47,366 research outputs found

    4-Hydroxybenzoic acid serves as an endogenous ring precursor for antroquinonol biosynthesis in Antrodia cinnamomea

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    Chou, Kevin Chi-Chung, Wu, Hsiang-Lin, Lin, Pei-Yin, Yang, Shang-Han, Chang, Tsu-Liang, Sheu, Fuu, Chen, Kai-Hsien, Chiang, Been-Huang (2019): 4-Hydroxybenzoic acid serves as an endogenous ring precursor for antroquinonol biosynthesis in Antrodia cinnamomea. Phytochemistry 161: 97-106, DOI: 10.1016/j.phytochem.2019.02.011, URL: http://dx.doi.org/10.1016/j.phytochem.2019.02.01

    [[alternative]]The Reaserch of the Role and Function in Administrative Corporation of the National Chiang Kai Shek Cultural Center

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    [[abstract]]In 1975, Chiang Kai Shek Memorial Hall was established as the first national performing arts center in memory of the former president Chang Kai-Shek. However, this organization had not been granted a decided status because of the limitation of the administration organization system and lots of laws until the year of 1992 when it was officially named National Chiang Kai Shek Cultural Center. Afterward, its system was assessed many times in order to go with the international trend and domestic opinion; then the Administrative Corporation was passed by the Executive Yuan at the Third Reading on January 9, 2004. Through this system, the only international performing arts center in Taiwan was reformed and its long-term problem of uncertain status was also solved on March 1, 2004. In this research, I want to probe into the different roles and functions before and after the Administrative Corporation in National Chiang Kai Shek Cultural Center through literature analysis and deep interview. Besides, I hope to collect opinions and advices from related arts groups, scholars and experts in order to get the best conclusion and suggestion. By literature analysis and deep interview, I find National Chiang Kai Shek Cultural Center has more different roles after the Administrative Corporation, but it is still not fully- functioned, especially as a broker to business and government. In the part of Future Envision, non-governmental performing arts groups have great expectations to National Chiang Kai Shek Cultural Center. In sum, non-governmental performing arts groups approve Administrative Corporation of National Chiang Kai Shek Cultural Center, and they think there are gap between the former and later roles of National Chiang Kai Shek Cultural Center.

    Mechanistic Study of Apatite Formation on Bioactive Glass Surface Using Solid-State NMR Spectroscopy

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    生物活性玻璃是一種70年代初期發現的材料,因為其在身體的環境中能夠與體內組織相連結的緣故而得名。此種材料的組成多為矽酸鹽與氧化鈣或是氧化鈉的非晶相混合物,在身體的環境中會在材料表面誘發羥基磷灰石的成長,而進一步與骨骼等組織相連結。目前已經成功的通過多種骨骼取代及骨骼缺陷填補的臨床測試。 文獻上對於羥基磷灰石在生物活性玻璃表面的生長機制有不同的意見:一種是先誘發非晶相礦物質層的沉積而進一步結晶,另一種是材料表面生成活化位置直接誘發晶體的成長。在本篇論文中,我們採用固態核磁共振來深入探討矽鈣玻璃生物活性的形成機制,因為技術上,許多不同的脈衝序列可以成功的測量系統中同核或是異核之空間環境。在生物活性玻璃的合成上,我們使用溶凝膠法合成出2-3微米的矽鈣玻璃系統,內含30%氧化鈣及70%氧化矽。將此系統浸泡在模擬體液中不同的時間,以觀測羥基磷灰石的成長。除了使用文獻中的一些常規技術做定性的測量外,我們採用許多先進的固態核磁共振技術,如雙共振、雙量子技術測量材料表面的化學環境。 實驗結果支持先誘發非晶相礦物質層的沉積而進一步結晶的反應機制。我們發現在晶體成長的過程中涉及到礦物質的脫水。實驗結果也顯示此結晶相與B類碳酸鹽磷灰石不同,但是與羥基磷灰石相似。我們相信,此論文所採用的固態核磁共振技術也可以有效地研究其他相類似的生物活性材料。The molecular mechanism of apatite formation on bioactive glass surface is studied using the techniques of XRD, EDX, SEM, FT-IR, and solid-state NMR. Using the sol-gel method a bioactive glass system containing glass beads of 2 to 3 microns in size is prepared with the composition containing 30 % CaO – 70 % SiO2. Our experimental data support the apatite formation mechanism proposed by Hench concerning the precipitation and crystallization of calcium phosphate. The phosphate ions initially deposited on the glass surface are largely amorphous and have substantial amount of water molecules in the surrounding. As the soaking time in simulated body fluid increases, some of the water molecules diffuse out of the phosphate lattice, leading to the formation of a crystalline phase. Our data show that the structure of the crystalline phase is different from type B carbonate apatite but similar to hydroxyapatite.第1章 緒論............................................1 1-1生物活性玻璃簡介...................................1 1-2生物活性簡介.......................................2 1-3研究動機與目的.....................................5 1-4參考文獻...........................................7 第2章 核磁共振.......................................11 2-1 核磁共振簡介.....................................11 2-2 核磁共振系統的量子力學敘述.......................12 2-2-1 核自旋(Nuclear spin)...........................12 2-2-2 塞曼交互作用(The Zeeman Interaction)...........13 2-2-3 密度矩陣(The density matrix)...................14 2-2-4 熱平衡下的密度矩陣.............................16 2-2-5 密度操作子之運動方程...........................17 2-3 簡單的核磁共振實驗...............................18 2-4 系統間相互作用力.................................21 2-4-1 化學遮蔽作用力.................................21 2-4-2 核間偶極-偶極直接交互作用......................22 2-4-2-1 異核偶極-偶極交互作用........................23 2-4-2-2 同核偶極-偶極交互作用........................23 2-5 魔角旋轉.........................................24 2-6 自旋空間平均化...................................25 2-6-1 相互作用座標...................................25 2-6-2 自旋去耦.......................................26 2-6-3 自旋鎖定(Spin Locking).........................27 2-6-4 Lee-Goldburg照射...............................28 2-7 極化傳遞.........................................29 2-7-1 同核自旋的極化傳遞.............................29 2-7-2 異核自旋的極化傳遞.............................29 2-7-3 在魔角旋轉下的Hartmann-Hahn配對................30 2-7-4 自旋溫度.......................................31 2-7-5 變接觸時間交叉極化魔角旋轉實驗.................32 2-8 雙量子相干.......................................33 2-8-1 雙量子訊號.....................................33 2-8-2 雙量子訊號的激發、演進和偵測...................34 2-8-3同核多量子技術..................................35 2-9 參考文獻.........................................36 第3章 合成與鑑定.....................................38 3-1 化學藥品.........................................38 3-2生物活性玻璃的製備................................39 3-2-1 膠體合成與老化(Aging)..........................39 3-2-2 膠體的乾燥.....................................40 3-2-3 矽鈣玻璃系統穩定化.............................41 3-3 玻璃的鑑定.......................................42 3-3-1 X光繞射分析(XRD)...............................42 3-3-2 傅利葉紅外光光譜(FT-IR)........................43 3-3-3 比表面積孔洞分析儀.............................43 3-3-4 感應耦合電漿質譜...............................46 3-3-5場發射掃描式電子顯微鏡及能量分散光譜儀…........47 3-3-6 熱重分析及低溫熱差分析儀.......................49 3-4 生物活性.........................................50 3-4-1 配製模擬體液...................................50 3-4-2 浸泡模擬體液...................................51 3-5 31P固態核磁共振光譜..............................51 3-5-1 31P魔角旋轉光譜................................52 3-5-2變接觸時間31P{1H}交叉極化魔角旋轉實驗….........52 3-5-3 31P{1H}Lee-Goldburg交叉極化雙共振關聯光譜......52 3-5-4 31P雙量子實驗..................................53 3-6 29Si魔角旋轉光譜.................................54 3-7 29Si{1H}交叉極化雙共振實驗.......................55 3-8 參考文獻.........................................55 第4章 實驗結果與討論.................................56 4-1 玻璃製備.........................................56 4-2 SEM、EDX和BET比表面積............................57 4-3 FT-IR和XRD.......................................59 4-4熱重分析和熱差分析................................61 4-5感應耦合電漿質譜..................................64 4-6 31P 魔角旋轉NMR..................................65 4-7 31P{1H}Lee-Goldburg交叉極化雙共振實驗............66 4-8 31P{1H}變化傳遞時間的交叉極化魔角旋轉實驗........71 4-9 31P雙量子NMR.....................................73 4-10 29Si魔角旋轉NMR.................................76 4-11 29Si{1H}交叉極化雙共振實驗......................77 4-12 討論............................................83 4-12-1 球狀生物活性玻璃..............................83 4-12-2 31P{1H}LG交叉極化雙共振光譜...................84 4-12-3 31P-31P二階偶極矩.............................85 4-12-4羥基磷灰石的成長...............................86 4-13 參考文獻........................................89 第5章 總結與未來展望.................................93 5-1 論文總結.........................................93 5-2 未來展望.........................................94 5-3 參考文獻.........................................95 第6章 附錄...........................................97 6-1 DSC結果討論......................................97 6-2 31P{1H}交叉極化實驗結果討論......................9

    Middle and late Eocene fish otoliths from the eastern and southern USA

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    Lin, Chien-Hsiang, Nolf, Dirk (2022): Middle and late Eocene fish otoliths from the eastern and southern USA. European Journal of Taxonomy 814: 1-122, DOI: 10.5852/ejt.2022.814.1745, URL: http://dx.doi.org/10.5852/ejt.2022.814.174

    Dr. Lin Sun, CAU, March 2013

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    This video is a conversation with Dr. Lin Sun. Dr. Sun talks about an exhibit at the Woodruff Library titled "At The Boundary." Jordan Moore, AUC Woodruff Library, is the interviewer

    Pomadasys quadrilineatus Shen & Lin 1984

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    Pomadasys quadrilineatus Shen & Lin, 1984 (Fig. 3d; no. 7–8 in pl. 1) Material examined. — 2 sagittae (NMMBOL 0799, 1007). Description. — Oval to oblong shape, slightly convex medial face and slightly concave lateral face. Dorsal margin slightly irregular and ventral margin rounded and minutely crenate in the middle. Crista superior well developed except for above the anterior cauda, where slightly ridgelike. Dorsal trough visible to crista superior. Crista inferior moderately developed. Cauda straight anteriorly, flexing sharply at two-thirds of the length. Ostium broad, the posteroventral corner wide, pointing posteriorly to form a lobe. Excisural notch absent. Dimensions. — OL, 7.38–7.72 mm; OH, 5.02–5.52 mm; OT, 1.56–1.67 mm; OsL, 2.52–3.09 mm; OsH, 1.76–1.88 mm. Diagnosis. — The broad ostium (caused in part by a deep trough near the dorsal margin of the ostium), with a well-developed posteroventral corner (creating a lobe) is diagnostic. The relative thinness and slender outline of the sagittae are also diagnostic.Published as part of Lin, Chien-Hsiang, Li, Kuang-Ti & Chang, Chih-Wei, 2013, Identification Of Pomadasys Species (Pisces, Haemulidae) From An Archaeological Midden Site In Nankuanli East (Taiwan), Based On Otolith Morphology, pp. 293-302 in Raffles Bulletin of Zoology 61 (1) on page 297, DOI: 10.5281/zenodo.535189

    Bengie Lin and Harry Cockrell at Kai Tak Airport, Hong Kong

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    Bengie Lin and Harry Cockrell at Kai Tak Airport, Hong Kong
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