Spiral surface growth without desorption

Spiral surface growth is well understood in the limit where the step motion is controlled by the local supersaturation of adatoms near the spiral ridge. In epitaxial thin-film growth, however, spirals can form in a step-flow regime where desorption of adatoms is negligible and the ridge dynamics is governed by the non-local diffusion field of adatoms on the whole surface. We investigate this limit numerically using a phase-field formulation of the Burton-Cabrera-Frank model, as well as analytically. Quantitative predictions, which differ strikingly from those of the local limit, are made for the selected step spacing as a function of the deposition flux, as well as for the dependence of the relaxation time to steady-state growth on the screw dislocation density.Comment: 9 pages, 3 figures, RevTe

Deletion of the ghrelin receptor GHSR corrects the trabecular, but not the cortical bone changes in the femoral head of ob/ob mice

Background: There exists an intriguing and complex relationship between fat and bone cells with respect to aging and osteoporosis, which is mediated in part by leptin. Genetically obese mice (ob/ob), that lack leptin, have aheterogeneous bone phenotype, with differential effects on cortical and trabecular compartments. Besides its role in bone metabolism, leptin is most well known for its anorexigenic properties. Opposed in action to leptin is ghrelin, a potent orexigenic peptide hormone derived from the stomach. Ghrelin and leptin also act as each other’s antagonists in gonadal and immune system function.Objective: To determine if ghrelin opposes leptin action on bone metabolism.Methods: Characterization of femoral micro-architecture in 6 months old male wild type, ob/ob, ghrelin receptor knockout (Ghsr -/-), and ob/ob.Ghsr-/- mice using micro-computed tomography.Results: Deletion of Ghsr alone did not significantly alter bone micro-architecture in wild type mice. Deletion of leptin reduced cortical volume and thickness in the femoral head of wild type mice, while it increased endocortical volume. Tissue volume remained unaffected. Conversely, deletion of leptin increased trabecular bone volume, trabecular number and connectivity in wild type mice. Additional deletion of Ghsr in ob/ob mice restored the changes to wild type levels in trabecular bone, but not in cortical bone (all not significant).Conclusion: We found that leptin deficiency has a negative effect on cortical and a positive effect on trabecular bone micro-architecture, confirming the heterogeneous skeletal effects observed by others in ob/ob mice. Knocking out ghrelin signaling compensates for the effect of leptin deficiency on trabecular bone. These observations demonstrate the positive activity of ghrelin signaling in bone, and suggest that ghrelin and leptin have opposing actions on bone metabolism

Gender specific effects of the calcium channel TRPV4 on osteoporotic fracture risk and osteoblast-osteoclast coupling

TRPV4 is a member of the transient receptor potential (TRP) superfamily and responds to an array of stimuli, including osmolarity, pH and pressure. Recent findings showing that TRPV4 deficiency leads to reduced sensing of mechanical stimuli led us to explore the role of TRPV4 in bone. TRPV4 mRNA was abundantly expressed in both osteoblasts and osteoclasts as assessed by qPCR. Femoral cortical and trabecular bone mass as assessed by microcomputed tomography was higher in male TRPV4 knockout mice compared to wild type mice. Despite thicker bone structures, cortical porosity was increased in the male TRPV4 knockout mice leading to reduced bone strength as assessed by 3-point bending. Osteoclast and osteoblast differentiation and function was studied, using bone marrow cultures from wildtype and TRPV4 knockout mice. Osteoclast numbers as well as the formation of resorption pits were significantly reduced in cultures of TRPV4 knockout mice compared to wildtype littermates. In contrast, osteoblast differentiation and matrix mineralization was significantly increased in TRPV4 knockout bone marrow cultures. None of these parameters were significantly different in bones and bone marrow cultures of female knock out mice. These data implicate a gender-specific osteoblast–osteoclast uncoupling and support the observed increase in bone mass in male TRPV4 deficient mice. To assess the possible impact of TRPV4 on osteoporotic outcome in humans, we extracted data from the genome-wide association study within the Rotterdam Study. Two single nucleotide polymorphisms (SNPs) in the TRPV4 gene showed strong associations with osteoporotic fracture risk fragility fracture risk and hip fracture risk in men, but not in women. This was not affected after adjusting for height, weight, age and bone mineral density (BMD). In conclusion, TRPV4 plays an important role in male but not female bone biology. Apparently, the increased periosteal bone apposition fails to overcome the increased cortical porosity, leading to reduced bone strength in TRPV4 deficient male mice. In line with the gender-specific findings in mice, variations in the TRPV4 gene are predicting fracture risk in men but not in women