Literature DB >> 6525350

Investigation of the mineral phases of bone by solid-state phosphorus-31 magic angle sample spinning nuclear magnetic resonance.

A H Roufosse, W P Aue, J E Roberts, M J Glimcher, R G Griffin.   

Abstract

Phosphorus-31 magic angle sample spinning NMR spectra have been employed to investigate the structure and composition of the mineral deposits in chicken bone. Three different pulse sequences, Bloch decay, cross-polarization, and dipolar suppression, were employed to obtain spectra from bone specimens of varying age. These were compared to the spectra obtained from a variety of crystalline and noncrystalline synthetic calcium phosphate solids used as reference standards. The results suggest that the most suitable model for the major solid calcium phosphate mineral phase in bone is a hydroxyapatite containing approximately 5-10% CO32- and approximately 5-10% HPO42- groups, the latter in a brushite-like configuration. From the NMR line shapes it was deduced that the fraction of HPO42- groups was highest in the youngest bone and decreased progressively with increasing age of the specimen.

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Year:  1984        PMID: 6525350     DOI: 10.1021/bi00320a033

Source DB:  PubMed          Journal:  Biochemistry        ISSN: 0006-2960            Impact factor:   3.162


  17 in total

1.  Maturational changes in dentin mineral properties.

Authors:  K Verdelis; L Lukashova; J T Wright; R Mendelsohn; M G E Peterson; S Doty; A L Boskey
Journal:  Bone       Date:  2007-01-03       Impact factor: 4.398

2.  The carbonate environment in bone mineral: a resolution-enhanced Fourier Transform Infrared Spectroscopy Study.

Authors:  C Rey; B Collins; T Goehl; I R Dickson; M J Glimcher
Journal:  Calcif Tissue Int       Date:  1989-09       Impact factor: 4.333

3.  Age-related changes in mineral of rat and bovine cortical bone.

Authors:  R Legros; N Balmain; G Bonel
Journal:  Calcif Tissue Int       Date:  1987-09       Impact factor: 4.333

4.  Phosphorus-31 in vivo magnetic resonance spectroscopy of bone fails to diagnose osteoporosis.

Authors:  S Confort-Gouny; J P Mattéi; J Vion-Dury; H Roux; J P Bisset; P J Cozzone
Journal:  Calcif Tissue Int       Date:  1995-06       Impact factor: 4.333

5.  Resolution-enhanced Fourier transform infrared spectroscopy study of the environment of phosphate ions in the early deposits of a solid phase of calcium-phosphate in bone and enamel, and their evolution with age. I: Investigations in the upsilon 4 PO4 domain.

Authors:  C Rey; M Shimizu; B Collins; M J Glimcher
Journal:  Calcif Tissue Int       Date:  1990-06       Impact factor: 4.333

6.  A comparison of the physical and chemical differences between cancellous and cortical bovine bone mineral at two ages.

Authors:  Liisa T Kuhn; Marc D Grynpas; Christian C Rey; Yaotang Wu; Jerome L Ackerman; Melvin J Glimcher
Journal:  Calcif Tissue Int       Date:  2008-08-07       Impact factor: 4.333

7.  Bone mineral: update on chemical composition and structure.

Authors:  C Rey; C Combes; C Drouet; M J Glimcher
Journal:  Osteoporos Int       Date:  2009-06       Impact factor: 4.507

8.  Characterization of very young mineral phases of bone by solid state 31phosphorus magic angle sample spinning nuclear magnetic resonance and X-ray diffraction.

Authors:  J E Roberts; L C Bonar; R G Griffin; M J Glimcher
Journal:  Calcif Tissue Int       Date:  1992-01       Impact factor: 4.333

9.  31P NMR relaxation of cortical bone mineral at multiple magnetic field strengths and levels of demineralization.

Authors:  Alan C Seifert; Alexander C Wright; Suzanne L Wehrli; Henry H Ong; Cheng Li; Felix W Wehrli
Journal:  NMR Biomed       Date:  2013-03-18       Impact factor: 4.044

10.  Analyses of mineral specific surface area and hydroxyl substitution for intact bone.

Authors:  Amanda J Taylor; Elizabeth Rendina; Brenda J Smith; Donghua H Zhou
Journal:  Chem Phys Lett       Date:  2013-11-19       Impact factor: 2.328
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