Magnetic field-induced one-magnon Raman scattering in the magnon Bose-Einstein condensation phase of TlCuCl3_{3}

We report the observation of the $A_{\rm g}$-symmetric one-magnon Raman peak in the magnon Bose-Einstein condensation phase of TlCuCl$_{3}$. Its Raman shift traces the one-magnon energy at the magnetic $\Gamma$ point, and its intensity is proportional to the squared transverse magnetization. The appearance of the one-magnon Raman scattering originates from the exchange magnon Raman process and reflects the change of the magnetic-state symmetry. Using the bond-operator representation, we theoretically clarify the Raman selection rules, being consistent with the experimental results.Comment: 6 pages, 4 figure

Low-density lipoprotein receptors play an important role in the inhibition of prostate cancer cell proliferation by statins

AbstractBackgroundThere are some reports about the antitumor effects of statins in these days. Statins decrease the level of cholesterol in the blood by inhibiting 3-hydroxy-3-methylglutaryl-coenzyme A reductase. Inhibition of this enzyme decreases intracellular cholesterol synthesis. Thus, the expression of low-density lipoprotein receptor (LDLr) is increased to import more cholesterol from the bloodstream. In this study, we assessed the effects of statins on the proliferation of prostate cancer cells, and studied the relationship between the expression of LDLr and the effects of statins.MethodsSimvastatin was used in the experiments. We studied the effect of simvastatin on PC-3 and LNCaP cell proliferation using the MTS assay, and evaluated the expression of LDLr after administration of simvastatin by quantitative polymerase chain reaction and Western blotting. Intracellular cholesterol levels in the prostate cancer cells were measured after administration of simvastatin. Furthermore, small interfering RNA (siRNA) was used to knockdown the gene expression of LDLr.ResultsIn PC-3 cells, simvastatin inhibited cell proliferation. In LNCaP cells, only a high concentration of simvastatin (100μM) inhibited cell proliferation. In LNCaP cells, the protein level of LDLr was increased by simvastatin. In PC-3 cells, the protein levels of LDLr were unregulated. In PC-3 cells, but not in LNCaP cells, intracellular cholesterol levels were significantly decreased by simvastatin. After knocking down LDLr expression by siRNA, intracellular cholesterol levels were decreased, and cell proliferation was inhibited by simvastatin in LNCaP cells.ConclusionSimvastatin inhibited prostate cancer cell growth by decreasing cellular cholesterol and could be more effective in androgen-independent prostate cancer, where there is loss of regulation of LDLr expression. LDLr was shown to play an important role in the statin-induced inhibition of prostate cancer cell proliferation. These results suggest that future studies evaluating the cholesterol-lowering effects of statin may lead to new approaches to the prevention and treatment of prostate cancer

Capillary Networks for Bio-Artificial Three-Dimensional Tissues Fabricated Using Cell Sheet Based Tissue Engineering

One of the most important challenges facing researchers in the field of regenerative medicine is to develop methods to introduce vascular networks into bioengineered tissues. Although cell scaffolds that slowly release angiogenic factors can promote post-transplantation angiogenesis, they cannot be used to construct thick tissues because of the time required for sufficient vascular network formation. Recently, the co-culture of graft tissue with vascular cells before transplantation has attracted attention as a way of promoting capillary angiogenesis. Although the co-cultured vascular cells can directly contribute to blood vessel formation within the tissue, a key objective that needs to be met is the construction of a continuous circulatory structure. Previously described strategies to reconstruct blood vessels include the culture of endothelial cells in a scaffold that contains microchannels or within the original vascular framework after decellularization of an entire organ. The technique, as developed by authors, involves the progressive stacking of three-layered cell sheets onto a vascular bed to induce the formation of a capillary network within the cell sheets. This approach enables the construction of thick, functional tissue of high cell density that can be transplanted by anastomosing its artery and vein (provided by the vascular bed) with host blood vessels

A novel alveolar epithelial cell sheet fabricated under feeder-free conditions for potential use in pulmonary regenerative therapy

INTRODUCTION: Lung transplantation is the only effective treatment option for many patients with irreversible pulmonary injury, and the demand for lung transplantation is increasing worldwide and expected to continue to outstrip the number of available donors. Regenerative therapy with alveolar epithelial cells (AECs) holds promise as an alternative option to organ transplantation. AECs are usually co-cultured with mouse-derived 3T3 feeder cells, but the use of xenogeneic tissues for regenerative therapy raises safety concerns. Fabrication of AEC sheets under feeder-free conditions would avoid these safety issues. We describe a novel feeder-free method of fabricating AEC sheets that may be suitable for pulmonary regenerative therapy. METHODS: Lung tissues excised from male outbred rats or transgenic rats expressing green fluorescent protein (GFP) were finely minced and dissociated with elastase. The isolated AECs were cultured under four different feeder-free conditions according to whether a rho kinase (ROCK) inhibitor was included in the low-calcium medium (LCM) and whether the tissue culture dish was coated with recombinant laminin-511 E8 fragment (rLN511E8). The expanded cells were cultured on temperature-responsive dishes and subsequently harvested as AEC sheets. Engraftment of GFP-AEC sheets after their transplantation onto a partially resected region of the left lung was assessed in athymic rats. RESULTS: AECs proliferated and reached confluence when cultured in LCM containing a ROCK inhibitor on tissue culture dishes coated with rLN511E8. When both the ROCK inhibitor and rLN511E8-coated culture dish were used, the number of AECs obtained after 7 days of culture was significantly higher than that in the other three groups. Immunohistochemical analyses revealed that aquaporin-5, surfactant protein (SP)-A, SP-C, SP-D and Axin-2 were expressed by the cultured AECs. AEC sheets were harvested successfully from temperature-responsive culture dishes (by lowering the temperature) when the expanded AECs were cultured for 7 days in LCM + ROCK inhibitor and then for 3 days in LCM + ROCK inhibitor supplemented with 200 mg/L calcium chloride. The AEC sheets were firmly engrafted 7 days after transplantation onto the lung defect and expressed AEC marker proteins. CONCLUSIONS: AEC sheets fabricated under feeder-free conditions retained the features of AECs after transplantation onto the lung in vivo. Further improvement of this technique may allow the bioengineering of alveolar-like tissue for use in pulmonary regenerative therapy