Optimised production of multifunctional microfibres by microfluidic chip technology for tissue engineering applications
Optimised production of multifunctional microfibres by microfluidic chip technology for tissue engineering applications
This paper describes a method for the production of alginate microfibres using glass-based microfluidic chips fabricated by a photolithography-wet etching procedure. The main focus of the work is the fabrication of a cell containing multifunctional microfibres which have great potential for applications in drug release formulations and tissue engineering scaffolds (to guide the regeneration of tissues in predefined sizes and shapes) providing cell structural support and immunoisolation. The key parameters, which critically influence the formation of microfibres and their geometries, were identified by a classical intuitive approach COST (Changing One Separate factor a Time). In particular, their effects on the microfibre diameter were investigated, which are directly associated with their functionalities relating to the implantation site, the nutrient availability and diffusion/transport of oxygen, essential nutrients, growth factors, metabolic waste and secretory products. The interplay between the alginate solution concentration, pumping rate and gelling bath concentration in controlling the diameter of the produced microfibres was investigated with a statistical approach by means of a “design of the experiments” (DoEs) optimization and screening. Finally, the processing impacts on cell viability, the cellular effect of wall thickness consistency and the spatial distribution of cells within the alginate microfibre were examined. We provide an approach for the production of alginate microfibres with controlled shape and content, which could be further developed for scaling up and working towards FDA approval.
1776-1785
Mazzitelli, Stefania
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Capretto, Lorenzo
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Carugo, Dario
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Zhang, Xunli
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Piva, Roberta
bbcb7277-0019-4a22-ab93-bd3249dcf3df
Nastruzzi, Claudio
fa760f44-1546-4aa2-838d-242a908ea463
2011
Mazzitelli, Stefania
d9923ab4-b354-4b9e-87d1-f67d86e1a8dc
Capretto, Lorenzo
0f3586b5-1560-49c1-a76b-59e74ea600ef
Carugo, Dario
0a4be6cd-e309-4ed8-a620-20256ce01179
Zhang, Xunli
d7cf1181-3276-4da1-9150-e212b333abb1
Piva, Roberta
bbcb7277-0019-4a22-ab93-bd3249dcf3df
Nastruzzi, Claudio
fa760f44-1546-4aa2-838d-242a908ea463
Mazzitelli, Stefania, Capretto, Lorenzo, Carugo, Dario, Zhang, Xunli, Piva, Roberta and Nastruzzi, Claudio
(2011)
Optimised production of multifunctional microfibres by microfluidic chip technology for tissue engineering applications.
Lab on a Chip, 11, .
(doi:10.1039/c1lc20082h).
Abstract
This paper describes a method for the production of alginate microfibres using glass-based microfluidic chips fabricated by a photolithography-wet etching procedure. The main focus of the work is the fabrication of a cell containing multifunctional microfibres which have great potential for applications in drug release formulations and tissue engineering scaffolds (to guide the regeneration of tissues in predefined sizes and shapes) providing cell structural support and immunoisolation. The key parameters, which critically influence the formation of microfibres and their geometries, were identified by a classical intuitive approach COST (Changing One Separate factor a Time). In particular, their effects on the microfibre diameter were investigated, which are directly associated with their functionalities relating to the implantation site, the nutrient availability and diffusion/transport of oxygen, essential nutrients, growth factors, metabolic waste and secretory products. The interplay between the alginate solution concentration, pumping rate and gelling bath concentration in controlling the diameter of the produced microfibres was investigated with a statistical approach by means of a “design of the experiments” (DoEs) optimization and screening. Finally, the processing impacts on cell viability, the cellular effect of wall thickness consistency and the spatial distribution of cells within the alginate microfibre were examined. We provide an approach for the production of alginate microfibres with controlled shape and content, which could be further developed for scaling up and working towards FDA approval.
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Published date: 2011
Organisations:
Bioengineering Sciences
Identifiers
Local EPrints ID: 183255
URI: http://eprints.soton.ac.uk/id/eprint/183255
ISSN: 1473-0197
PURE UUID: 451ed1b7-c63f-410d-9b13-0d61cb028d10
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Date deposited: 03 May 2011 08:57
Last modified: 15 Mar 2024 03:28
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Author:
Stefania Mazzitelli
Author:
Lorenzo Capretto
Author:
Roberta Piva
Author:
Claudio Nastruzzi
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