Temperature-induced mobility in octacalcium phosphate impacts crystal symmetry: water dynamics studied by NMR crystallography

Octacalcium phosphate (OCP, Ca (PO ) (HPO ) ·5H O) is a notable calcium phosphate due to its biocompatibility, making it a widely studied material for bone substitution. It is known to be a precursor of bone mineral, but its role in biomineralisation remains unclear. While the structure of OCP has b...

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Veröffentlicht in:	Faraday discussions 2025-01, Vol.255, p.451-482
Hauptverfasser:	Nelson, Adam, Papawassiliou, Wassilios, Paul, Subhradip, Hediger, Sabine, Hung, Ivan, Gan, Zhehong, Venkatesh, Amrit, Franks, W Trent Trent, Smith, Mark E, Gajan, David, De Paëpe, Gaël, Bonhomme, Christian, Laurencin, Danielle, Gervais, Christel
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Sprache:	eng
Schlagworte:	Ambient temperature Biocompatibility Calcium isotopes Calcium phosphates Crystallography Dynamic structural analysis Materials substitution Molecular dynamics NMR Nuclear magnetic resonance Room temperature Symmetry Water chemistry
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creator	Nelson, Adam Papawassiliou, Wassilios Paul, Subhradip Hediger, Sabine Hung, Ivan Gan, Zhehong Venkatesh, Amrit Franks, W Trent Trent Smith, Mark E Gajan, David De Paëpe, Gaël Bonhomme, Christian Laurencin, Danielle Gervais, Christel
description	Octacalcium phosphate (OCP, Ca (PO ) (HPO ) ·5H O) is a notable calcium phosphate due to its biocompatibility, making it a widely studied material for bone substitution. It is known to be a precursor of bone mineral, but its role in biomineralisation remains unclear. While the structure of OCP has been the subject of thorough investigations (including using Rietveld refinements of X-ray diffraction data, and NMR crystallography studies), important questions regarding the symmetry and H-bonding network in the material remain. In this study, it is shown that OCP undergoes a lowering of symmetry below 200 K, evidenced by H, O, P and Ca solid-state NMR experiments. Using molecular-dynamics (MD) simulations and gauge including projected augmented wave (GIPAW) DFT calculations of NMR parameters, the presence of rapid motions of the water molecules in the crystal cell at room temperature is proved. This information leads to an improved description of the OCP structure at both low and ambient temperatures, and helps explain long-standing issues of symmetry. Remaining challenges related to the understanding of the structure of OCP are then discussed.
doi_str_mv	10.1039/d4fd00108g
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source	Royal Society Of Chemistry Journals 2008-; Alma/SFX Local Collection
subjects	Ambient temperature Biocompatibility Calcium isotopes Calcium phosphates Crystallography Dynamic structural analysis Materials substitution Molecular dynamics NMR Nuclear magnetic resonance Room temperature Symmetry Water chemistry
title	Temperature-induced mobility in octacalcium phosphate impacts crystal symmetry: water dynamics studied by NMR crystallography
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