The carbonate environment in bone mineral: A resolution-enhanced fourier transform infrared spectroscopy study

Calcified Tissue International - Tập 45 Số 3 - Trang 157-164 - 1989
Christian Rey1, Bradley J. Collins2, Thomas J. Goehl2, Ian Dickson3, Melvin J. Glimcher
1Laboratory for the Study of Skeletal Disorders and Rehabilitation, Department of Orthoapedic Surgery, Children's Hospital, Harvard Medical School, Boston, USA
2Department of Chemistry, National Institute of Environmental Health Science, Research Triangle Park, USA
3Department of Medicine, University of Cambridge, Cambridge, England.

Tóm tắt

Từ khóa


Tài liệu tham khảo

Arends J, Jongebloed WL (1981) Apatite single crystals. Formation, dissolution and influence, of CO3 2− ions. Recveil Rev 100(1):3–9

Biltz RM, Pellegrino ED (1977) The nature of bone carbonate. Clin Orthop Rel Res 129:279–292

Hallsworth AS, Weatherell JA, Robinson C (1973) Loss of carbonate during the first stages of enamel caries. Caries Res 7:345–348

Biltz RM, Pellegrino ED (1981) Skeletal carbonates and acid-base regulation. Mineral Electrolyte Metal 5:1–7

Elliott JC (1964) The crystallographic structure of dental enamel and related apatites. Ph.D. Thesis, Univeristy of London.

Elliott JC, Holcomb DW, Young RA (1985) Infrared determination of the degree of substitution of hydroxyl by carbonate ions in human dental enamel. Calcif Tissue Int 37:372–375

Termine JD, Eanes ED, Greenfield DJ, Nylen MU (1973) Hydrazine deproteinated bone mineral. Calcif Tissue Res 12:73–90

Emerson WH, Fischer ED (1962) The infrared absorption spectra of carbonate in calcified tissues. Arch Oral Biol 7:671–683

Baxter JD, Biltz RM, Pellegrino ED (1966) The physical state of bone carbonate: a comparative infrared study in several, mineralized tissues. Yale J Biol Med 3:456–470

LeGeros RZ, Trautz OR, Klein E, LeGeros JP (1969) Two types of carbonates substitution in the apatite structure. Experientia 25(1):5–7

Nelson DGA, Featherstone, JDB (1982) Preparation analysis and characterization of carbonated apatites. Calcif Tissue Int 34:S69–81

Suzuki M (1974) A study of physicochemical nature of hard tissues. Hirosaki Igaku 26:20–25

LeGros R, Balmain N, Bonel G (1986) Structure and composition of the mineral phase of periosteal bone. J Chem Res Synop 1:8–9

Kaupinen JK, Moffatt DJ, Mantsch HH, Cameron DG (1981) Fourier self-deconvolution: a method for resolving intrinsically overlapped bands. Appl Spect 35: 271–276

Roufosse AH, Landis WJ, Sabine NK, Glimcher MJ (1979) Identification of brushite in newly deposited bone mineral from embryonic chicks. J Ultrastruct Res 68:235–255

Trombe JC, Bonel G, Montel G (1969) Etude par spectrometrie d'absorption dans l'infrarouge de l'ion carbonate dans quelques apatites preparées a haute température. CR Acad Sci Paris 268:941–944

Vignoles-Montrejaud M (1984) Contribution a l'étude des apatites carbonatées de type B These d'Etat, I.N.P. Toulouse

Roufosse AH, Aue JE, Roberts JE, Glimcher MJ, Griffin RG (1984) Investigation of the mineral phases of bone by solid-state phorphorus 31 major angle sample spinning nuclear magnetic resonance. Biochemistry 23:6115–6126

Pellegrino ED, Biltz RM (1972) Mineralization in the chicks embryo: I monohydrogen phosphate and carbonate relationships during maturation of bone crystals complex. Calcif Tissue Res 10:128–135

LeGeros RZ, Kijkowska R, LeGeros JP, Abergas T, Bleiwas H (1987) CO3-for-OH (type A) and CO3-for-PO4 (type B) substitutions in precipiated carbonate-apatites. IADR Meeting Abstracts, J Dent Res 66–190

Gee A, Dietz VR (1955) Pyrophosphate formation upon ignition of precipitated basic calcium phosphate. J Am Chem Soc 77:2961–2965

LeGeros RZ, LeGeros JP (1983) Carbonate analysis of synthetic mineral and biological apatites. IADR Meeting Abstracts. J Dent Res 62–259

Bonel G (1972) Contribution a l'étude de la carbonatation des apatites. Ann Chim 7:127–144

LeGeros RZ, Trautz OR, LeGeros JP, Klein E (1968) Carbonate substitution in the apatitic structure. Bull Soc Chim Fr 1712–1718

Trombe JC (1972) Contribution a l'Etude de la decomposition et de la reactivite de certaines apatites hydroxylées carbonatées ou Fluorées alcalino terreuses. Thèse d'Etat, Université P. Sabitier Toulouse

Roux P (1982) Contribution a l'Etude du comportement et de la synthèse des apatites carbonatées sous haute pression. Thèse d'Etat, I.N.P. Toulouse

McClellan GH, Guerry H, Lehr JR (1969) Crystal chemical investigations of natural apatites. An. Miner. 54:1374–1391

Blumenthal NC, Posner AS (1973) Hydroxyapatite: mechanisms of formation and properties. Calcif Tissue Res 13:235–243

Vignoles C (1973) Contribution a l'étude de l'influence des ions alcalins sur la carbonatation dans les sites de type B des apatites phosphocalciques. These de 3 cycle I.N.P. Toulouse

Biltz RM, Pellegrino ED (1971) The hydroxyl content of calcified tissue mineral. Calcif Tissue Res 7:259

Grynpas MD, Bonar LC, Glimcher MJ (1984) Failure to detect an amorphous calcium-phosphate solid phase in bone mineral: a radial distribution function study. Calcif Tissue Int 36:291–301

Posner AS, Botts F (1975) Synthetic amorphous calcium phosphate and its relation to bone mineral structure. Acc Chem Res 8:273–281

Triffitt JT, Terepka AR, Neuman WF (1968) A comparative study of the exchange, in vivo of major constituents of bone mineral. Calcif Tissue Res 2:165–176

Hendricks SB, Hill WL (1950) The nature of bone and phosphate rocks. Proc Natl Acad Sci 36:731

Johnson NW (1966) Difference in the shape of human enamel crystallites after partial destruction by caries, EDTA, and various acids. Arch Oral Biol 11:1421–1424

Daculsi G, LeGeros RZ (1986) Central dark lines in synthetic and biological apatites. IADR Meeting Abstracts. J Dent Res 65:802