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Kang, H-S,Kim, Y-H,Lee, C-S,Lee, J-J,Choi, I.,Pyun, K-H 충남대학교 약학대학 의약품개발연구소 1997 藥學論文集 Vol.13 No.-
DEREGULATION of interleukin-6 (IL-6) expression caused the synthesis and release of many inflammatory mediators. It is involved in chronic inflammation, autoimmune diseases, and malignancy. Stephania tetrandra S. Moore is a Chinese medicinal herb which has been used traditionally as a remedy for neuralgia and arthritis in China. To investigate the anti-inflammatory effects of S. tetrandra S. Moore in vitro and in vivo, its effects on the production of Il-6 and inflammatory mediators were analysed. When human monocytes/macrophages stimulated with silica were treated with 0.1-10 ㎍/㎖ S. tetranda S. Moore, the production of IL-6 was inhibited up to 50%. At these concentrations, it had no cytotoxicity effect on these cells. It also suppressed the production of Il-6 by alveolar macrophages stimulated with silica. In addition, it inhibited the release of superoxide anion and hydrogen peroxide from human monocytes/macrophages. To assess the anti-fibrosis efects of S. tetrandra S. Moore, its effects on in vivo experimental inflammatory models were evaluated. In the experimental silicosis model, IL-6 activities in the sera and in the culture supernatants of pulmonary fibroblasts were also inhibited by it. In vitro and in vivo treatment of S. tetrandra S. Moore reduced collagen production by rat lung fibroblasts and lung tissue. Also, S. tetrandra S. Moore reduced the levels of serum GOT and GPT in the rat cirrhosis model induced by CCl_4, and it was effective in reducing hepatic fibrosis and nodular formation. Taken together, these data indicate that it has a potent antiinflammatory and anti-fibrosis effect by reducing IL-6 production.
Shin, S.W.,Suryawanshi, M.P.,Hong, H.K.,Yun, G.,Lim, D.,Heo, J.,Kang, S.H.,Kim, J.H. Pergamon Press 2016 ELECTROCHIMICA ACTA Vol.219 No.-
An array of one dimensional (1D) TiO<SUB>2</SUB> nanorods (TONRs) has been regarded as an attractive candidate for electrochemical energy conversion and as storage device due to its large surface area, effiective light scattering, and undisturbed charge transport pathway. However, the high defect/trap densities on surface of the nanostructured morphology and architecture may generally hinder the performance enhancement by providing electron-hole recombination sites. Hence, the surface passivation of nanoarchitectures based photoelectrodes has recently received much attention as an effective strategy to enhance the charge-separation and charge-transfer processes in photoelectrochemical (PEC) water splitting devices. In particular, a coating layer with narrowing band gap materials can promote enhanced light harvesting in the UV-vis region as well as surface passivation, directly supplying a driving force for charge separation and charge transfer due to band alignment. In this paper, the surface of TONRs were passivated by 10 and 30nm thick Zn(O,S) layers with a relatively narrow band gap using an atomic layer deposition technique to modulate the thickness exactly. The 10nm Zn(O,S)/TONR array exhibits a significantly enhanced photocurrent density (J<SUB>sc</SUB>) of 5.94mA/cm<SUP>2</SUP> at 1.23eV vs NHE and an incident photon-to-electron conversion efficiency (IPCE) of 49% at 374nm compared with that of TONR arrays (J<SUB>sc</SUB> of 1.99mA/cm<SUP>2</SUP> at 1.23eV vs NHE and an IPCE of 20% at 380nm). However, the PEC performance is worse in the 30nm Zn(O,S)/TONR arrays, showing a J<SUB>sc</SUB> of 3.09mA/cm<SUP>2</SUP> at 1.23eV vs NHE and an IPCE of 29% at 374nm. To clearly demonstrate these PEC behaviors, the TONR and Zn(O,S)/TONR arrays were characterized by electrochemical impedance spectroscopy (EIS), open circuit voltage decay (OCV) measurement, and X-ray photoelectron spectroscopy (XPS). The above mentioned characterizations indicate that the enhanced PEC performance of the 10nm Zn(O,S)/TONR array resulted from the (i) increased light harvesting in the UV-vis region, (ii) lower charge transfer resistance and (iii) high value of valence band offset (VBO, -1.44eV) and conduction band offset (CBO, -1.2eV) than those of the TONR. However, the deterioration of J<SUB>sc</SUB> in the 30nm Zn(O,S)/TONR array is attributed to the negative value of VBO (-0.13eV) and positive value of CBO (+0.27eV), as well as the higher charge transfer resistance to the electrolyte than that of the TONR arrays, despite of the improved light absorption in the visible region. The photocurrent densities of 10nm Zn(O,S)/TONR and 30nm Zn(O,S)/TONR photocathodes decay to 4.718mA/cm<SUP>2</SUP> (5.90mA/cm<SUP>2</SUP> at 0min) and 2.212mA/cm<SUP>2</SUP> (3.03mA/cm<SUP>2</SUP> at 0min) after 90min, respectively, they retain of about~80% and 70% of its original values. These experimental results and discussions not only provide the physical insights into the surface passivation effect and band alignment but also can open a promising route to design the thin passivation layer having the narrowing band gap energy (1.0eV~2.5eV) on the 1D TiO<SUB>2</SUB> nanostructure for further enhanced performance and realization of a TiO<SUB>2</SUB> based PEC system.