Genesis and growth of extracellular-vesicle-derived microcalcification in atherosclerotic plaques

Joshua D. Hutcheson; Claudia Goettsch; Sergio Bertazzo; Natalia Maldonado; Jessica L. Ruiz; Wilson Goh; Katsumi Yabusaki; Tyler Faits; Carlijn Bouten; Gregory Franck; Thibaut Quillard; Peter Libby; Masanori Aikawa; Sheldon Weinbaum; Elena Aikawa

doi:10.1038/nmat4519

Genesis and growth of extracellular-vesicle-derived microcalcification in atherosclerotic plaques

Joshua D. Hutcheson, Claudia Goettsch, Sergio Bertazzo, Natalia Maldonado, Jessica L. Ruiz, Wilson Goh, Katsumi Yabusaki, Tyler Faits, Carlijn Bouten, Gregory Franck, Thibaut Quillard, Peter Libby, Masanori Aikawa, Sheldon Weinbaum, Elena Aikawa^*

^*Corresponding author for this work

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

306 Citations (Scopus)

Abstract

Clinical evidence links arterial calcification and cardiovascular risk. Finite-element modelling of the stress distribution within atherosclerotic plaques has suggested that subcellular microcalcifications in the fibrous cap may promote material failure of the plaque, but that large calcifications can stabilize it. Yet the physicochemical mechanisms underlying such mineral formation and growth in atheromata remain unknown. Here, by using three-dimensional collagen hydrogels that mimic structural features of the atherosclerotic fibrous cap, and high-resolution microscopic and spectroscopic analyses of both the hydrogels and of calcified human plaques, we demonstrate that calcific mineral formation and maturation results from a series of events involving the aggregation of calcifying extracellular vesicles, and the formation of microcalcifications and ultimately large calcification areas. We also show that calcification morphology and the plaque's collagen content - two determinants of atherosclerotic plaque stability - are interlinked.

Original language	English
Pages (from-to)	335-343
Number of pages	9
Journal	Nature Materials
Volume	15
Issue number	3
DOIs	https://doi.org/10.1038/nmat4519
Publication status	Published - Mar 1 2016
Externally published	Yes

Bibliographical note

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© 2016 Macmillan Publishers Limited. All rights reserved.

ASJC Scopus Subject Areas

General Chemistry
General Materials Science
Condensed Matter Physics
Mechanics of Materials
Mechanical Engineering

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title = "Genesis and growth of extracellular-vesicle-derived microcalcification in atherosclerotic plaques",

abstract = "Clinical evidence links arterial calcification and cardiovascular risk. Finite-element modelling of the stress distribution within atherosclerotic plaques has suggested that subcellular microcalcifications in the fibrous cap may promote material failure of the plaque, but that large calcifications can stabilize it. Yet the physicochemical mechanisms underlying such mineral formation and growth in atheromata remain unknown. Here, by using three-dimensional collagen hydrogels that mimic structural features of the atherosclerotic fibrous cap, and high-resolution microscopic and spectroscopic analyses of both the hydrogels and of calcified human plaques, we demonstrate that calcific mineral formation and maturation results from a series of events involving the aggregation of calcifying extracellular vesicles, and the formation of microcalcifications and ultimately large calcification areas. We also show that calcification morphology and the plaque's collagen content - two determinants of atherosclerotic plaque stability - are interlinked.",

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AU - Hutcheson, Joshua D.

AU - Goettsch, Claudia

AU - Bertazzo, Sergio

AU - Maldonado, Natalia

AU - Ruiz, Jessica L.

AU - Goh, Wilson

AU - Yabusaki, Katsumi

AU - Faits, Tyler

AU - Bouten, Carlijn

AU - Franck, Gregory

AU - Quillard, Thibaut

AU - Libby, Peter

AU - Aikawa, Masanori

AU - Weinbaum, Sheldon

AU - Aikawa, Elena

PY - 2016/3/1

Y1 - 2016/3/1

N2 - Clinical evidence links arterial calcification and cardiovascular risk. Finite-element modelling of the stress distribution within atherosclerotic plaques has suggested that subcellular microcalcifications in the fibrous cap may promote material failure of the plaque, but that large calcifications can stabilize it. Yet the physicochemical mechanisms underlying such mineral formation and growth in atheromata remain unknown. Here, by using three-dimensional collagen hydrogels that mimic structural features of the atherosclerotic fibrous cap, and high-resolution microscopic and spectroscopic analyses of both the hydrogels and of calcified human plaques, we demonstrate that calcific mineral formation and maturation results from a series of events involving the aggregation of calcifying extracellular vesicles, and the formation of microcalcifications and ultimately large calcification areas. We also show that calcification morphology and the plaque's collagen content - two determinants of atherosclerotic plaque stability - are interlinked.

AB - Clinical evidence links arterial calcification and cardiovascular risk. Finite-element modelling of the stress distribution within atherosclerotic plaques has suggested that subcellular microcalcifications in the fibrous cap may promote material failure of the plaque, but that large calcifications can stabilize it. Yet the physicochemical mechanisms underlying such mineral formation and growth in atheromata remain unknown. Here, by using three-dimensional collagen hydrogels that mimic structural features of the atherosclerotic fibrous cap, and high-resolution microscopic and spectroscopic analyses of both the hydrogels and of calcified human plaques, we demonstrate that calcific mineral formation and maturation results from a series of events involving the aggregation of calcifying extracellular vesicles, and the formation of microcalcifications and ultimately large calcification areas. We also show that calcification morphology and the plaque's collagen content - two determinants of atherosclerotic plaque stability - are interlinked.

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Genesis and growth of extracellular-vesicle-derived microcalcification in atherosclerotic plaques

Abstract

Bibliographical note

ASJC Scopus Subject Areas

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