Biomechanical Environment Regulates Biomimetic Mineralization of Bone Matrix / 医用生物力学

Bone defects have always been an important cause of threat to human health, and artificial biomimetic bone repair replacement materials are currently one of the most effective and feasible solution approaches to treat bone damage. To develop artificial bone biomimetic materials, an in vitro biomimetic mineralization system must be constructed first to study in vitro biomimetic mineralization mechanism of natural bone matrix. Collagen is a template for mineralization, and its properties such as crosslinking degree, diameter, osmotic pressure, and surface charge can all directly affect mineralization progress. The biochemical and mechanical environments in which mineralization occurs are also quite distinct in their effects on mineralization process, particularly noncollagenous proteins and fluid shear stress (FSS). FSS is considered to be the main mechanical stimulation of bone tissues in micro-environment, which is of great significance to bone growth, repair and health maintenance. FSS at different levels and loading regimes has significant effects on transformation of amorphous calcium phosphate to bone apatite, self-assembly and directional alignment of collagen fibrils, and formation of hierarchical intrafibrillar mineralization. In this paper, the factors affecting collagen mineralization and their mechanism were summarized, with focus on regulation of FSS on collagen mineralization, and development direction in future was also prospected.

Research progress on the biomimetic remineralization of hard tooth tissues based on polyamide-amine dendrimer / 华西口腔医学杂志

Polyamide-amine (PAMAM) dendrimer, a new hyperbranched macromolecular polymer, is considered an "artificial protein" by many scholars on account of its excellent chemical and biological characteristics. PAMAM has internal cavities and a large number of reactive terminal groups. These structures allow the polymer to be used as a bionic macromoleculethat could simulate the biomimetic mineralization of the natural organic matrix on the surface of tooth tissue. Specifically, PAMAM can beused as an organic template to regulate mineral nucleation and crystal growth; thus, the polymerisa more ideal dental restoration material than traditional allogenic materials. This article reviews research progress on thePAMAM-induced biomimetic mineralization of hard tooth tissues.

Review of the mechanism of biomimetic intrafibrillar mineralization / 口腔疾病防治

@#Bone is a hierarchically structured and highly mineralized hard tissue composed of an organic phase (type I collagen and noncollagenous proteins) and an inorganic phase (nanohydroxyapatite). Intrafibrillar mineralized collagen is the basic structural unit of bone tissue and is of high significance due to its superior mechanical and biological properties. Thus, to truly understand the unique properties of bone, it is necessary to review the most basic structural level of bone. In this article, we review the recent advances in understanding the development of intrafibrillar mineralization and the prevailing theories in the formation of such intrafibrillar minerals. Understanding the mechanisms of intrafibrillar mineralization may facilitate the development of engineered bone for clinical applications and provide deeper insight into the nature of biomineralization.