查詢結果分析
來源資料
相關文獻
- 不同莫耳濃度之氯化亞鐵四水合物與氯化鐵六水合物製備之磁性奈米粒子在腫瘤熱治療效益之探討
- 電磁場概論與暴露限制標準
- 電磁場實務與標準:第一部份--電磁場實務
- 電磁場實務與標準:第二部份--人體暴露限制值
- A Modified Method of Dextran-coated Fe₃O₄ Magnetic Nanoparticles by One-step and Two-step Synthetic Pathways
- 界面活性劑葡聚醣披覆四氧化三鐵磁性奈米粒子之製備及其特性之研究
- 射頻電流導引結構應用於可切換式天線輻射場形及改善天線SAR特性
- 新式手持端MIMO裝置降低SAR值導波護蓋
- 超音波振盪對四氧化三鐵磁性奈米粒子之加熱比吸收率影響之研究
頁籤選單縮合
題名 | 不同莫耳濃度之氯化亞鐵四水合物與氯化鐵六水合物製備之磁性奈米粒子在腫瘤熱治療效益之探討=Study on the Effect of Magnetic Fluid Hyperthermia by Using Ferrous Chloride Tetrahydrate and Ferric Chloride Hexahydrate with Different Molarities |
---|---|
作者姓名(中文) | 蔡長書; 陳弘一; | 書刊名 | 慈濟技術學院學報 |
卷期 | 20 2013.03[民102.03] |
頁次 | 頁1-20 |
分類號 | 440.34 |
關鍵詞 | 氯化亞鐵四水合物; 氯化鐵六水合物; 莫耳濃度; 比吸收率; 磁流體熱治療; Ferrous chloride tetrahydrate; Ferric chloride hexahydrate; Molarity; Specific adsorption rate; Magnetic fluid hyperthermia; MFH; |
語文 | 中文(Chinese) |
中文摘要 | 本文首先以不同鐵化合物材料及不同莫耳濃度比值,製備磁性奈米粒子磁流體並探討其腫瘤熱治療(magnetic fluid hyperthermia, MFH)之效益。氯化亞鐵四水合物(FeCl2·4H2O)與氯化鐵六水合物(FeCl3·6H2O)所製備之磁性奈米粒子,於Fe2+:Fe3+=1:1、1:1.5 與1:2 有最高之SAR 值,其分別為84.7±12.7、93.4±14.2、89.2±6.4 W/g。氯化亞鐵四水合物與硝酸亞鐵九水合物所製備之磁性奈米粒子,於Fe2+與Fe3+莫耳數比等於1:1 時,有最高之SAR 值(28.5±1.9W/g)。以硫酸亞鐵七水合物與氯化鐵六水合物所製備之磁性奈米粒子,於Fe2+:Fe3+ = 1:2.5、2.5:1、3:1 時有最高比吸收率(SAR)值,其分別為62.0±6.5、59.4±10.3、66.0±5.0 W/g。硫酸亞鐵七水合物與硝酸亞鐵九水合物所製備之磁性奈米粒子,於Fe2+:Fe3+=2.5:1、3:1 有最高之SAR 值,其分別為66.6±7.0、63.5±6.0 W/g。由實驗結果得知,在製備之磁流體中,Fe2+與Fe3+莫耳數比,及不同鐵化合物材料明顯影響比吸收率值。以氯化亞鐵四水合物與硝酸亞鐵九水合物製備之磁性奈米粒子,其SAR 值最低,加熱效率經評估最差。硫酸亞鐵七水合物與氯化鐵六水合物;及硫酸亞鐵七水合物與硝酸亞鐵九水合物之結果並無太大差異。 以氯化亞鐵四水合物與氯化鐵六水合物所製備之磁性奈米粒子,鐵離子莫耳數比值為1:1.5,可獲最高之SAR 值,評估在腫瘤熱治療加熱效率經最佳。 |
英文摘要 | The effect of magnetic fluid hyperthermia were evaluated by using ferrous chloride tetrahydrate and ferric chloride hexahydrate with different molarity in this work. We also compare the other iron compounds including iron(III)nitrate 9-hydrate, ferrous sulfate 7-hydrate. The SAR values of ferrofluids were found to be 84.7±12.7, 93.4±14.2 and 89.2±6.4 W/g, respectively, when prepared by using ferrous chloride tetrahydrate (FeCl2· 4H2O) and ferric chloride hexahydrate (FeCl3· 6H2O), with the 1:1, 1:1.5 and 1:2 ratio of iron compound’s molarity . The highest SAR (specific adsorption rate) value of ferrofluid was found to be 28.5±1.9W/g , when prepared by using ferrous chloride tetrahydrate (FeCl2·4H2O) and iron(III)nitrate 9-hydrate(Fe(NO3)3· 9H2O) with the 1:1 ratio of iron compound’s molarity. The SAR values of ferrofluids were found to be 62.0±6.5, 59.4±10.3, and 66.0±5.0 W/g, respectively, when prepared by using ferrous sulfate 7-hydrate (FeSO4· 7H2O) and ferric chloride hexahydrate (FeCl3· 6H2O) with the 1:2.5, 2.5:1, and 3:1 ratio of iron compound’s molarity . The SAR values of ferrofluids were found to be 66.6±7.0 and 63.5±6.0 W/g respectively, when prepared by using ferrous sulfate 7-hydrate (FeSO4· 7H2O) and iron(III)nitrate 9-hydrate (Fe(NO3)3· 9H2O), with the 1:1, 1:1.5 and 1:2 ratio of iron compound’s molarity . The highest SAR value of ferrofluid is 93.4±14.2 W/g when prepared by using ferrous chloride tetrahydrate and ferric chloride hexahydrate with the 1:1.5 ratio of iron compound’s molarity . The heating quality of ferrofluid for magnetic fluid hyperthermia is better when comparing with other iron compounds . |
本系統之摘要資訊系依該期刊論文摘要之資訊為主。