Neural network analysis identifies scaffold properties necessary for in vitro chondrogenesis in elastin-like polypeptide biopolymer scaffolds.

dc.contributor.author

Nettles, Dana L

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Haider, Mansoor A

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Chilkoti, Ashutosh

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Setton, Lori A

dc.coverage.spatial

United States

dc.date.accessioned

2011-04-15T16:46:35Z

dc.date.issued

2010-01

dc.description.abstract

The successful design of biomaterial scaffolds for articular cartilage tissue engineering requires an understanding of the impact of combinations of material formulation parameters on diverse and competing functional outcomes of biomaterial performance. This study sought to explore the use of a type of unsupervised artificial network, a self-organizing map, to identify relationships between scaffold formulation parameters (crosslink density, molecular weight, and concentration) and 11 such outcomes (including mechanical properties, matrix accumulation, metabolite usage and production, and histological appearance) for scaffolds formed from crosslinked elastin-like polypeptide (ELP) hydrogels. The artificial neural network recognized patterns in functional outcomes and provided a set of relationships between ELP formulation parameters and measured outcomes. Mapping resulted in the best mean separation amongst neurons for mechanical properties and pointed to crosslink density as the strongest predictor of most outcomes, followed by ELP concentration. The map also grouped formulations together that simultaneously resulted in the highest values for matrix production, greatest changes in metabolite consumption or production, and highest histological scores, indicating that the network was able to recognize patterns amongst diverse measurement outcomes. These results demonstrated the utility of artificial neural network tools for recognizing relationships in systems with competing parameters, toward the goal of optimizing and accelerating the design of biomaterial scaffolds for articular cartilage tissue engineering.

dc.description.version

Version of Record

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https://www.ncbi.nlm.nih.gov/pubmed/19754250

dc.identifier.eissn

1937-335X

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https://hdl.handle.net/10161/3372

dc.language

eng

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en_US

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Mary Ann Liebert Inc

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Tissue Eng Part A

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10.1089/ten.tea.2009.0134

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Tissue Engineering Part a

dc.subject

Animals

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Cartilage

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Chondrogenesis

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Elastin

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Humans

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Hydrogels

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Neural Networks (Computer)

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Tissue Engineering

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Neural network analysis identifies scaffold properties necessary for in vitro chondrogenesis in elastin-like polypeptide biopolymer scaffolds.

dc.type

Journal article

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2010-1-0

duke.description.issue

1

duke.description.volume

16

pubs.author-url

https://www.ncbi.nlm.nih.gov/pubmed/19754250

pubs.begin-page

11

pubs.end-page

20

pubs.issue

1

pubs.organisational-group

Biomedical Engineering

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Chemistry

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Duke

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Duke Cancer Institute

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Duke Institute for Brain Sciences

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Institutes and Centers

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Institutes and Provost's Academic Units

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Pratt School of Engineering

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School of Medicine

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Trinity College of Arts & Sciences

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University Institutes and Centers

pubs.publication-status

Published

pubs.volume

16

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