Strategies of hemopoietic stress adaptation within the medullary cavity

Three-dimensional cortical bone microstructure in a rat model of hypoxia-induced growth retardation

Little is known about hypoxia-induced modification of the canal network in the cortical bone despite its involvement in intracortical vascularity and bone blood supply. In this study, we examined the effect of chronic hypoxia on the canal network in postnatal bone. Tibiae were harvested from 4- and 8-week-old rats (hyp-4 and -8, n = 8 each), whose growth was retarded owing to postnatal exposure to hypoxia (12-14% O₂), and from 3- and 4-week-old normoxic rats (cnt-4 and -5, n = 8 each), which were similar in tibial length and cortical cross-sectional area to hyp-4 and -8, respectively. The diaphyseal canals were detected by monochromatic synchrotron radiation CT with a 3.1-μm voxel resolution. The anatomical properties of the canal network were compared between age- or size-matched hypoxic and normoxic groups. The canals were larger in diameter, were more densely distributed and connected, and opened into the marrow cavity with a higher density in hyp-4 than in cnt-4. The canal density and connectivity were also higher in hyp-4 than in cnt-3. The canal diameter, density, and connectivity were smaller in hyp-8 than in cnt-4; however, the densities of endocortical and periosteal canal openings did not differ between hyp-8 and cnt-4. We concluded that chronic hypoxia enhanced the formation of cortical canal networks at the postnatal developmental stage, probably facilitating intra- and transcortical vascularization and bone perfusion accordingly.

Young, adult, and old rats have similar changes in mRNA expression of many skeletal genes after fracture despite delayed healing with age

Genes active in fracture healing are not well understood. Because age slows skeletal repair, the change in gene expression between animals of differing ages may illuminate novel pathways important to this healing response. To explore this, 6-, 26-, and 52-week-old female Sprague-Dawley rats were subjected to mid-diaphyseal femoral fracture with intramedullary fixation. The fracture callus was collected at 0, 0.4 (3 days), 1, 2, 4, or 6 weeks after fracture. RNA was extracted and pooled between two animals for each sample. Three samples were done for each time point for each age for a total of 54 Affymetrix U34A GeneChip microarrays. Of the 8700 genes on each array, 3300 were scored as present. Almost all of these genes were affected by femoral fracture with either upregulation or downregulation in the 6 weeks after fracture. Upregulated genes included markers for matrix genes for both cartilage and bone, osteoblasts, osteocytes, osteoclasts, fibroblasts, and mast cells. Downregulated genes included genes related to blood cell synthesis. Nearly all genes presently associated with bone metabolism showed the same response to fracture healing regardless of the age of the animal. In conclusion, skeletal fracture led to similar changes in RNA expression for most skeletal genes despite the delay in the formation of bone to bridge the fracture gap in old rats. Defects in the healing of skeletal trauma in older rats may lie in systems not normally studied by skeletal biologists.

Gene expression during fracture healing in rats comparing intramedullary fixation to plate fixation by DNA microarray

OBJECTIVE

This study was designed to compare mRNA gene expression in healing diaphyseal femoral fractures between those injuries treated with intramedullary nails and those treated with internal plate fixation.

DESIGN

RNA gene expression was measured at 1 day, 3 days, and 1, 2, 4, and 6 weeks after surgery in the fracture callus of rats randomized to femoral shaft fracture with intramedullary nail fixation, rigid plate fixation, or sham fracture.

SETTING

AAALAC-accredited vivarium of an independent academic medical center.

ANIMALS

Fifty-seven, adult, female, Sprague-Dawley rats at 16 weeks of age.

INTERVENTION

Femoral fracture with intramedullary nail fixation, femoral fracture with plate and screw fixation, or sham surgery with no fracture.

MAIN OUTCOME MEASUREMENTS

RNA expression for 8700 genes was measured with 19 Affymetrix U34A microarrays. The fracture callus was significantly larger with intramedullary nail fixation than with plate fixation. Most genes responded to fracture with a change in mRNA expression. Most of the responding genes followed the same time course for both fixation methods. This included genes related to growth factors, bone matrix, mast cells, most nerve factors, and hematopoiesis. The intramedullary nail group had significantly greater up-regulation for transcripts related to cartilage, cell division, inflammation, and the acetylcholine receptor. There was significantly greater up-regulation in the plate group for genes related to macrophage activity.

CONCLUSIONS

There were differentially expressed genes present between the 2 surgical groups that may give insight into the control of fracture repair.