Micro- and nanomechanical analysis of articular cartilage by indentation-type atomic force microscopy: validation with a gel-microfiber composite microscopy
Micro- and nanomechanical analysis of articular cartilage by indentation-type atomic force microscopy: validation with a gel-microfiber composite microscopy
As documented previously, articular cartilage exhibits a scale-dependent dynamic stiffness when probed by indentation-type atomic force microscopy (IT-AFM). In this study, a micrometer-size spherical tip revealed an unimodal stiffness distribution (which we refer to as microstiffness), whereas probing articular cartilage with a nanometer-size pyramidal tip resulted in a bimodal nanostiffness distribution. We concluded that indentation of the cartilage's soft proteoglycan (PG) gel gave rise to the lower nanostiffness peak, whereas deformation of its collagen fibrils yielded the higher nanostiffness peak. To test our hypothesis, we produced a gel-microfiber composite consisting of a chondroitin sulfate-containing agarose gel and a fibrillar poly(ethylene glycol)-terephthalate/poly(butylene)-terephthalate block copolymer. In striking analogy to articular cartilage, the microstiffness distribution of the synthetic composite was unimodal, whereas its nanostiffness exhibited a bimodal distribution. Also, similar to the case with cartilage, addition of the negatively charged chondroitin sulfate rendered the gel-microfiber composite's water content responsive to salt. When the ionic strength of the surrounding buffer solution increased from 0.15 to 2 M NaCl, the cartilage's microstiffness increased by 21%, whereas that of the synthetic biomaterial went up by 31%. When the nanostiffness was measured after the ionic strength was raised by the same amount, the cartilage's lower peak increased by 28%, whereas that of the synthetic biomaterial went up by 34%. Of interest, the higher peak values remained unchanged for both materials. Taken together, these results demonstrate that the nanoscale lower peak is a measure of the soft PG gel, and the nanoscale higher peak measures collagen fibril stiffness. In contrast, the micrometer-scale measurements fail to resolve separate stiffness values for the PG and collagen fibril moieties. Therefore, we propose to use nanostiffness as a new biomarker to analyze structure-function relationships in normal, diseased, and engineered cartilage.
2731-2740
Loparic, Marko
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Wirz, Dieter
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Daniels, A.U.
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Raiteri, Roberto
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VanLandingham, Mark R.
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Guex, Geraldine
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Martin, Ivan
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Aebi, Ueli
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Stolz, Martin
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2 June 2010
Loparic, Marko
4e68cec6-e997-4eae-af08-ba4548caebce
Wirz, Dieter
9b54711d-f9fc-4ba5-a0d2-916d7274efe6
Daniels, A.U.
79d2d48d-1aa7-4584-9924-5328ca4c8650
Raiteri, Roberto
6242d937-2e7f-4b42-a19e-320f9b420144
VanLandingham, Mark R.
caaf6166-9e41-458e-8d04-432bf00d57c3
Guex, Geraldine
7edc385a-618c-45eb-bd16-603665bc8884
Martin, Ivan
a6c0b810-3113-43cd-aa25-243a5f05364b
Aebi, Ueli
ea7e2491-b815-4ea3-a657-28e2e057f09f
Stolz, Martin
7bfa1d59-511d-471b-96ce-679b343b5d1d
Loparic, Marko, Wirz, Dieter, Daniels, A.U., Raiteri, Roberto, VanLandingham, Mark R., Guex, Geraldine, Martin, Ivan, Aebi, Ueli and Stolz, Martin
(2010)
Micro- and nanomechanical analysis of articular cartilage by indentation-type atomic force microscopy: validation with a gel-microfiber composite microscopy.
Biophysical Journal, 98 (11), .
(doi:10.1016/j.bpj.2010.02.013).
Abstract
As documented previously, articular cartilage exhibits a scale-dependent dynamic stiffness when probed by indentation-type atomic force microscopy (IT-AFM). In this study, a micrometer-size spherical tip revealed an unimodal stiffness distribution (which we refer to as microstiffness), whereas probing articular cartilage with a nanometer-size pyramidal tip resulted in a bimodal nanostiffness distribution. We concluded that indentation of the cartilage's soft proteoglycan (PG) gel gave rise to the lower nanostiffness peak, whereas deformation of its collagen fibrils yielded the higher nanostiffness peak. To test our hypothesis, we produced a gel-microfiber composite consisting of a chondroitin sulfate-containing agarose gel and a fibrillar poly(ethylene glycol)-terephthalate/poly(butylene)-terephthalate block copolymer. In striking analogy to articular cartilage, the microstiffness distribution of the synthetic composite was unimodal, whereas its nanostiffness exhibited a bimodal distribution. Also, similar to the case with cartilage, addition of the negatively charged chondroitin sulfate rendered the gel-microfiber composite's water content responsive to salt. When the ionic strength of the surrounding buffer solution increased from 0.15 to 2 M NaCl, the cartilage's microstiffness increased by 21%, whereas that of the synthetic biomaterial went up by 31%. When the nanostiffness was measured after the ionic strength was raised by the same amount, the cartilage's lower peak increased by 28%, whereas that of the synthetic biomaterial went up by 34%. Of interest, the higher peak values remained unchanged for both materials. Taken together, these results demonstrate that the nanoscale lower peak is a measure of the soft PG gel, and the nanoscale higher peak measures collagen fibril stiffness. In contrast, the micrometer-scale measurements fail to resolve separate stiffness values for the PG and collagen fibril moieties. Therefore, we propose to use nanostiffness as a new biomarker to analyze structure-function relationships in normal, diseased, and engineered cartilage.
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Published date: 2 June 2010
Organisations:
Engineering Mats & Surface Engineerg Gp
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Local EPrints ID: 71693
URI: http://eprints.soton.ac.uk/id/eprint/71693
ISSN: 0006-3495
PURE UUID: b29a7c36-fa9d-4b8b-8427-d0d338ba022e
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Date deposited: 21 Dec 2009
Last modified: 14 Mar 2024 02:55
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Author:
Marko Loparic
Author:
Dieter Wirz
Author:
A.U. Daniels
Author:
Roberto Raiteri
Author:
Mark R. VanLandingham
Author:
Geraldine Guex
Author:
Ivan Martin
Author:
Ueli Aebi
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