Literature DB >> 2505907

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

C Rey1, B Collins, T Goehl, I R Dickson, M J Glimcher.   

Abstract

The environment of carbonate ions in bones of different species (rat, rabbit, chicken, cow, human) was investigated by Fourier Transform Infrared Spectroscopy (FTIR) associated with a self-deconvolution technique. The carbonate bands in the v2 CO3(2-) domain show three components which were identified by using synthetic standards and different properties of the apatitic structure (ionic affinity for crystallographic locations, ionic exchange). The major component at 871 cm-1 is due to carbonate ions located in PO4(3-) sites (type B carbonate). A band at 878 cm-1 was exclusively assigned to carbonate ions substituting for OH-ions in the apatitic structure (type A carbonate). A band at 866 cm-1 not previously observed was shown to correspond to a labile carbonate environment. The intensity ratio of type A to type B carbonate appears remarkably constant in all bone samples. The 866 cm-1 carbonate band varies in its relative intensity in different species.

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Year:  1989        PMID: 2505907     DOI: 10.1007/bf02556059

Source DB:  PubMed          Journal:  Calcif Tissue Int        ISSN: 0171-967X            Impact factor:   4.333


  16 in total

1.  Mineralization in the chick embryo. I. Monohydrogen phosphate and carbonate relationships during maturation of the bone crystal complex.

Authors:  E D Pellegrino; R M Biltz
Journal:  Calcif Tissue Res       Date:  1972

2.  Hydroxyapatite: mechanism of formation and properties.

Authors:  N C Blumenthal; A S Posner
Journal:  Calcif Tissue Res       Date:  1973-10-23

3.  Hydrazine-deproteinated bone mineral. Physical and chemical properties.

Authors:  J D Termine; E D Eanes; D J Greenfield; M U Nylen; R A Harper
Journal:  Calcif Tissue Res       Date:  1973

4.  Differences in the shape of human enamel crystallites after partial destruction by caries, EDTA and various acids.

Authors:  N W Johnson
Journal:  Arch Oral Biol       Date:  1966-12       Impact factor: 2.633

5.  The hydroxyl content of calcified tissue mineral.

Authors:  R M Biltz; E D Pellegrino
Journal:  Calcif Tissue Res       Date:  1971

6.  A comparative study of the exchange in vivo of major constituents of bone mineral.

Authors:  J T Triffitt; A R Terepka; W F Neuman
Journal:  Calcif Tissue Res       Date:  1968-10-21

7.  Two types of carbonate substitution in the apatite structure.

Authors:  R Z LeGeros; O R Trautz; E Klein; J P LeGeros
Journal:  Experientia       Date:  1969-01-15

8.  Failure to detect an amorphous calcium-phosphate solid phase in bone mineral: a radial distribution function study.

Authors:  M D Grynpas; L C Bonar; M J Glimcher
Journal:  Calcif Tissue Int       Date:  1984-05       Impact factor: 4.333

9.  Preparation, analysis, and characterization of carbonated apatites.

Authors:  D G Nelson; J D Featherstone
Journal:  Calcif Tissue Int       Date:  1982       Impact factor: 4.333

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

Authors:  A H Roufosse; W P Aue; J E Roberts; M J Glimcher; R G Griffin
Journal:  Biochemistry       Date:  1984-12-04       Impact factor: 3.162
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  86 in total

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2.  Effect of hydrazine based deproteination protocol on bone mineral crystal structure.

Authors:  I A Karampas; M G Orkoula; C G Kontoyannis
Journal:  J Mater Sci Mater Med       Date:  2012-03-03       Impact factor: 3.896

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Authors:  L M Rodríguez-Lorenzo
Journal:  J Mater Sci Mater Med       Date:  2005-05       Impact factor: 3.896

Review 5.  FT-IR imaging of native and tissue-engineered bone and cartilage.

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Journal:  Biomaterials       Date:  2006-12-18       Impact factor: 12.479

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Authors:  Shai Abehsera; Shmuel Bentov; Xuguang Li; Simy Weil; Rivka Manor; Shahar Sagi; Shihao Li; Fuhua Li; Isam Khalaila; Eliahu D Aflalo; Amir Sagi
Journal:  Sci Rep       Date:  2021-06-03       Impact factor: 4.379

7.  A Fourier transform infrared spectroscopy analysis of carious dentin from transparent zone to normal zone.

Authors:  Y Liu; X Yao; Y W Liu; Y Wang
Journal:  Caries Res       Date:  2014       Impact factor: 4.056

8.  Chemistry of bone mineral, based on the hypermineralized rostrum of the beaked whale Mesoplodon densirostris.

Authors:  Zhen Li; Jill D Pasteris
Journal:  Am Mineral       Date:  2014-04       Impact factor: 3.003

9.  Fourier transform infrared imaging microspectroscopy and tissue-level mechanical testing reveal intraspecies variation in mouse bone mineral and matrix composition.

Authors:  Hayden-William Courtland; Philip Nasser; Andrew B Goldstone; Lyudmila Spevak; Adele L Boskey; Karl J Jepsen
Journal:  Calcif Tissue Int       Date:  2008-10-15       Impact factor: 4.333

10.  Influence of de-remineralization process on chemical, microstructural, and mechanical properties of human and bovine dentin.

Authors:  Tattiana Enrich-Essvein; Cristina Benavides-Reyes; Pedro Álvarez-Lloret; María Victoria Bolaños-Carmona; Alejandro B Rodríguez-Navarro; Santiago González-López
Journal:  Clin Oral Investig       Date:  2020-05-27       Impact factor: 3.573
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