水产品中氟苯尼考和氟苯尼考胺的高效液相色谱荧光法同时测定

建立了水产品中氟苯尼考和氟苯尼考胺同时检测的高效液相色谱荧光法,以乙腈-磷酸二氢钠溶液(0.01 mol/L,含0.005 mol/L十二烷基硫酸钠和0.10%三乙胺)(体积比2:3)为流动相,流速为0.6 mL/min,荧光检测激发波长为225 nm,发射波长为280 nm.本方法氟苯尼考在10～10 000 μg/L,氟苯尼考胺在2～2 000 μg/L范围内与峰面积呈线性相关,相关系数分别为1和0.999 9.当空白样晶中氟本尼考添加水平为20～200 μg/kg,氟苯尼考胺添加水平为4～50μg/kg时,该方法的回收率为79%～91%,相对标准偏差为3.66%～6.21%,检出限分别为5 μg/kg和1 μg/kg.     

固相萃取-气相色谱法同时检测水产品中的氯霉素、甲砜霉素、氟苯尼考和氟苯尼考胺

建立了同时测定水产品中氯霉素、甲砜霉素、氟苯尼考和氟苯尼考胺的固相萃取-气相色谱方法。用98:2(V/V)的乙酸乙酯和氨水提取鱼体中的氯霉素、甲砜霉素、氟苯尼考和氟苯尼考胺,用MCX固相萃取小柱对提取物进行净化和富集,经98:2(V/V)的甲醇和氨水混合溶液洗脱后氮吹浓缩,并用乙腈复溶,再用BSTFA衍生化和气相色谱仪检测。实验条件下,氯霉素浓度在5~50μg/L范围,甲砜霉素、氟苯尼考和氟苯尼考胺浓度在15~100μg/L范围内线性良好,相关系数分别为0.9909,0.9937,0.9948和0.9916,检出限分别为0.3,1.0,1.0和1.0μg/kg,7次加标回收率为71.8%~105%,相对标准偏差在8.1%~15%之间。     

高效液相色谱荧光检测法同时检测鸡肉中甲砜霉素、氟苯尼考及氟苯尼考胺残留

建立了高效液相色谱荧光法同时检测鸡肉中甲砜霉素、氟苯尼考和氟苯尼考胺残留的新方法。样品经丙酮、二氯甲烷提取,饱和正己烷脱脂,氮吹仪吹干浓缩后,以乙腈-NaH2PO4溶液(0.01 mol/L,含0.005 mol/L十二烷基硫酸钠和0.1％三乙胺)(体积比32：68)为流动相,流速为1.0 mL/min,荧光检测激发波...     

超高效液相色谱-质谱联用检测 土壤中两种抗生素呋喃唑酮和氟苯尼考

建立了超高效液相色谱-串联质谱(UPLC/MS/MS)检测土壤中多种环境基质下呋喃唑酮和氟苯尼考的方法.提取液采用磷酸盐缓冲溶液(pH=3)-乙腈(3:7,V/V),经过SPE固相萃取小柱SAX-HLB串联富集,使用Waters BEH C18色谱柱(2.1×100 mm)进行分离,UPLC/MS/MS在多反应监测模式下进行定性与定量分析.以3倍信噪比确定方法检出限,以10倍信噪比确定方法定量限.结果表明,本方法在5 min内即可分离两种物质,呋喃唑酮和氟苯尼考的检出限分别为1.19和0.41μg/kg;定量限分别为3.40和1.37μg/kg.50μg/L加标水平的呋喃唑酮和氟苯尼考的回收率分别为92%和79%;200μg/L加标水平下呋喃唑酮与氟苯尼考的回收率分别为96%和86%.     

氟苯尼考对映异构体手性拆分及其光学纯度的测定

采用Chiralpak AD-H(4.6μm×250 mm,5μm)手性色谱柱,建立了氟苯尼考对映体的正相高效液相色谱拆分方法。考察了流动相中碱性添加剂、醇类改性剂种类及浓度对分离度、保留时间、理论塔板数、拖尾因子的影响。结果表明:以正己烷-异丙醇-甲醇(70∶15∶15)为流动相,流速为1 mL/min,柱温为30℃,检测波长为224 nm条件下,氟苯尼考与其光学异构体获得满意的分离效果。氟苯尼考在0.05～0.5g/L质量浓度范围内与其峰面积呈良好的线性关系,相关系数r为0.999 7;氟苯尼考的检出限为0.1μg/L;日内精密度RSD小于1.8%,日间精密度RSD小于2.3%;加标回收率为109%～112%,RSD不大于3.0%。该方法快速、方便,可用于工业生产中氟苯尼考光学纯度的控制。     

固相萃取-超高效合相色谱法测定猪肉中氟苯尼考对映体及其代谢物氟苯尼考胺的含量北大核心CSCD

在10.0 g猪肉样品中加入含3%(体积分数)氨水的乙酸乙酯溶液25 mL,涡旋1 min混匀,离心5 min,所得沉淀用上述方法再重复提取一次。合并两次提取液,于40℃减压浓缩至近干,用10 mL磷酸盐缓冲溶液(pH 6.0)溶解残渣。所得溶液过活化好的HLB固相萃取柱,用10 mL水淋洗,真空抽柱1 min,用6 mL甲醇洗脱。收集洗脱液,于40℃氮吹至近干,加入体积比8∶2的正庚烷-异丙醇混合溶液1 mL,涡旋3 min溶解残渣,过0.22μm有机滤膜,滤液供超高效合相色谱仪分析。采用CHIRALPAK AD-3手性色谱柱作固定相,设置柱温40℃,系统背压13.8 MPa,以不同体积比的超临界二氧化碳和含0.5%(体积分数)氨水的甲醇溶液的混合溶液为流动相进行梯度洗脱,在检测波长224 nm处用外标法测定(-)-氟苯尼考、(+)-氟苯尼考及它们的代谢物氟苯尼考胺的含量。结果显示:3种目标化合物的质量浓度在0.50~20.00 mg·L^(-1)内与其对应的峰面积呈线性关系,测定下限为0.05 mg·kg^(-1)[(-)-氟苯尼考和(+)-氟苯尼考]和0.1 mg·kg^(-1)(氟苯尼考胺)。以阴性猪肉样品为基质进行3个浓度水平的加标回收试验,3种目标化合物的回收率为81.2%~107%,测定值的相对标准偏差(n=6)为5.0%~9.0%。方法用于20份猪肉样品的分析,仅在1份样品中检出(-)-氟苯尼考(248μg·kg^(-1))。     

超高效液相色谱法测定鱼体组织中地克珠利残留量

建立了鱼体血浆、肌肉、皮肤、肝脏、肾脏和鳃组织中地克珠利残留量测定的超高效液相色谱法(UPLC-TUV)。鱼体血浆、肝脏和肾脏组织采用乙酸乙酯提取,50 mmol/L KH2PO4溶液去除组织中的蛋白,正己烷去脂;鱼体肌肉、皮肤和鳃组织采用乙腈提取,用乙酸乙酯从40 g/L NaCl溶液中进行反萃取,正己烷去除脂肪;以乙腈-0.3%乙酸水溶液为流动相,以ACQUITY UPLC BEH C18为分离柱,柱温为30℃,紫外检测波长为280 nm。地克珠利质量浓度在0.05~10.0 mg/L范围内呈线性相关,相关指数r2=0.999。平均回收率为70.3%~93.5%,相对标准偏差为0.81%~8.6%,地克珠利在鱼体肌肉、皮肤、脂肪和腮组织组织中的检出限为25μg/kg,定量限为50μg/kg;地克珠利在鱼体血浆、肝脏和肾脏样品中组织中的检出限和定量限分别为75μg/kg和100μg/kg。方法适用于鱼体各组织中地克珠利残留量的测定。     

高效液相色谱法测定动物组织中四环素类抗生素残留量的研究

建立了动物组织中四环素、金霉素、土霉素、强力霉素、去甲基金霉素、甲烯土霉素和二甲胺四环素等7种四环素类抗生素残留量的液相色谱同时测定方法。方法采用Inertsil C8-3(5μm,250 mm×4.0 mm i.d)反相色谱柱,以pH 4.0的EDTA-Mcllvaine缓冲溶液为提取溶液,以HLB固相萃取柱为净化柱,流动相为甲醇+乙腈+0.01mol/L三氟乙酸(梯度洗脱),流速1.5 mL/min,检测波长350 nm,进样量100μL。方法的检出限为1.5~5.0μg/kg,测定低限为50μg/kg,线性范围为50~1200μg/kg,加标回收率为73.8%~103%,相对标准偏差为0.5%~8.5%。方法适用于动物肌肉、肝脏和肾脏组织中7种四环素类抗生素残留量的同时检测。     

高效液相色谱-荧光检测法分析麦类中麦角克列斯汀碱

提出了一种采用高效液相色谱-荧光检测法(HPLC-FLD)测定麦类样品中麦角克列斯汀碱的方法。麦类样品经V(乙腈)∶V(0.1 mol/L乙酸铵缓冲溶液)=1∶4提取,以C18小柱净化,C18色谱柱(4.6×250 mm,5μm)分离,V(水)∶V(乙腈)=3∶2作流动相,流速1.0 mL/min,以HPLC-FLD定量测定。标准工作溶液浓度在1.0~50.0μg/L范围内,与峰面积成良好的线性关系,线性相关系数0.9999,样品在10.0、50.0、250.0μg/kg添加水平的回收率为76%~85%,相对标准偏差(RSD)为6.6%~8.8%(n=8),方法检测限为5.0μg/kg(S/N10)。     

改良的QuEChERS与HPLC-HESI/MS/MS同时测定中华鳖组织中氯硝柳胺和酰胺醇类药物及其代谢物的残留量

建立了中华鳖(Trionyx sinensis)组织(血浆、肌肉、裙边、肝脏和肾脏)中氯硝柳胺、氯霉素、甲砜霉素、氟苯尼考和氟苯尼考胺同时测定的高效液相色谱-加热电喷雾电离源串联质谱法(HPLC-HESI/MS/MS)。样品经改进的QuEChERS方法提取净化,以氨化乙腈为提取剂,十八烷基硅烷键合硅胶(C18)粉为净化剂,甲醇-水为流动相,流速为0.3 mL/min,以Waters Symmetry~ C_(18)(2.1 mm×100 mm,3.5μm)为色谱分离柱,采用正负离子分段扫描和多反应监测模式(MRM)检测。氯霉素、甲砜霉素、氟苯尼考和氟苯尼考胺采用内标标准曲线法定量,氯硝柳胺采用基质匹配标准曲线外标法定量。结果表明,在0.3~100μg/L范围内,5种待测物均呈良好的线性关系,相关系数(r2)均不小于0.998 7。在1~20μg/kg加标水平下,中华鳖空白血浆、肌肉、裙边、肝脏和肾脏的加标回收率为77.9%~105.3%(n=6),相对标准偏差为2.7%~10.5%(n=6),方法的检出限分别为0.5、0.1、0.5、0.5、0.5μg/kg,定量下限分别为1.0、0.3、1.0、1.0、1.0μg/kg。该方法操作简便、准确、灵敏度高,适用于中华鳖组织中氯硝柳胺、氯霉素、甲砜霉素、氟苯尼考和氟苯尼考胺残留量的同时测定。     

高效液相色谱法检测鳗鱼中氟苯尼考残留量

建立了鳗鱼肌肉中氟苯尼考残留的分析方法。采用乙酸乙酯作为提取剂,提取液挥干后溶于缓冲液中,经正已烷脱脂、C18SPE小柱净化后,采用高效液相色谱进行分析,方法在1～200ng之间呈线性相关;相关系数r=0．9999。对于0．05、0．10、0．50mg／kg 3个添加水平,平均回收率均在90％以上,相对标准偏差为4．24％～7．36％,方法检出限和定量限分别为9．1μg/kg和22．3μg／kg。     

An efficient enantioselective synthesis of florfenicol via asymmetric aziridination

An efficient enantioselective synthesis of florfenicol is accomplished in 44.7% overall yield from commercially available p-(methylsulfonyl)benzaldehyde. Key features of this synthesis are the asymmetric aziridination reaction mediated by the Wulff’s catalyst in situ derived from (R)-VANOL and diastereoselectively ring-opening of (2S,3S)-fluoroaziridine 13.     

Simultaneous determination of florfenicol with its metabolite based on modified quick,easy, cheap,effective, rugged,and safe sample pretreatment and evaluation of their degradation behavior in agricultural soils

A simple and simultaneous method for the determination of florfenicol and its metabolite florfenicol amine in agricultural soils using modified quick, easy, cheap, effective, rugged, and safe sample pretreatment and reversed‐phase high‐performance liquid chromatography with tandem mass spectrometry is presented. Florfenicol and its metabolite florfenicol amine residues in agricultural soils were extracted with alkalized acetonitrile and an aliquot was cleaned up with Si(CH₂)₃NH (CH₂)₂NH₂ and C₁₈ sorbent, which were powder materials. High‐performance liquid chromatography with tandem mass spectrometry was applied to simultaneously determine the level of florfenicol and florfenicol amine in agricultural soils. Excellent linearity was achieved for florfenicol and florfenicol amine over a range of concentrations from 0.1–500 μg/L with coefficients more than 0.99. Average recoveries at four different levels (0.005, 0.05, 0.5, and 5.0 mg/kg) for florfenicol and florfenicol amine ranged from 73.6–94.9% with relative standard deviations of 2.9–12.5%. The limits of detection for florfenicol and florfenicol amine in agricultural soils were 2.0 μg/kg, and the limits of quantification were 6.0 μg/kg. Based on this method, the degradation behavior of florfenicol and its metabolite florfenicol amine in three soils (Nanchang, Hangzhou, and Changchun) under sterilized and native conditions was investigated and the transformation rate of florfenicol amine from florfenicol was evaluated.     

采用液相色谱-串联质谱同时检测动物源性食品中胺苯醇类药物及其代谢产物

建立了采用液相色谱-串联质谱(LC-MS/MS)同时测定动物源食品中氯霉素、甲砜霉素、氟苯尼考以及氟苯尼考胺残留量的方法。三类胺苯醇类药物及其代谢物用氨化乙酸乙酯(97+3v/v)提取,C18小柱净化;其中氯霉素、甲砜霉素、氟苯尼考用内标法定量,氟苯尼考与氟苯尼考胺用外表法定量。方法的定量测定低限氯霉素为0.1μg/kg,甲氟霉素、氟苯尼考胺为1.00g/kg,各基质的加标平均回收率在73.8%～120.5%之间,相对标准偏差≤25%。     

Stability of florfenicol in drinking water

Florfenicol, a broad-spectrum antibiotic, is being developed for veterinary application as an oral concentrate intended for dilution with drinking water. When a drug product is dosed via drinking water in a farm setting, a number of variables, including pH, chlorine content, hardness of the water used for dilution, and container material, may affect its stability, leading to a decrease in drug potency. The stability of florfenicol after dilution of Florfenicol Drinking Water Concentrate Oral Solution, 23 mg/mL, with drinking water was studied. A stability-indicating, validated liquid chromatographic method was used to evaluate florfenicol stability at 25 degrees C at 5, 10, and 24 h after dilution. The results indicate that florfenicol is stable under a range of simulated field conditions, including various pipe materials and conditions of hard or soft and chlorinated or nonchlorinated water at low or high pH. Significant degradation (> 10%) was observed only for isolated combinations in galvanized pipes. Analysis indicated that the florfenicol concentration in 8 of the 12 water samples stored in galvanized pipes remained above 90% of the initial concentration (100 mg/L) for 24 h after dilution.     

Bioequivalence evaluation of Florfenicol pharmaceutics in pigs using liquid chromatography-tandem mass spectrometry

The bioequivalence of two Florfenicol (FF) products in pigs was evaluated. A 2?×?2 crossover trial with a 14 days wash-out period was performed. The pigs were orally administered in a single dose (2?mg/kg b.w of FF). Serum samples were analyzed using a liquid chromatography-tandem mass spectrometry method. The limit of quantification was 0.1?ng/mL, and the calibration range was 1.0–100.0?ng/mL. Furthermore, intraday and interday were 5.43–9.09% and 6.23–9.68%, respectively. The areas under the curve (AUC_0–48) for the test product B of FF and reference product A were 7289.61?±?1750.44 and 6545.01?±?2766.25?h?×?ng/mL, respectively. The highest concentrations of FF in the serum (C_max) were 726.05?±?211.77 and 641.97?±?117.94?ng/mL. The mean retention times (MRT) was 7.91?±?1.98 and 7.76?±?2.89?h while the half-lives (T_1/2) were 4.07?±?1.71 and 4.99?±?3.30?h. From the analysis of variance results, the p values of C_max and AUC_0–∞ for the 90% confidence interval were 0.492 and 0.320 (p?>?0.05), respectively. A comparison between the test product and the reference product showed no significant difference. Both products showed bioequivalence after being administered in pigs.     

An Indirect Competitive Enzyme-linked Immunosorbent Assay for Simultaneous Determination of Florfenicol and Thiamphenicol in Animal Meat and Urine

A high-affinity polyclonal antibody was prepared by immunizing animals with haptens FFD and FFM. Under the optimal combination of coating antigen and antibody, an indirect competitive enzyme-linked immunosorbent assay (icELISA) for simultaneous detection of florfenicol and thiamphenicol residues in animal meat and urine samples was developed. The icELISA showed an IC₅₀ value of 1.32 ng mL^?1 for florfenicol and 2.13 ng mL^?1 for thiamphenicol, respectively. The linear ranges were from 0.31 to 5.61 ng mL^?1 with a limit of detection of 0.12 ng mL^?1 for florfenicol, and 0.41 to 11.2 ng mL^?1 with a limit of detection of 0.15 ng mL^?1 for thiamphenicol, respectively. The average recoveries of florfenicol and thiamphenicol in spiked samples ranged from 77.2% to 116.0% with a relative standard deviation of less than 15%. Therefore, this proposed icELISA provided a valid detection method for florfenicol and thiamphenicol residues in animal tissue and urine samples.     

Simultaneous determination of residues of chloramphenicol, florfenicol, florfenicol amine, and thiamphenicol in shrimp tissue by gas chromatography with electron capture detection

A gas chromatographic (GC) method is presented for determining residues of chloramphenicol (CAP), florfenicol (FF), florfenicol amine (FFa), and thiamphenicol (TAP) in shrimp tissues, with meta-nitrochloramphenicol (mCAP) as the internal standard. The composited shrimp is extracted with basic ethyl acetate, followed by an acetonitrile-basic ethyl acetate mixture. This extract is centrifuged, filtered, evaporated, and reconstituted in water; the reconstituted extract is acidified, defatted with hexane, and passed through a propylsulfonic acid (PRS) and C18 solid-phase extraction (SPE) system. The C18 SPE column is eluted with methanol, and the PRS SPE column is eluted with basic MeOH plus counter ion. The combined eluates are evaporated, reconstituted in acetonitrile, and derivatized with Sylon BFT. After derivatization, the addition of toluene directly to the sample, followed by the addition of basic water, quenches the derivatization process. After centrifugation, the organic layer is carefully removed, and the analytes are determined by GC with electron capture detection. Shrimp tissues were fortified with fenicols (i.e., CAP, FF, FFa, and TAP) at 5, 10, 20, 40, and 80 ng/mL. Overall recoveries were 88, 101, 91, and 84% with overall interassay (between-day) variabilities (i.e., relative standard deviations) of 5.3, 9.4, 12.8, and 7.4% for CAP, FF, FFa, and TAP, respectively. The method detection limits were calculated as 0.7, 1.4, 2.4, and 1.3 ng/g (ppb) for CAP, FF, FFa, and TAP, respectively, based on a 10 g sample. The quantitation limit as determined empirically by this method is the lower limit of the standard curve, which is about 5 ng/g (ppb) for each analyte.     

Determination of florfenicol in fish feed by liquid chromatography

A simple, accurate, and reproducible assay was developed for the determination of Florfenicol in medicated fish feed. Florfenicol was extracted from ground feed into an acetonitrile-water mixture by shaking and sonication. A portion of the centrifuged extract was passed through an Envi-Carb solid-phase extraction cartridge, through which Florfenicol eluted unretained. The collected eluant was diluted to adjust for analyte concentration, and injected into a reversed-phase liquid chromatography system. Samples were quantitated by external standard analysis versus multilevel calibration solutions. The procedure is suitable for the quantitation of samples medicated with 0.2-4 g/kg Florfenicol. Accuracy was evaluated by 2 analysts, who determined recovery of Florfenicol from feeds fortified over a range of 0.1-6.0 g/kg. The average recovery was 100.5% (relative standard deviation, 1.2%). The linearity, accuracy, precision, reproducibility (interday and analyst), and selectivity of the method are presented. The detection and quantitation limits were determined to be 0.2 and 1.0 mg/kg, respectively.