GAKTpore: stereological characterisation methods for porous foams in biomedical applications

Gareth Sheppard; Karl Tassenberg; Bogdan Nenchev; Joel Strickland; Ramy Mesalam; Jennifer Shepherd; Hugo Williams

doi:10.3390/ma14051269

GAKTpore: stereological characterisation methods for porous foams in biomedical applications

Gareth Sheppard^*, Karl Tassenberg, Bogdan Nenchev, Joel Strickland, Ramy Mesalam, Jennifer Shepherd, Hugo Williams

^*Corresponding author for this work

Metallurgy and Materials

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

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Abstract

In tissue engineering, scaffolds are a key component that possess a highly elaborate pore structure. Careful characterisation of such porous structures enables the prediction of a variety of large-scale biological responses. In this work, a rapid, efficient, and accurate methodology for 2D bulk porous structure analysis is proposed. The algorithm, “GAKTpore”, creates a morphology map allowing quantification and visualisation of spatial feature variation. The software achieves 99.6% and 99.1% mean accuracy for pore diameter and shape factor identification, respectively. There are two main algorithm novelties within this work: (1) feature-dependant homogeneity map; (2) a new waviness function providing insights into the convexity/concavity of pores, important for understanding the influence on cell adhesion and proliferation. The algorithm is applied to foam structures, providing a full characterisation of a 10 mm diameter SEM micrograph (14,784 × 14,915 px) with 190,249 pores in ∼ 9 min and has elucidated new insights into collagen scaffold formation by relating microstructural formation to the bulk formation environment. This novel porosity characterisation algorithm demonstrates its versatility, where accuracy, repeatability, and time are paramount. Thus, GAKTpore offers enormous potential to optimise and enhance scaffolds within tissue engineering.

Original language	English
Article number	1269
Pages (from-to)	1-19
Number of pages	19
Journal	Materials
Volume	14
Issue number	5
DOIs	https://doi.org/10.3390/ma14051269
Publication status	Published - 7 Mar 2021

Bibliographical note

Funding: This research was funded by the UK Engineering and Physical Sciences Research Council (EPRSC), grant number: EP/L016206/1.

Acknowledgments: G.S., K.T., B.N. and J.S. (Joel Strickland) gratefully acknowledge the support from the Centre for Doctoral Training in Innovative Metal Processing (IMPaCT) and the Mechanics of Material Advanced Microscopy Centre at the University of Leicester.

Publisher Copyright:
© 2021 by the authors. Licensee MDPI, Basel, Switzerland.

Keywords

2D biomaterials
Homogeneity
Metal foams
Pore analysis
Porous materials
Scaffold
Space holders
Tissue engineering

ASJC Scopus subject areas

General Materials Science
Condensed Matter Physics

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SheppardG2021GAKTporeFinal published version, 10.7 MBLicence: Creative Commons: Attribution (CC BY)

Cite this

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title = "GAKTpore: stereological characterisation methods for porous foams in biomedical applications",

abstract = "In tissue engineering, scaffolds are a key component that possess a highly elaborate pore structure. Careful characterisation of such porous structures enables the prediction of a variety of large-scale biological responses. In this work, a rapid, efficient, and accurate methodology for 2D bulk porous structure analysis is proposed. The algorithm, “GAKTpore”, creates a morphology map allowing quantification and visualisation of spatial feature variation. The software achieves 99.6% and 99.1% mean accuracy for pore diameter and shape factor identification, respectively. There are two main algorithm novelties within this work: (1) feature-dependant homogeneity map; (2) a new waviness function providing insights into the convexity/concavity of pores, important for understanding the influence on cell adhesion and proliferation. The algorithm is applied to foam structures, providing a full characterisation of a 10 mm diameter SEM micrograph (14,784 × 14,915 px) with 190,249 pores in ∼ 9 min and has elucidated new insights into collagen scaffold formation by relating microstructural formation to the bulk formation environment. This novel porosity characterisation algorithm demonstrates its versatility, where accuracy, repeatability, and time are paramount. Thus, GAKTpore offers enormous potential to optimise and enhance scaffolds within tissue engineering.",

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note = "Funding: This research was funded by the UK Engineering and Physical Sciences Research Council (EPRSC), grant number: EP/L016206/1. Acknowledgments: G.S., K.T., B.N. and J.S. (Joel Strickland) gratefully acknowledge the support from the Centre for Doctoral Training in Innovative Metal Processing (IMPaCT) and the Mechanics of Material Advanced Microscopy Centre at the University of Leicester. Publisher Copyright: {\textcopyright} 2021 by the authors. Licensee MDPI, Basel, Switzerland.",

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AU - Mesalam, Ramy

AU - Shepherd, Jennifer

AU - Williams, Hugo

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N2 - In tissue engineering, scaffolds are a key component that possess a highly elaborate pore structure. Careful characterisation of such porous structures enables the prediction of a variety of large-scale biological responses. In this work, a rapid, efficient, and accurate methodology for 2D bulk porous structure analysis is proposed. The algorithm, “GAKTpore”, creates a morphology map allowing quantification and visualisation of spatial feature variation. The software achieves 99.6% and 99.1% mean accuracy for pore diameter and shape factor identification, respectively. There are two main algorithm novelties within this work: (1) feature-dependant homogeneity map; (2) a new waviness function providing insights into the convexity/concavity of pores, important for understanding the influence on cell adhesion and proliferation. The algorithm is applied to foam structures, providing a full characterisation of a 10 mm diameter SEM micrograph (14,784 × 14,915 px) with 190,249 pores in ∼ 9 min and has elucidated new insights into collagen scaffold formation by relating microstructural formation to the bulk formation environment. This novel porosity characterisation algorithm demonstrates its versatility, where accuracy, repeatability, and time are paramount. Thus, GAKTpore offers enormous potential to optimise and enhance scaffolds within tissue engineering.

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GAKTpore: stereological characterisation methods for porous foams in biomedical applications

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

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