Porous scaffolds with tailored reactivity modulate in-vitro osteoblast responses.

CaSiO3 (CS) ceramic has been extensively studied for biomedical applications. The main advantages are its ability to induce bone-like apatite formation and the beneficial effects of the dissolution products on the bone cells, resulting from high reactivity of CS in liquid solutions. However, the high reactivity also results in a rapid degradation rate and accordingly leads to a high pH value in the body fluid, adversely affecting bone cell responses, especially when CS is used as a highly porous scaffold. In this study, we provide an approach to minimize this pH-dependent cell damage and maximize the beneficial effects of the dissolution products of the CS scaffold by adding chemically stable and biocompatible Zn-containing hardystonite (Ca2ZnSi2O7, HT) into the CS scaffold, the resultant composite scaffold is referred to as HT-CS. We investigated the responses of primary human osteoblasts (HOBs) to the CS, HT and the HT-CS scaffolds. HOBs on HT and HT-CS scaffolds attached better than on the CS scaffold. HOBs cultured on the HT-CS scaffolds expressed higher gene expression levels for Runx-2, osteopontin (OPN), osteocalcin (OCN), bone sialoprotein (BSP), and collagen type I (Col-I) and enhanced alkaline phosphatase (ALP) activity compared to those on the CS and HT scaffolds. The higher activity of the HOBs cultured on the HT-CS scaffold was ascribed to the moderate pH variation and the dissolution products containing Ca, Si and Zn.

Physical properties of root cementum: part 20. Effect of fluoride on orthodontically induced root resorption with light and heavy orthodontic forces for 4 weeks: a microcomputed tomography study.

INTRODUCTION: The major side effect of orthodontic treatment is orthodontically induced inflammatory root resorption. Fluoride was previously shown to reduce the volume of the root resorption craters in rats. However, the effect of fluoride on orthodontically induced inflammatory root resorption in humans has not yet been investigated. The aim of this study was to investigate the effect of high and low amounts of fluoride intake from birth on orthodontically induced inflammatory root resorption under light (25 g) and heavy (225 g) force applications. METHODS: Forty-eight patients who required maxillary premolar extractions as part of their orthodontic treatment were selected from 2 cities in Turkey with high and low fluoride concentrations in the public water of ≥ 2 and ≤ 0.05 ppm, respectively. The patients were randomly separated into 4 groups of 12 each: group 1, high fluoride intake and heavy force; group 2, low fluoride intake and heavy force; group 3, high fluoride intake and light force; and group 4, low fluoride intake and light force. Light or heavy buccal tipping orthodontic forces were applied on the maxillary first premolars for 28 days. At day 28, the teeth were extracted, and the samples were analyzed with microcomputed tomography. RESULTS: Fluoride reduced the volume of root resorption craters in all groups; however, this effect was significantly different with high force application (P = 0.015). It was also found that light forces caused less root resorption than heavy forces. There was no statistical difference in the amount of root resorption observed on root surfaces (buccal, lingual, mesial, and distal) in all groups. However, the middle third of the roots showed the least root resorption. With high fluoride intake and heavy force application, less root resorption was found in all root surfaces and root thirds. CONCLUSIONS: Fluoride may reduce the volume of root resorption craters. This effect is significant with heavy force applications (P <0.05). The cervical and apical thirds of the root showed significantly greater root resorption after the application of buccal tipping force for 4 weeks.

Three dimensional microvascular measurements in human endometrium using optical slices from laser scanning confocal microscopy (LSCM).

There is increasing interest in the structure of the microvascular environment in human endometrium because of the recognition of the complexity and functional importance of this tissue. Endometrial microcirculatory networks and their relationships have rarely been studied in three-dimensions. Longitudinal uterine slices containing endometrial tissue were carefully selected from women undergoing a hysterectomy. Formalin-fixed endometrial sections (≤ 50 µm) representing the fundal and isthmic regions were immunofluorescently labeled with monoclonal antibody (CD34) to target the endothelium of microvessel and fluorescein isothiocyanate (FITC) labeled goat anti-mouse. Digital images were acquired using a Nikon Eclipse E800 microscope equipped with a Radiance 2000 confocal scanning laser attachment. ImarisBasic 4.1 visualization suite was utilized for qualitative interpretation. NeuronTracer 1.0 software was utilized to derive the length and numerical densities. There were significant changes across the phases of the menstrual cycle in functional and basal endometrial layers in vessel length density (LD(v)) and branch point density (ND(v)) within both fundal and isthmic regions of the uterus (P<0.001). There was also a significant effect of menstrual cycle phase on mean vessel segment length (SL(v)) within each region and within each of the layers (P<0.001). The capillary radial diffusion distance r(diff) was negatively correlated with LD(v). In general, within each of the menstrual cycle phases, LD(v), ND(v) were greater in the fundal than the isthmic regions while, in contrast, SL(v) was found to be greatest in the isthmic region. Utilization of immunofluorescence and laser scanning confocal microscopy has enabled us to demonstrate significant vascular changes in human endometrial layers illustrating that in general, within each of the menstrual cycle phases, vessel length and branch point densities were greater in the fundal than the isthmic regions, while vessel segment lengths were found to be greatest in the isthmic region.