分析化学
分析化學
분석화학
CHINESE JOURNAL OF ANALYTICAL CHEMISTRY
2010年
2期
245-248
,共4页
孙秀兰%汪忠云%方银军%陈佩佩%李在均
孫秀蘭%汪忠雲%方銀軍%陳珮珮%李在均
손수란%왕충운%방은군%진패패%리재균
黄曲霉毒素%免疫传感器%交流阻抗%溶胶凝胶
黃麯黴毒素%免疫傳感器%交流阻抗%溶膠凝膠
황곡매독소%면역전감기%교류조항%용효응효
Aflatoxin B_1%Ιmmunosensor%Εlectrochemical impedance spectroscopy%Sol-gel
利用溶胶凝胶法,将正硅酸乙酯在HCl存在下水解形成的硅溶胶和黄曲霉毒素B_1抗体的混合液涂于玻碳电极表面, 制备非标记型电化学阻抗免疫传感器.以[Fe(CN)_6]~(3-/4-)的磷酸盐缓冲溶液为测试底液,分别研究传感器的循环伏安和交流阻抗行为.实验表明,电极因免疫反应所形成的复合物阻碍了[Fe(CN)_6]~(3-/4-)在电极表面的扩散), 其氧化还原峰电流明显减小,电子转移阻抗随黄曲霉毒素浓度增加而线性增大.当介质pH=6.5和孵育时间为20 min时,免疫前后传感器的电子转移阻抗变化值最大.在此最佳条件下,传感器电子转移阻抗对黄曲霉毒素响应的线性范围为1.0~10 μg/L;检出限为0.1 μg/L(S/N=3).此方法具有高的灵敏度和稳定性,可应用于食品中黄曲霉毒素的测定.
利用溶膠凝膠法,將正硅痠乙酯在HCl存在下水解形成的硅溶膠和黃麯黴毒素B_1抗體的混閤液塗于玻碳電極錶麵, 製備非標記型電化學阻抗免疫傳感器.以[Fe(CN)_6]~(3-/4-)的燐痠鹽緩遲溶液為測試底液,分彆研究傳感器的循環伏安和交流阻抗行為.實驗錶明,電極因免疫反應所形成的複閤物阻礙瞭[Fe(CN)_6]~(3-/4-)在電極錶麵的擴散), 其氧化還原峰電流明顯減小,電子轉移阻抗隨黃麯黴毒素濃度增加而線性增大.噹介質pH=6.5和孵育時間為20 min時,免疫前後傳感器的電子轉移阻抗變化值最大.在此最佳條件下,傳感器電子轉移阻抗對黃麯黴毒素響應的線性範圍為1.0~10 μg/L;檢齣限為0.1 μg/L(S/N=3).此方法具有高的靈敏度和穩定性,可應用于食品中黃麯黴毒素的測定.
이용용효응효법,장정규산을지재HCl존재하수해형성적규용효화황곡매독소B_1항체적혼합액도우파탄전겁표면, 제비비표기형전화학조항면역전감기.이[Fe(CN)_6]~(3-/4-)적린산염완충용액위측시저액,분별연구전감기적순배복안화교류조항행위.실험표명,전겁인면역반응소형성적복합물조애료[Fe(CN)_6]~(3-/4-)재전겁표면적확산), 기양화환원봉전류명현감소,전자전이조항수황곡매독소농도증가이선성증대.당개질pH=6.5화부육시간위20 min시,면역전후전감기적전자전이조항변화치최대.재차최가조건하,전감기전자전이조항대황곡매독소향응적선성범위위1.0~10 μg/L;검출한위0.1 μg/L(S/N=3).차방법구유고적령민도화은정성,가응용우식품중황곡매독소적측정.
In the presence of hydrochloric acid, tetraethoxysilicane was hydrolyzed and formed silica sol. Non-labeled immunosensor was fabricated by droping the mixture solution of the silica sol and antibody of aflatoxin B_1 on the surface of glassy carbon electrode. In this work, a Fe(CN)_6~(3-/4-) phosphate buffer solution) was employed as base solution for investigating cyclic voltammetry(CV) and electrochemical impedance spectroscopic(EIS) performances of the sensor, respectively. The experimental results t indicated that because of the complex formed by the immunoreaction hindered the diffusion of Fe(CN)_6~(3-/4-) on the electrode surface, the redox peak current of the immunosensor in CV obviously decreased, and its electron transfer impedance linearly) increased with increasing the concentration of aflantoxin B_1(AFB). When the medium acidit and incubation) time were pH 6.5 and 20 min, respectively, the biggest electron transfer impedance changed value before and after the immunoreaction was obtained. Under the optimal conditions, a linear range to concentration of aflatoxin B_1 was 1-10 μg/L with a detection limit of 0.1 μg/L(S/N=3). Proposed method is of high sensitivity and stability, it has been successfully applied to determine AFB_1 in maize, rice and peanut.
