缺钙羟基磷灰石的形成与结构。

Formation and structure of Ca-deficient hydroxyapatite.

作者信息

Blumenthal N C, Betts F, Posner A S

出版信息

Calcif Tissue Int. 1981;33(2):111-7. doi: 10.1007/BF02409422.

Abstract

When amorphous calcium phosphate (ACP) was transformed to crystalline hydroxyapatite (HA) in a series of aqueous slurry concentrations ranging from low to high, the higher slurry concentrations produced more Ca-deficient HA as measured by Ca/P ratio and heat-produced pyrophosphate. We feel that the excess solution phosphate produced in the higher slurry transformations results in lower Ca/P ratio HA. It has been suggested that an ACP is the precursor to bone apatite. Regulation of the in vivo ACP slurry concentration could then control the stoichiometry and, therefore, the metabolic activity of bone apatite. X-ray radial distribution function (RDF) analyses showed that CO3(2-) substitution in HA creates far greater structural distortions than do Ca deficiencies. The latter, however, do produce small, but observable, structural distortions when compared to stoichiometric HA. It now seems clear that the RDF of bone apatite can be modeled by a synthetic, Ca-deficient, CO3(2-)-containing HA.

摘要

当无定形磷酸钙（ACP）在一系列从低到高的水浆浓度中转化为结晶羟基磷灰石（HA）时，通过钙磷比和热产生的焦磷酸盐测量，较高的浆浓度产生了更多缺钙的HA。我们认为，在较高的浆转化中产生的过量溶液磷酸盐导致了钙磷比更低的HA。有人提出，ACP是骨磷灰石的前体。那么，体内ACP浆浓度的调节可以控制化学计量，从而控制骨磷灰石的代谢活性。X射线径向分布函数（RDF）分析表明，HA中的CO3(2-)取代比钙缺乏产生的结构畸变要大得多。然而，与化学计量的HA相比，后者确实会产生小但可观察到的结构畸变。现在似乎很清楚，骨磷灰石的RDF可以由一种合成的、缺钙的、含CO3(2-)的HA来模拟。

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缺钙羟基磷灰石的形成与结构。

Formation and structure of Ca-deficient hydroxyapatite.

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