Suitability of PLLA as piezoelectric substrates for tissue engineering evidenced by microscopy techniques

N. B. Barroca; A. L. Daniel-da-Silva; P. S. Gomes; M. H. R.  Fernandes; S. Lanceros-Méndez; P. Sharma; A. Gruverman; M. H. V. Fernandes; P. M. Vilarinho

doi:10.1017/S1431927612012974

Suitability of PLLA as piezoelectric substrates for tissue engineering evidenced by microscopy techniques

N. B. Barroca, A. L. Daniel-da-Silva, P. S. Gomes, M. H. R. Fernandes, S. Lanceros-Méndez, P. Sharma, A. Gruverman, M. H. V. Fernandes, P. M. Vilarinho

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Abstract

Since the discovery of the piezoelectric character of bone, the suitability of some piezoelectric materials have been studied for bone repair; they are thought to act like transducers converting the mechanical energy of skeletal deformation in electrical stimuli capable of controlling osteogenic growth. The mechanisms underlying this process are far from being understood and systematic studies at a local scale are required. Atomic force microscopy (AFM) is a unique way to observe phenomena at the nanoscale and liquid imaging provides a unique tool to assess biological phenomena at the nanoscale. So in this study, aiming at a better understanding of the role of piezoelectricity in the osteogenic growth, the interaction between a poled piezoelectric material, in this case poly (L-lactic) acid and an adhesion promoting protein, the fibronectin, and bone-like cells is evaluated by scanning probe microscopy and confocal laser scanning microscopy (CLSM).

Original language	English
Pages (from-to)	63-64
Number of pages	2
Journal	Microscopy and Microanalysis
Volume	18
Issue number	Suppl 5
DOIs	https://doi.org/10.1017/S1431927612012974
Publication status	Published - Aug 2012
Externally published	Yes

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Barroca, N. B., Daniel-da-Silva, A. L., Gomes, P. S., Fernandes, M. H. R., Lanceros-Méndez, S., Sharma, P., Gruverman, A., Fernandes, M. H. V., & Vilarinho, P. M. (2012). Suitability of PLLA as piezoelectric substrates for tissue engineering evidenced by microscopy techniques. Microscopy and Microanalysis, 18(Suppl 5), 63-64. https://doi.org/10.1017/S1431927612012974

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title = "Suitability of PLLA as piezoelectric substrates for tissue engineering evidenced by microscopy techniques",

abstract = "Since the discovery of the piezoelectric character of bone, the suitability of some piezoelectric materials have been studied for bone repair; they are thought to act like transducers converting the mechanical energy of skeletal deformation in electrical stimuli capable of controlling osteogenic growth. The mechanisms underlying this process are far from being understood and systematic studies at a local scale are required. Atomic force microscopy (AFM) is a unique way to observe phenomena at the nanoscale and liquid imaging provides a unique tool to assess biological phenomena at the nanoscale. So in this study, aiming at a better understanding of the role of piezoelectricity in the osteogenic growth, the interaction between a poled piezoelectric material, in this case poly (L-lactic) acid and an adhesion promoting protein, the fibronectin, and bone-like cells is evaluated by scanning probe microscopy and confocal laser scanning microscopy (CLSM).",

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AU - Barroca, N. B.

AU - Daniel-da-Silva, A. L.

AU - Gomes, P. S.

AU - Fernandes, M. H. R.

AU - Lanceros-Méndez, S.

AU - Sharma, P.

AU - Gruverman, A.

AU - Fernandes, M. H. V.

AU - Vilarinho, P. M.

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AB - Since the discovery of the piezoelectric character of bone, the suitability of some piezoelectric materials have been studied for bone repair; they are thought to act like transducers converting the mechanical energy of skeletal deformation in electrical stimuli capable of controlling osteogenic growth. The mechanisms underlying this process are far from being understood and systematic studies at a local scale are required. Atomic force microscopy (AFM) is a unique way to observe phenomena at the nanoscale and liquid imaging provides a unique tool to assess biological phenomena at the nanoscale. So in this study, aiming at a better understanding of the role of piezoelectricity in the osteogenic growth, the interaction between a poled piezoelectric material, in this case poly (L-lactic) acid and an adhesion promoting protein, the fibronectin, and bone-like cells is evaluated by scanning probe microscopy and confocal laser scanning microscopy (CLSM).

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Suitability of PLLA as piezoelectric substrates for tissue engineering evidenced by microscopy techniques

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