Department of Cell and Molecular Biology, Feinberg School of Medicine, Northwestern University, 303 E. Chicago Avenue, Chicago, 60611, USA,
Calcif Tissue Int. 2013 Oct;93(4):307-15. doi: 10.1007/s00223-012-9678-2. Epub 2012 Dec 16.
There is substantial practical interest in the mechanism by which the carbonated apatite of bone mineral can be initiated specifically in a matrix. The current literature is replete with studies aimed at mimicking the properties of vertebrate bone, teeth, and other hard tissues by creating organic matrices that can be mineralized in vitro and either functionally substitute for bone on a permanent basis or serve as a temporary structure that can be replaced by normal remodeling processes. A key element in this is mineralization of an implant with the matrix and mineral arranged in the proper orientations and relationships. This review examines the pathway to crystallization from a supersaturated calcium phosphate solution in vitro, focusing on the basic mechanistic questions concerning mineral nucleation and growth. Since bone and dentin mineral forms within collagenous matrices, we consider how the in vitro crystallization mechanisms might or might not be applicable to understanding the in vivo processes of biomineralization in bone and dentin. We propose that the pathway to crystallization from the calcium phosphate-supersaturated tissue fluids involves the formation of a dense liquid phase of first-layer bound-water hydrated calcium and phosphate ions in which the crystallization is nucleated. SIBLING proteins and their in vitro analogs, such as polyaspartic acids, have similar dense liquid first-layer bound-water surfaces which interact with the dense liquid calcium phosphate nucleation clusters and modulate the rate of crystallization within the bone and dentin collagen fibril matrix.
人们对碳酸磷灰石在基质中特异性起始的机制具有实质性的实际兴趣。目前的文献中充满了旨在通过创建可在体外矿化的有机基质来模拟脊椎动物骨骼、牙齿和其他硬组织特性的研究,这些基质要么可以永久替代骨骼,要么可以作为一种临时结构,通过正常的重塑过程来替代。这其中的一个关键要素是将植入物与基质和矿物质按适当的方向和关系进行矿化。本综述考察了体外过饱和磷酸钙溶液中结晶的途径,重点关注关于矿物质成核和生长的基本机制问题。由于骨骼和牙本质矿物质在胶原基质中形成,我们考虑了体外结晶机制可能或不可能适用于理解骨骼和牙本质中生物矿化的体内过程。我们提出,从过饱和的组织液中结晶的途径涉及首先形成一层紧密结合的水合钙和磷酸根离子的致密液相,在其中进行结晶成核。SIBLING 蛋白及其体外类似物,如聚天冬氨酸,具有类似的致密液相第一层结合水表面,与致密液相磷酸钙成核簇相互作用,并调节骨骼和牙本质胶原纤维基质内的结晶速率。