Trabecular bone microdamage and microstructural stresses under uniaxial compression.

The balance between local remodeling and accumulation of trabecular bone microdamage is believed to play an important role in the maintenance of skeletal integrity. However, the local mechanical parameters associated with microdamage initiation are not well understood. Using histological damage labeling, micro-CT imaging, and image-based finite element analysis, regions of trabecular bone microdamage were detected and registered to estimated microstructural von Mises effective stresses and strains, maximum principal stresses and strains, and strain energy density (SED). Bovine tibial trabecular bone cores underwent a stepwise uniaxial compression routine in which specimens were micro-CT imaged following each compression step. The results indicate that the mode of trabecular failure observed by micro-CT imaging agreed well with the polarity and distribution of stresses within an individual trabecula. Analysis of on-axis subsections within specimens provided significant positive relationships between microdamage and each estimated tissue stress, strain and SED parameter. In a more localized analysis, individual microdamaged and undamaged trabeculae were extracted from specimens loaded within the elastic region and to the apparent yield point. As expected, damaged trabeculae in both groups possessed significantly higher local stresses and strains than undamaged trabeculae. The results also indicated that microdamage initiation occurred prior to apparent yield at local principal stresses in the range of 88-121 MPa for compression and 35-43 MPa for tension and local principal strains of 0.46-0.63% in compression and 0.18-0.24% in tension. These data provide an important step towards understanding factors contributing to microdamage initiation and establishing local failure criteria for normal and diseased trabecular bone.

Regulation of syndecan-4 expression with mechanical stress during the development of angioplasty-induced intimal thickening.

In this study, we postulated that acute mechanical strain of the arterial wall induces changes in syndecan-4 expression that in turn may modulate cellular events, which promote neointima formation. Correlative in vivo and in vitro studies were performed to determine whether: (1) balloon injury of the rat carotid artery induces spatially and temporally regulated changes in syndecan-4 messenger RNA (mRNA) and protein expression; (2) the application of biaxial mechanical strain to cultured vascular wall cells regulates the expression of syndecan-4 mRNA and protein and its cell surface distribution and surface shedding; and (3) shed syndecan-4 directly effects cell motility behavior. We observed that syndecan-4 mRNA and protein expression were regulated in a temporally and spatially specific manner, such that initial expression of syndecan-4 was localized to adventitial cells followed by later expression in the neointima. Notably, in vitro stimulation of isolated adventitial fibroblasts with a mechanical stretch protocol that was designed to mimic in vivo balloon injury produced a rapid increase in syndecan-4 (4.3-fold increase; P <.001) that was accompanied both by enhanced protein shedding and by the disassembly of focal adhesions. Also significant was that shed syndecan-4, induced with mechanically conditioned media, appeared to be responsible for a chemotactic response of adventitial fibroblasts (P =.005). These results indicate that mechanical strain tightly regulates syndecan-4 expression, which may, in part, provide a mechanism for the activation of myofibroblast migration from the tunica adventitia into the neointima.

Upregulation of Nox-based NAD(P)H oxidases in restenosis after carotid injury.

Restenosis, a frequent complication of coronary angioplasty, is associated with increased superoxide (O2*(-)) production. Although the molecular identity of the responsible oxidase is unclear, an NAD(P)H oxidase appears to be involved. In smooth muscle, p22phox and 2 homologues of gp91phox, nox1 and nox4, are expressed, whereas fibroblasts contain gp91phox. To begin investigating the possibility that these oxidase components might contribute to the increased O2*(-) that accompanies neointimal formation, we measured their expression after balloon injury of the rat carotid artery. The increase in O2*(-) production 3 to 15 days after surgery was not due to inflammatory cell infiltration but appeared to be derived from medial and neointimal smooth muscle cells and adventitial fibroblasts. Nox1 and p22phox mRNAs were increased 2.7- and 3.6-fold, respectively, at day 3 after injury and remained elevated for 15 days. gp91Phox was increased 7 to 15 days after injury, and nox4 expression was increased 2-fold, but only at day 15 after surgery. These results confirm and extend our previous in vitro data and suggest that in the vasculature, the nox-based NAD(P)H oxidases serve different functions. This dynamic regulation of oxidase components may be critical to smooth muscle phenotypic modulation in restenosis and atherosclerosis.