,
S., Fiorentino,
R., Farra,
F., Musiani,
author_sort N., Halib,
title Topological characterization of a bacterial cellulose-acrylic acid polymeric matrix
title_short Topological characterization of a bacterial cellulose-acrylic acid polymeric matrix
title_full Topological characterization of a bacterial cellulose-acrylic acid polymeric matrix
title_fullStr Topological characterization of a bacterial cellulose-acrylic acid polymeric matrix
title_full_unstemmed Topological characterization of a bacterial cellulose-acrylic acid polymeric matrix
title_sort topological characterization of a bacterial cellulose-acrylic acid polymeric matrix
publisher Elsevier Science Bv
publishDate 2015
url http://ddms.usim.edu.my/handle/123456789/8459
_version_ 1645152421107728384
score 13.222552