Microneedles from Fishscale-Nanocellulose Blends Using Low Temperature Mechanical Press Method

Fish scale biopolymer blended with nanocellulose crystals is used for production of microneedles applying mechanical press microfabrication and the effect of nanocellulose on microfabrication, water absorption, moisture stability and mechanical properties of the microneedles is reported. The result...

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Main Authors: Ololade Olatunji, Richard T. Olsson
Format: Article
Language:English
Published: MDPI AG 2015-09-01
Series:Pharmaceutics
Subjects:
Online Access:http://www.mdpi.com/1999-4923/7/4/363
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spelling doaj-83d6e230dbdb467b8e659e5050a034be2020-11-25T00:49:12ZengMDPI AGPharmaceutics1999-49232015-09-017436337810.3390/pharmaceutics7040363pharmaceutics7040363Microneedles from Fishscale-Nanocellulose Blends Using Low Temperature Mechanical Press MethodOlolade Olatunji0Richard T. Olsson1Chemical Engineering Department, University of Lagos, Akoka, Lagos, NigeriaFibre and Polymer Technology, School of Chemical Science and Engineering, KTH–Royal Institute of Technology, SE-100-44 Stockholm, SwedenFish scale biopolymer blended with nanocellulose crystals is used for production of microneedles applying mechanical press microfabrication and the effect of nanocellulose on microfabrication, water absorption, moisture stability and mechanical properties of the microneedles is reported. The results show that microneedles produced from the nanocellulose loaded fish scale biopolymer requires higher temperature for micromolding (80 ± 5 °C) than microneedles from only fish scale biopolymer, which were moldable at 50 ± 5 °C. The mechanical properties of the fish scale biopolymer-nanocellulose (FSBP-NC) films showed that the addition of nanocellulose (NC) resulted in lower elongation and higher tensile stress compared to fish scale biopolymer (FSBP) films. The nanocellulose also prevented dissolution of the needles and absorbed up to 300% and 234% its own weight in water (8% and 12% w/w NC/FSBP), whereas FSBP films dissolved completely within 1 min, Indicating that the FSBP-NC films can be used to produce microneedles with prolonged dissolution rate. FTIR spectrometry of the FSBP films was compared with the FSBP-NC films and the NC gels. The FTIR showed typical peaks for fish scale polymer and nanocellulose with evidence of interactions. SEM micrographs showed relatively good dispersion of NC in FSBP at both NC contents corresponding to 8% and 12% w/w NC/FSBP respectively.http://www.mdpi.com/1999-4923/7/4/363microneedlesnanoparticlescellulosefish scalebiopolymerdrug deliverybiomaterialsmicromolding
collection DOAJ
language English
format Article
sources DOAJ
author Ololade Olatunji
Richard T. Olsson
spellingShingle Ololade Olatunji
Richard T. Olsson
Microneedles from Fishscale-Nanocellulose Blends Using Low Temperature Mechanical Press Method
Pharmaceutics
microneedles
nanoparticles
cellulose
fish scale
biopolymer
drug delivery
biomaterials
micromolding
author_facet Ololade Olatunji
Richard T. Olsson
author_sort Ololade Olatunji
title Microneedles from Fishscale-Nanocellulose Blends Using Low Temperature Mechanical Press Method
title_short Microneedles from Fishscale-Nanocellulose Blends Using Low Temperature Mechanical Press Method
title_full Microneedles from Fishscale-Nanocellulose Blends Using Low Temperature Mechanical Press Method
title_fullStr Microneedles from Fishscale-Nanocellulose Blends Using Low Temperature Mechanical Press Method
title_full_unstemmed Microneedles from Fishscale-Nanocellulose Blends Using Low Temperature Mechanical Press Method
title_sort microneedles from fishscale-nanocellulose blends using low temperature mechanical press method
publisher MDPI AG
series Pharmaceutics
issn 1999-4923
publishDate 2015-09-01
description Fish scale biopolymer blended with nanocellulose crystals is used for production of microneedles applying mechanical press microfabrication and the effect of nanocellulose on microfabrication, water absorption, moisture stability and mechanical properties of the microneedles is reported. The results show that microneedles produced from the nanocellulose loaded fish scale biopolymer requires higher temperature for micromolding (80 ± 5 °C) than microneedles from only fish scale biopolymer, which were moldable at 50 ± 5 °C. The mechanical properties of the fish scale biopolymer-nanocellulose (FSBP-NC) films showed that the addition of nanocellulose (NC) resulted in lower elongation and higher tensile stress compared to fish scale biopolymer (FSBP) films. The nanocellulose also prevented dissolution of the needles and absorbed up to 300% and 234% its own weight in water (8% and 12% w/w NC/FSBP), whereas FSBP films dissolved completely within 1 min, Indicating that the FSBP-NC films can be used to produce microneedles with prolonged dissolution rate. FTIR spectrometry of the FSBP films was compared with the FSBP-NC films and the NC gels. The FTIR showed typical peaks for fish scale polymer and nanocellulose with evidence of interactions. SEM micrographs showed relatively good dispersion of NC in FSBP at both NC contents corresponding to 8% and 12% w/w NC/FSBP respectively.
topic microneedles
nanoparticles
cellulose
fish scale
biopolymer
drug delivery
biomaterials
micromolding
url http://www.mdpi.com/1999-4923/7/4/363
work_keys_str_mv AT ololadeolatunji microneedlesfromfishscalenanocelluloseblendsusinglowtemperaturemechanicalpressmethod
AT richardtolsson microneedlesfromfishscalenanocelluloseblendsusinglowtemperaturemechanicalpressmethod
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