孟鲁斯特钠咀嚼片在健康人体内药动学和生物等效性

目的:研究两种(仿制新药与市售)孟鲁司特钠咀嚼片在人体内生物等效性。方法:采用单中心、随机、开放、双周期自身交叉试验设计,20名健康男性志愿者分2周期分别口服受试制剂和参比制剂各10 mg,HPLC法测定血浆中孟鲁司特钠咀嚼片的浓度,用DAS2.1.1软件计算人体药动学参数并进行生物等效性评价。结果:受试制剂和参比制剂两药的主要药代动力学参数AUC0-t分别为(17.94±6.19)μg h/ml和(17.37±4.73)μg h/ml,AUC0-∞分别为(18.26±6.16)μg h/ml和(17.64±4.66)μg h/ml,Cmax分别为(5.58±1.95)μg/ml和(5.54±1.65)μg/ml,Tmax分别为(2.03±0.97)h和(1.93±0.69)h,t1/2分别为(1.20±0.17)h和(1.19±0.13)h。受试制剂的平均相对生物利用度为(101.5±6.56)%。结论:受试制剂和参比制剂具有生物等效性。     

酮洛芬缓释片人体药动学和生物等效性研究

目的:评价受试酮洛芬缓释片与参比酮洛芬片的生物等效性。方法:采用反相高效液相色谱法测定24名健康男性志愿受试者交叉单剂量口服受试酮洛芬缓释片与参比酮洛芬片150mg后血浆中酮洛芬的浓度,用3p97程序进行数据处理。结果:口服受试和参比酮洛芬制荆后的AUC_(0-(?))分别是38.94±9.15μg·h·ml~(-1)、38.04±6.90μg·h·ml~(-1);AUC_(0-(?))分别是44.50±8.09μg·h·ml~(-1)、42.99±8.36μg·h·ml~(-1);T_(max)分别是3.87±0.55 h、1.96±0.60h;C_(max)分别是5.78±1.11μg·ml~(-1)、11.62±2.10μg·ml~(-1);t_(1/2)(Ke)分别是5.88±1.16h、1.70±1.40h。结论:受试酮洛芬缓释片与参比酮洛芬片具有生物等效性。     

雷诺嗪缓释片在比格犬体内的药代动力学

目的:研究雷诺嗪缓释片在比格犬体内的药物代谢动力学,并与参照制剂比较,为其是否具有缓释特征提供依据。方法:首先建立血浆中雷诺嗪浓度的液相色谱-串联质谱联用检测方法,并考察方法的专属性、准确度、日内日间精密度、回收率、线性范围等。采用随机对照试验设计,将12只比格犬随机分为A、B组,每组6只,分别服用1片雷诺嗪缓释片(500 mg/片)和1片参比制剂雷诺嗪片(500 mg/片),均于给药前和给药后不同时间点采集血样,用已建立的液质联用方法检测血样中雷诺嗪的血药浓度,计算2组比格犬的药代动力学参数。结果:受试组和参照组半衰期t1/2分别为13.3±8.3和2.36±0.92 h,峰浓度Cmax分别为923.9±340.5和3205±1314 ng/mL,达峰时间Tmax分别为1.6±0.38和0.88±0.14 h,曲线下面积AUC0~∞分别为6252.1±2860.3和9916±4305(ng·h)/mL,清除率Cl分别为11.3±9.8和6.39±3.95 L/(kg·h)。受试制剂雷诺嗪缓释片和参比制剂雷诺嗪片的药代特征和血药浓度-时间变化趋势明显不同,受试组血药浓度缓慢上升和下降,峰值较低;而参照组血药浓度峰值显著高于受试组,有明显的突释效应。结论:液质联用检测方法准确可靠,适合体内药代动力学研究;与参比制剂雷诺嗪片相比,受试制剂雷诺嗪缓释片符合缓释片的基本药代动力学特点。     

HPLC-MS/MS法测定人血浆中草乌甲素的浓度及生物等效性研究(英文)

本文建立了一种快速、高灵敏的HPLC-MS/MS法用于检测人血浆中的草乌甲素浓度。血浆样品采用沃特斯HLB小柱进行固相萃取,汉邦C18色谱柱(150 mm×4.6 mm,5μm)进行分离,流动相为甲醇∶水(85∶15,v/v),水相含10 mmol/L的醋酸铵和0.1%的甲酸。采用ESI源和多反应监测(MRM)的方式进行检测,草乌甲素及内标的反应离子对分别为644.4/584.4和237.2/194.2,草乌甲素血药浓度在0.010～1.0 ng/mL范围内线性关系良好,最低定量限为0.010 ng/mL可以满足口服0.4 mg草乌甲素后血药浓度的检测,日内日间及质控样品精密度及准确度均在允许范围内。本检测方法被成功的应用在中国健康志愿者生物等效性研究中,20名志愿者口服0.4 mg草乌甲素试验制剂和参比制剂后主要药代动力学参数分别如下:Cmax(0.325±0.110),(0.323±0.115)ng/mL;AUC0-16(1.627±0.489),(1.732±0.556)ng.h/mL;AUC0-∞(1.730±0.498),(1.831±0.562)ng.h/mL;t1/2(4.26±0.95),(3.80±0.90)h;Tmax(1.34±0.54),(1.83±0.99)h。     

辛伐他汀在大鼠体内药动学性别差异的研究

目的:研究Wistar大鼠单次灌服辛伐他汀后体内药代动力学的性别差异。方法:利用高效液相色谱方法检测大鼠血浆中辛伐他汀浓度,采用非房室模型法计算各自药动学参数。结果:雌、雄大鼠体内Cmax分别为(144.66±22.31)ng·mL~(-1)和(165.91±52.50)ng·mL~(-1);t_(1/2)分别为(4.74±1.19)h和(14.98±6.64)h;AUC_(0-10)分别为(0.990±0.19)μg.h·mL~(-1)和(0.726±0.15)μg·h·mL~(-1);AUC0-∞分别为(1.62±0.47)μg·h·mL~(-1)和(2.19±0.62)μg·h·mL~(-1);MRT分别为(9.69±1.60)h和(23.08±8.89)h,经t-检验,雌、雄大鼠主要药动学参数t_(1/2)、AUC_(0-10)、MRT均有统计学显著性差异(p<0.01)。结论:辛伐他汀在大鼠体内的药代动力学存在明显的性别差异,辛伐他汀在雌性大鼠体内代谢较快。     

恩诺沙星在罗氏沼虾体内的药物代谢动力学

应用反相高效液相色谱法(RP-HPLC)研究了恩诺沙星在罗氏沼虾(Macrobrachiumrosenbergii)体内的药物代谢动力学。实验结果表明,恩诺沙星在血淋巴、肝胰腺、肌肉中的平均回收率分别为86.54%±2.39%、85.43%±2.75%、95.01%±1.99%,其代谢产物环丙沙星在血淋巴、肝胰腺、肌肉中的平均回收率分别为94.34%±8.30%、75.17%±5.42%、80.42%±1.67%;恩诺沙星及其代谢产物环丙沙星在三种组织中的平均日内精密度分别为3.39%±0.53%和3.92%±1.24%,而日间精密度分别为5.11%±1.73%和5.28%±2.10%。恩诺沙星、环丙沙星的最低检测限分别为0.02μg/ml和0.01μg/ml。罗氏沼虾以10mg/kg虾体重剂量单次肌肉注射给药后,血液中药物浓度即刻达到峰值,并迅速向组织中分布。实验数据经MCPKP药动学软件分析,恩诺沙星在血淋巴中的主要药物代谢动力学参数为:t1/2α为0.581h、t1/2β为69.315h、Vd/F为7.230L/kg、CL/F为0.035L/h.kg、K12为0.01/h、K21为0.005/h、AUC为291.898μg/ml.h、Tmax为0.083h、Cmax为6.293μg/ml;恩诺沙星在肝胰腺、肌肉组织中主要药动学参数:t1/2α为1.941h、0.000h;t1/2β为70.732h、59.456h;AUC为308.07μg/ml.h、217.039μg/ml.h。三种组织中均能检测到恩诺沙星的活性代谢产物环丙沙星,但含量均处于较低水平,药物浓度-时间数据经MCPKP药动学软件处理后,不能用开放性一室模型或二室模型拟合。     

复方依那普利非洛地平缓释片在健康中国人体内的药动学特征

目的:研究复方依那普利非洛地平缓释片在健康中国人体内的药动学特征。方法:采用双交叉实验设计,将12名健康受试者随机分为2组,先接受第1周期低剂量给药,即分别单次口服受试制剂(复方依那普利非洛地平缓释片,每片含非洛地平5 mg和马来酸依那普利5 mg)1片和2种单方参比制剂(马来酸依那普利片,含马来酸依那普利5 mg;非洛地平缓释片,含非洛地平5 mg)各1片,然后分别每日口服受试制剂1片和2种单方参比制剂各1片,连续7 d。第1周期结束后,2组再交叉进行第2周期研究,给药方案同第1周期。随后进行高剂量研究,即2组所有受试者均单次口服受试制剂2片。采用液质联用法测定人血浆中非洛地平、依那普利及其活性代谢物依那普利拉的浓度,计算药动学参数并进行统计学分析。结果:单次低剂量给药研究中,受试者分别口服受试制剂与合用2种单方参比制剂所测得的非洛地平、依那普利和依那普利拉的各药动学参数均无显著差异(P>0.05);多次低剂量给药研究中,除口服受试制剂者的依那普利拉Tmax比口服参比制剂的受试者平均提前0.6 h左右(P<0.05)以外,其他药动学参数均无显著差异(P>0.05);单次低、高剂量给药的药动学数据显示:所有受试者血浆中非洛地平、依那普利和依那普利拉的AUC和Cmax均随给药剂量提高而增大,除接受高剂量受试制剂者的依那普利Tmax较接受低剂量的受试者平均延迟0.4 h左右(P<0.05)以外,两者间的其他药动学参数均无显著差异(P>0.05);各药动学参数在男性和女性受试者间无显著差异(P>0.05)。结论:该研究建立的人血浆中非洛地平、依那普利和依那普利拉的LC-MS测定方法的准确度、精密度、稳定性及线性关系等均符合生物样品的分析要求,适用于复方依那普利非洛地平缓释片人体药动学研究;口服受试制剂与同服2种单方参比制剂的体内药动学过程基本一致。     

RP-HPLC法测定阿托伐他汀在新西兰兔体内的药代动力学

目的:研究阿托伐他汀片在新西兰兔体内的药代动力学.方法:18只成年健康雄性新西兰兔.随机分为正常对照组、10mg/kg·d阿托伐他汀片组与15 mg/kg·d阿托伐他汀片组,每组6只,采用RP-HPLC法测定血药浓度,计算药代动力学参数.结果:10mg/kg·d组与15 mg/kg·d组的主要药代动力学参数分别为:AUC0～t/μ g·L-1·h为(619.58±215.45)与(1138.34±422.32)、AUC0～∞/μ g·L-1·h为(655.68±242.83)与(1216.57±353.64)、Cmax/μ g·L-1为(455.81±168.52)和(896.53±168.5.8)、MRT0～t/h为(3.68±0.75)与(5.73±0.56)、MRT0～∞/h为(3.83±0.91)与(5.25±0.48)、Tmax/h为(2.51±0.82)与(3.68±0.33)、T1/2/h为(4.22±0.55)与(9.51±0.67).结论:RP-HPLC法适用于阿托伐他汀片动物药代动力学的研究.     

妇宁康泡腾胶囊的药代动力学研究

目的研究妇宁康泡腾胶囊在家兔体内的药动学特点。方法用HPLC法测定甘草酸在家兔体内48 h血药浓度,采用3P87药动学程序计算药动学参数。结果主要药动学参数为t1/2=8.956 h,Tmax=8.27 h,Cmax=0.4544μg/ml,AUC=37.161。结论该制剂在家兔体内吸收代谢缓慢,其生物半衰期超过8 h。     

绒盖牛肝菌酸HPLC检测方法的建立及在大鼠体内的药代动力学

为建立绒盖牛肝菌酸血药浓度和各主要组织的HPLC检测方法,考察绒盖牛肝菌酸在大鼠体内的药代动力学和组织分布特点。采用Agilent ZORBAX Eclipse XDB-C18 column色谱柱(4.6 mm×250 mm,0.5μm)分离,以V(甲醇)∶V(水)=75∶25为流动相,流速1.0 m L/min,柱温25℃,检测波长243 nm。研究结果表明大鼠血浆及肝组织中的内源性物质均不干扰样品的测定,线性关系良好,大鼠灌胃绒盖牛肝菌酸符合一室模型,主要药代动力学参数Tmax为(0.76±0.21)h,Cmax为(8.76±0.81)μg/m L,t1/2为(0.18±0.28)h,AUC0-inf为(102.95±0.78)μg/(m L·h),大鼠尾静脉注射绒盖牛肝菌酸符合二室模型,主要药代动力学参数t1/2为(0.33±0.71)h,AUC_(0-inf)为(34.14±2.38)μg/(m L·h)。该方法简单快速,准确可靠,符合生物样品的测定要求,并明确了绒盖牛肝菌酸在大鼠体内的药代动力学和组织分布特征。     

N-trimethyl chitosan chloride-coated liposomes for the oral delivery of curcumin

The aims of this study were to design the formulation of curcumin (CUR) liposomes coated with N-trimethyl chitosan chloride (TMC) and to evaluate in vitro release characteristics and in vivo pharmacokinetics and bioavailability of TMC-coated CUR liposomes in rats. The structure of synthesized TMC was examined by infrared spectroscopy, with the presence of trimethyl groups, and by proton nuclear magnetic resonance spectroscopy, indicating the high degree of substitution quaternization (65.6%). Liposomes, composed of soybean phosphotidylcholine, cholestrol, and D-α-tocopheryl polyethylene glycol 1000 succinate, were prepared by a thin-film dispersion method. Characteristics of the CUR liposomes, including entrapment efficiency (86.67%), drug-loading efficiency (2.33%), morphology, particle size (221.4?nm for uncoated liposomes and 657.7?nm for TMC-coated liposomes), and zeta potential (-9.63 mV for uncoated liposomes and +15.64 mV for TMC-coated liposomes) were investigated. Uncoated CUR liposomes and TMC-coated CUR liposomes showed a similar in vitro release profile. Nearly 50% of CUR was released from liposomes, whereas 80% of CUR was released from CUR propylene glycol solution. CUR incorporated into TMC-coated liposomes exhibited different pharmacokinetic parameters and enhanced bioavailability (C(max)?=?46.13 μg/L, t(1/2)?=?12.05 hours, AUC?=?416.58 μg/L·h), compared with CUR encapsulated by uncoated liposomes (C(max)?=?32.12 μg/L, t(1/2)?=?9.79 hours, AUC?=?263.77 μg/L·h) and CUR suspension (C(max)?=?35.46 μg/L, t(1/2)?=?3.85 hours, AUC?=?244.77 μg/L·h). In conclusion, oral delivery of coated CUR liposomes is a promising strategy for poorly water-soluble CUR.     

Determining the pharmacokinetics of psilocin in rat plasma using ultra-performance liquid chromatography coupled with a photodiode array detector after orally administering an extract of Gymnopilus spectabilis

This study established ultra-performance liquid chromatography coupled with a photodiode array detector for determining psilocin and its pharmacokinetics in rat plasma after orally administering an extract of Gymnopilus spectabilis. The extract was separated on an ODS C18 column (2.3 μm, 100 mm × 2.1 mm I.D.) by gradient elution with (A) water containing 50mM AcONH(4) and (B) acetonitrile. The wavelength was set at 265 nm and the injection volume was 10 μL. Under these conditions, the calibration curve was linear over the concentration range 0.2-20 μg/mL with a correlation coefficient of r(2)=0.9992. The inter- and intraday precision levels were less than 7% and the accuracies (%) were within the range 92.0-102.5%. The method was sufficiently valid to be applied to a pharmacokinetics study of psilocin in rat plasma. The pharmacokinetic parameters of psilocin in rat plasma after the oral administration of a G. spectabilis extract were as follows: C(max), 0.43 ± 0.12 μg/mL; T(max), 90 ± 2.1 min; AUC(0→t), 1238.3 ± 96.4 (μg/mL) min; and T(1/2), 117.3 ± 40.3 min.     

Stereospecific versus nonstereospecific assessments for the bioequivalence of two formulations of racemic chlorpheniramine

Chlorpheniramine (chlorphenamine, CPAM) is a racemic antihistaminic H1 drug containing two enantiomers. The aim of this study was to assess the bioequivalence of two formulations (reference and Vietnamese-tested formulation) of racemic chlorpheniramine combined with phenylpropanolamine in an open-labeled, randomized, crossover two-period study, after administration of 8 mg of racemic chlorpheniramine in 12 healthy Vietnamese subjects. First, dissolution of both formulations was tested in vitro according to USP requirements. Then the 12 subjects received both formulations after an overnight fast and a 7-day wash-out period. Plasma samples were collected up to 168 h. Plasma concentrations of total chlorpheniramine and its individual enantiomers were determined with a validated chiral HPLC method and pharmacokinetic parameters were estimated using model-independent analysis. For the reference formulation, Cmax and AUC values were higher for (+)S-chlorpheniramine ((+)S-CPAM) compared to (-)R-chlorpheniramine ((-)R-CPAM) (13.3 vs. 6.8 ng/ml and 409 vs. 222 ng/ml/h, respectively) while Clt/F and Vd/F were lower (9.8 vs. 17.6 l/h and 321 vs. 627 l, respectively). No difference was observed for Tmax, t(1/2), and MRT. Pharmacokinetic parameters were similar for the reference and the Vietnamese-tested formulation. Bioequivalence was assessed by Schuirmann test, as recommended by the current FDA and European Community criteria. Dissolution tests showed that both formulations were equivalent. A nonstereospecific, but not a stereospecific, approach indicated bioequivalence between the formulations.     

N-trimethyl chitosan chloride-coated liposomes for the oral delivery of curcumin

The aims of this study were to design the formulation of curcumin (CUR) liposomes coated with N-trimethyl chitosan chloride (TMC) and to evaluate in vitro release characteristics and in vivo pharmacokinetics and bioavailability of TMC-coated CUR liposomes in rats. The structure of synthesized TMC was examined by infrared spectroscopy, with the presence of trimethyl groups, and by proton nuclear magnetic resonance spectroscopy, indicating the high degree of substitution quaternization (65.6%). Liposomes, composed of soybean phosphotidylcholine, cholestrol, and D-α-tocopheryl polyethylene glycol 1000 succinate, were prepared by a thin-film dispersion method. Characteristics of the CUR liposomes, including entrapment efficiency (86.67%), drug-loading efficiency (2.33%), morphology, particle size (221.4?nm for uncoated liposomes and 657.7?nm for TMC-coated liposomes), and zeta potential (–9.63 mV for uncoated liposomes and +15.64 mV for TMC-coated liposomes) were investigated. Uncoated CUR liposomes and TMC-coated CUR liposomes showed a similar in vitro release profile. Nearly 50% of CUR was released from liposomes, whereas 80% of CUR was released from CUR propylene glycol solution. CUR incorporated into TMC-coated liposomes exhibited different pharmacokinetic parameters and enhanced bioavailability (C_max?=?46.13 μg/L, t_1/2?=?12.05 hours, AUC?=?416.58 μg/L·h), compared with CUR encapsulated by uncoated liposomes (C_max?=?32.12 μg/L, t_1/2?=?9.79 hours, AUC?=?263.77 μg/L·h) and CUR suspension (C_max?=?35.46 μg/L, t_1/2?=?3.85 hours, AUC?=?244.77 μg/L·h). In conclusion, oral delivery of coated CUR liposomes is a promising strategy for poorly water-soluble CUR.     

Improved retention of idarubicin after intravenous injection obtained for cholesterol-free liposomes

To date there has been a focus on the application of sterically stabilized liposomes, composed of saturated diacylphospholipid, polyethylene glycol (PEG) conjugated lipids (5-10 mole%) and cholesterol (CH) (>30 mole%), for the systemic delivery of drugs. However, we are now exploring the utility of liposome formulations composed of diacylphospholipid conjugated PEG mixtures prepared in the absence of added cholesterol, with the primary objective of developing formulations that retain encapsulated drug better than comparable formulations prepared with cholesterol. In this report the stability of cholesterol-free distearoylphosphatidylcholine (DSPC):distearoylphosphatidylethanolamine (DSPE)-PEG(2000) (95:5 mol/mol) liposomes was characterized in comparison to cholesterol-containing formulations DSPC:CH (55:45 mol/mol) and DSPC:CH:DSPE-PEG(2000) (50:45:5 mol/mol/mol), in vivo. Circulation longevity of these formulations was determined in consideration of variables that included varying phospholipid acyl chain length, PEG content and molecular weight. The application of cholesterol-free liposomes as carriers for the hydrophobic anthracycline antibiotic, idarubicin (IDA), was assessed. IDA was encapsulated using a transmembrane pH gradient driven process. To determine stability in vivo, pharmacokinetic studies were performed using 'empty' and drug-loaded [(3)H]cholesteryl hexadecyl ether radiolabeled liposomes administered intravenously to Balb/c mice. Inclusion of 5 mole% of DSPE-PEG(2000) or 45 mole% cholesterol to DSPC liposomes increased the mean plasma area under the curve (AUC(0-24h)) 19-fold and 10-fold, respectively. Cryo-transmission electron micrographs of IDA loaded liposomes indicated that the drug formed a precipitate within liposomes. The mean AUC(0-4h) for free IDA was 0.030 micromole h/ml as compared to 1.38 micromole h/ml determined for the DSPC:DSPE-PEG(2000) formulation, a 45-fold increase, demonstrating that IDA was retained better in cholesterol-free compared to cholesterol-containing liposomes.     

<Emphasis Type="Italic">In Vivo</Emphasis> Assessment of Parenteral Formulations of Oligo(3-Hydroxybutyric Acid) Conjugates with the Model Compound Ibuprofen

Polymer-drug conjugates have gained significant attention as pro-drugs releasing an active substance as a result of enzymatic hydrolysis in physiological environment. In this study, a conjugate of 3-hydroxybutyric acid oligomers with a carboxylic acid group-bearing model drug (ibuprofen) was evaluated in vivo as a potential pro-drug for parenteral administration. Two different formulations, an oily solution and an o/w emulsion were prepared and administered intramuscularly (IM) to rabbits in a dose corresponding to 40 mg of ibuprofen/kilogramme. The concentration of ibuprofen in blood plasma was analysed by HPLC, following solid–phase extraction and using indometacin as internal standard (detection limit, 0.05 μg/ml). No significant differences in the pharmacokinetic parameters (C _max, T _max, AUC) were observed between the two tested formulations of the 3-hydroxybutyric acid conjugate. In comparison to the non-conjugated drug in oily solution, the relative bioavailability of ibuprofen conjugates from oily solution, and o/w emulsion was reduced to 17% and 10%, respectively. The 3-hydroxybutyric acid formulations released the active substance over a significantly extended period of time with ibuprofen still being detectable 24 h post-injection, whereas the free compound was almost completely eliminated as early as 6 h after administration. The conjugates remained in a muscle tissue for a prolonged time and can hence be considered as sustained release systems for carboxylic acid derivatives.     

Enhanced Oral Bioavailability of Griseofulvin via Niosomes

The aim of the present report was to develop nonionic surfactant vesicles (niosomes) to improve poor and variable oral bioavailability of griseofulvin. Niosomes were prepared by using different nonionic surfactants span 20, span 40, and span 60. The lipid mixture consisted of surfactant, cholesterol, and dicetyl phosphate in the molar ratio of 125:25:1.5, 100:50:1.5, and 75:75:1.5, respectively. The niosomal formulations were prepared by thin film method and ether injection method. The influence of different formulation variables such as surfactant type, surfactant concentration, and cholesterol concentration was optimized for size distribution and entrapment efficiency for both methods. Result indicated that the niosomes prepared by thin film method with span 60 provided higher entrapment efficiency. The niosomal formulation exhibited significantly retarded in vitro release as compared with free drug. The in vivo study revealed that the niosomal dispersion significantly improved the oral bioavailability of griseofulvin in albino rats after a single oral dose. The maximum concentration (C _max) achieved in case of niosomal formulation was approximately double (2.98 μg/ml) as compared to free drug (1.54 μg/ml). Plasma drug profile also suggested that the developed niosomal system also has the potential of maintaining therapeutic level of griseofulvin for a longer period of time as compared to free griseofulvin. The niosomal formulation showed significant increase in area under the curve_0-24 (AUC; 41.56 μg/ml h) as compared to free griseofulvin (22.36 μg/ml h) reflecting sustained release characteristics. In conclusion, the niosomal formulation could be one of the promising delivery system for griseofulvin with improved oral bioavailability and prolonged drug release profiles.     

铅螯合物人工抗原的制备与鉴定

以双功能螯合剂异硫氰酸苄基乙二胺四乙酸(ITCBE)螯合铅离子,制备得半抗原Pb-ITCBE,然后再分别与载体蛋白KLH或BSA偶联制备得免疫原Pb-ITCBE-KLH与包被抗原Pb-ITCBE-BSA,ITCBE-BSA.用二喹啉甲酸法测3种抗原的浓度,分析半抗原、抗原与载体蛋白的紫外吸收光谱,利用SDS-PAGE对3种抗原的分子量进行鉴定,用三硝基苯磺酸法检测3种抗原中的赖氨酸残基的ε-NH2被半抗原替换的程度,用石墨炉原子分光吸收法检测抗原中铅的含量.研究结果表明,免疫原与包被抗原制备成功,Pb-ITCBE-KLH、Pb-ITCBE-BSA、ITCBE-BSA的浓度依次为6.47± 0.08 mg/ml,6.68± 0.06 mg/ml,5.57± 0.05 mg/ml;抗原与载体蛋白的紫外吸收光谱的特征各不相同;SDS-PAGE的结果显示3种抗原的分子量均不同于各自的载体蛋白;抗原中载体蛋白ε-氨基的替换程度依次为1.86± 0.74 %、55.53± 1.13%、54.19± 1.34%;铅的含量依次为15.64± 0.11 μg/ml,17.33± 0.15 μg/ml,0 μg/ml.