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1.
研究阿莫西林可溶性粉在猪体内的药代动力学特征,并评价其与市售注射用阿莫西林钠的生物等效性。采用高效液相色谱法(HPLC)测定血浆中阿莫西林浓度,通过Data Analysis System(DAS 3.0)计算药动学参数,采用非房室模型分析方法对药代动力学参数进行评价,猪经内服给药后,药物平均滞留时间MRT(0-t)为3.12±0.41h,平均达峰时间Tmax为1.63±0.35h,平均达峰浓度Cmax为4101.35±631.55μg/L,平均药-时曲线下面积AUC(0-t)为13540.33±3445.51μg/L×h,消除速率常数λz为0.36±0.14/h,半衰期t1/2z为2.48±1.73h。 猪经静脉注射给药后,平均滞留时间MRT(0-t)为1.54±0.35h,平均药-时曲线下面积AUC(0-t)为8522.56±1430.51μg/L×h,消除速率常数λz为0.23±0.12/h,半衰期t1/2z为3.84±2.03h。 结果表明:受试制剂阿莫西林可溶性粉经内服给药后,具有较快的吸收速度,吸收进血液后在体内的停留时间较短,代谢较快,平均达峰时间短,药物消除速度较快,平均绝对生物利用度为79.44%,为临床制定合理用药方案提供科学依据。  相似文献   

2.
健康仔猪单剂量内服左旋氧氟沙星的药动学研究   总被引:1,自引:0,他引:1  
以20mg/kg剂量内服进行左旋氧氟沙星的辩证药动学研究。高效液相色谱法测定血浆药物浓度、3P97药代动力学程序处理药时数据。健康组药时数据符合一级吸收一室模型,其主要药动学参数为:吸收半衰期t1/2ka(0.42±0.08)h,消除半衰期t1/2ke(7.62±0.38)h,达峰时间tmax(1.85±0.25)h,峰浓度Cmax(6.99±0.92)mg/L,药时曲线下面积AUC(90.7±10.07)mg/L·h,生物相表观分布容积VF(s)(2.45±0.28)L/kg,平均滞留时间MRT(11.92±0.94)h。  相似文献   

3.
10头健康仔猪随机均分为健康组、脾虚组 ,按 2 0mg/kg的剂量进行内服左旋氧氟沙星的药动学研究。高效液相色谱法测定血浆中药物浓度 ,3P97药代动力学程序处理药时数据。健康组和脾虚组药动学数据适合一级吸收一室模型。健康组主要药动学数据为 :吸收半衰期 (t1 / 2ka)(0 42± 0 0 8)h ,消除半衰期 (t1 / 2ke) (7 62± 0 38)h ,达峰时间 (tmax) (1 85± 0 2 5)h ,达峰浓度 (Cmax) (6 99± 0 92 )mg/L ,药时曲线下面积 (AUC) (90 7± 1 0 0 7)mg·L- 1 ·h ,表观分布容积 (V/ F(s) ) (2 45± 0 2 8)L·kg,平均滞留时间 (MRT) (1 1 92± 0 94)h。脾虚组 :t1 / 2ka(1 1 7± 0 38)h ,t1 / 2ke (9 0 2± 1 1 8)h ,tmax (3 93± 1 0 5)h ,Cmax (4 2 8± 1 45)mg/L ,AUC (72 2 1± 1 6 0 7)mg·L- 1 ·h ,V/ F(s) (3 95±1 2 8)L·kg,MRT (1 3 74± 1 2 1 )h。结果表明 :仔猪脾虚状态下明显影响左旋氧氟沙星内服给药的药动学特征  相似文献   

4.
吡喹酮脂质体在山羊体内的代谢动力学研究   总被引:1,自引:0,他引:1  
本试验对吡喹酮脂质体在山羊体内的代谢动力学进行了研究.给山羊一次静脉推注吡喹酮脂质体3mg/kg·bw,取24h内不同间隔时间血样,血药浓度测定按文献操作[1].4只山羊的血药浓度测定结果,血药浓度--时间曲线符合无吸收因素一室开放模型.其药代动力学参数,消除半衰期(T1/2β)为10.00+0.59h);消除速率常数(ke)为0.0690±0.040h-1;初始浓度(B)为18.81±0.64(ug/100m1);维持有效血药浓度时间(TCP)为20.01±1.28h;表现分布容积(vd)O 2.85±0.37(100ml/ky);廓清率(CL)为0.139±0.029(100ml/ky·h)药时曲试下面积(AUC)为271.67士21.07(μg/100m1).  相似文献   

5.
[目的] 研究头孢氨苄片受试制剂和参比制剂在比格犬体内的生物等效性。[方法] 采用双周期和双序列交叉设计,将22只健康比格犬随机分成2组,按30 mg/kg BW分别单剂量口服头孢氨苄片受试制剂Trolevis®300和参比制剂Rilexine®300,于给药前(0 h)和给药后0.5、1、1.5、2、2.5、3、4、6、8、12、17和24 h从臂头静脉采血。对超高效液相色谱串联质谱(UPLC-MS/MS)方法进行特异性、线性、检测限、准确度、精密度、稳定性等方法学考察。利用建立好的UPLC-MS/MS方法测定血浆中的药物浓度,并用WinNonlinTM 8.1软件对药代动力学参数进行分析计算。[结果] 方法学结果显示,在100~5 000 ng/mL浓度范围内相关性良好,相关系数(R2)≥ 0.99,标准曲线方程为y=10.6828x-176.481;高、中、低3个浓度的相对回收率平均值分别为105.63%、104.35%和102.40%;日内和日间变异系数均<15%;检测限为50 ng/mL,定量限为100 ng/mL。药代动力学结果显示,参比制剂组和受试制剂组药代动力学参数如下:Tmax分别为(1.77±0.55)和(2.70±4.68)h;Cmax分别为(28.09±5.09)和(26.82±7.94)μg/mL;T1/2分别为(3.39±1.43)和(3.12±1.05)h;AUC0-t分别为(121.81±25.80)和(116.34±36.30)μg·h/mL。受试制剂与参比制剂药时曲线相似,且受试制剂与参比制剂Cmax、AUC0-t和AUC0-∞几何均数的比值分别为99.51%、99.27%和99.30%,其90% CI均在80.00%~125.00%之间。[结论] 本试验建立的UPLC-MS/MS方法准确、可靠,可用于头孢氨苄的浓度测定,且头孢氨苄受试制剂与参比制剂是等效的,临床上均可用于相关疾病的治疗。  相似文献   

6.
6头成年健康黄牛按10 mg/kg剂量单次快速静注吡喹酮,另6头成年健康黄牛根据交叉试验设计法按10 mg/kg剂量单次肌注、30 mg/kg剂量内服吡喹酮进行药动学与生物利用度试验.利用高效液相色谱法测定血浆中吡喹酮原药的质量浓度,其检测限为25μg/L.房室模型分析表明,静注给药后的药时数据符合无吸收二室开放模型,其分布半衰期(t1/2a)、消除半衰期(t1/2β)、表观分布容积(Vd)、总体清除率(ClB)、药时曲线下面积(AUC)分别为(0.25±0.03)h、(1.28±0.20)h、(2.11±0.38)L/kg、(1.14±0.10)L/(kg·h)和(8.79±0.74)mg/(L·h).肌注的药时数据符合有吸收一室开放模型,主要药动学参数吸收半衰期(t 1/2ka)、消除半衰期(t1/2ke)、药时曲线下面积(AUC)、达峰时间(tmax)、峰浓度(Gmax)和生物利用度(F)分别为(0.40±0.17)h、(4.65±0.91) h、(6.85±1.02)mg/(L·h)、(1.33±0.52)h、(0.83±0.08)mg/L和77.93%.内服给药后符合有吸收一室开放模型,吸收不规则,其药动学参数t 1/2ka、t1/2ke、AUC、tmax、Cmax和F分别为(1.08±0.13)h、(6.81±1.26)h、(8.51±1.78)mg/(L·  相似文献   

7.
《兽药市场指南》2020,(4):11-12
米尔贝肟吡喹酮咀嚼片由浙江海正动物保健品有限公司研制,(2019)新兽药证字71号。米尔贝肟吡喹酮咀嚼片主要成分包括米尔贝肟,吡喹酮,本品为淡黄色椭圆形刻痕片(27.5mg规格)或淡黄色圆形片(137.5mg规格)。  相似文献   

8.
国产表阿佛菌素在绵羊体内的药代动力学研究   总被引:1,自引:0,他引:1  
用反相高效液相色谱结合荧光检测法,对试验绵羊经静脉、皮下单剂量注射0 2 mg/kg表阿佛菌素的药代动力学进行了研究。血样提取物通过C18小柱富集、洗脱,甲醇洗提部分经加入1 甲基咪唑和三氟乙酸酐的乙腈液衍生化后进行色谱分析。血药浓度在 2. 5 ~ 200 ng/mL 范围呈良好线性关系(R= 0 996 8),方法平均回收率96 65%±3.84%,血药最低检测限 2.5 ng/mL,日内、日间变异系数分别小于 10%、12%。2 种途径给药后体内药物运转分别符合二室和一室开放模型。主要药代参数如下,静脉注射:消除半衰期(T1/2β)12.66±2.05 h,药时曲线下面积(AUC0~74)1.02±0 30 (mg/L)·h,fc=0 13±0 05; 皮下注射:吸收半衰期(T1/2ka )4.42±1.04 h,峰浓度(Cmax)0 02±0 01 μg/mL,峰时(Tmax ) 15. 36±2. 91 h,消除半衰期(t1/2k ) 26. 22±9. 04 h,药时曲线下面积(AUC0~122)1.19±0 37 (mg/L)·h。上述结果表明,绵羊静脉注射表阿佛菌素后体内药物分布广泛,消除较慢。皮下注射吸收好,消除比静脉注射更为缓慢,体内药物平均滞留时间长。  相似文献   

9.
本研究旨在建立犬血浆中米尔贝肟的LC-MS/MS检测方法,评价国产米尔贝肟片在犬体内的相对生物利用度。对12条比格犬采用开放、随机、交叉、单剂量给药,口服国产米尔贝肟片、进口米尔贝肟片。LC-MS/MS测定犬血浆中米尔贝肟的浓度,3p97药动学计算软件处理血浆药物-时间数据。该方法低浓度(5ng/mL)回收率高于85%,最低定量限为5ng/mL;健康犬口服进口和国产米尔贝肟片的药物动力学最佳数学模型均为一级吸收一室模型。本研究中建立的HPLC-MS/MS检测方法可用于口服给药后犬血浆中米尔贝肟含量的测定;口服国产米尔贝肟片与进口米尔贝肟片的相对生物利用度为99.07%。  相似文献   

10.
吡喹酮在猪体内的生物利用度及药物动力学研究   总被引:6,自引:0,他引:6  
8头体重32.9±4.3kg(平均值土标准差)的健康长白×约克夏杂种猪,随机交叉设计试验,按10mg/kg静注或50mg/kg内服吡喹酮,给药间隔时间为2周。以乙醚萃取法提取血浆中的药物,反相高效液相色谱法测定血浆吡喹酮的浓度。非线性最小二乘法计算机程序拟合静注及内服的药时数据,分别适合二室开放模型及一级吸收一室开放模型。静注给药的动力学参数是:t1/2α0.31±0.08h,t1/2β1.50±0.57h,Vd(area)3.09±1.19 I/kg,Cl_B24.57±8.57ml/kg/min,AUC 7.48±2.36μg/ml·h。内服给药的动力学参数是:C_(max)0.27±0.21μg/ml,t_(max)0.97±0.50h,t1/2Ka 0.53±0.31h,t1/2 Ke 1.07±0.38h,tlag 0.07±0.08h,AUC 0.91±1.14μg/ml·h,F 3.20±5.7%。猪内服吡喹酮后,生物利用度很低的原因可能是吡喹酮在肝内有极强的首过效应。  相似文献   

11.
试验将20只2月龄健康番鸭,随机分为2组,每组10只,雌雄各半,分别进行静脉注射和口服硫酸头孢喹肟给药的药动学研究。静脉注射和口服的给药剂量分别为10和20 mg/kg。以反相HPLC测定血浆中硫酸头孢喹肟的浓度,血药浓度—时间数据用3P97药动学程序软件处理。鸭单剂量静脉注射给药后,血药浓度—时间数据符合无吸收二室开放模型,其主要动力学参数分别为:V(c),(1.146±0.02) L/kg;t1/2α,(0.290±0.02)h;t1/2β,(1.691±0.15)h;AUC (6.635±0.18)(mg·h)/L;CL(s),(1.508±0.04)L/(kg·h)。鸭口服硫酸头孢喹肟的血药浓度—时间数据符合一级吸收一室开放模型,主要动力学参数分别为:t1/2(ka),(0.45±0.05)h;t1/2(ke),(0.96±0.29)h;T(peak),(0.91±0.09)h;C(max),(3.14±0.64)mg/L;AUC,(8.29±1.26)(mg·h)/L;F,(62.55±0.10)%。硫酸头孢喹肟在体内的药动学特征表现为吸收迅速、分布广泛、消除迅速。但口服给药在鸭体内生物利用度低,可能由于硫酸头孢喹肟的脂溶性低,其在消化道吸收率低所致。但8 h内能保持有效血药浓度范围((0.14±0.03)~(3.14±0.64)μg/mL),可抑制鸭疫里默氏杆菌及其他细菌感染。  相似文献   

12.
为比较研究制备的伊维菌素长效透皮制剂与普通伊维菌素注射剂药物代谢及药效时间,本研究制备伊维菌素含量分别为0.5%、1.0%和1.5%的长效透皮制剂,采用高效液相色谱法检测不同药量相同体积伊维菌素长效透皮制剂和普通伊维菌素注射剂(1.0%)在家兔体内的药代动力学,并通过PKSolver药代动力学处理软件对数据进行分析。结果显示,0.5%、1.0%、1.5%伊维菌素长效透皮剂和1.0%普通注射剂吸收半衰期分别为0.81、0.52、1.02和0.12 d;达峰时间为1.55、0.97、1.62和0.42 d;峰浓度为47.36、72.02、115.30和99.53 ng/mL;消除半衰期为3.61、5.92、5.59和1.79 d;平均滞留时间为5.27、7.37、5.13和2.16 d;药时曲线面积为1 488.70、3 081.98、3 161.20和480.00 ng·d/mL,伊维菌素长效透皮剂体内维持有效药物浓度的时间长达35 d,普通注射剂仅为9 d。结果表明,伊维菌素长效透皮剂效果稳定,可进行更深入的研究。  相似文献   

13.
The pharmacokinetics of afoxolaner and milbemycin oxime (A3 and A4 forms) in dogs were evaluated following the oral administration of NexGard Spectra ® (Merial), a fixed combination chewable formulation of these two active pharmaceutical ingredients. Absorption of actives was rapid at levels that provide the minimum effective doses of 2.5 mg/kg and 0.5 mg/kg of afoxolaner and milbemycin oxime, respectively. The time to maximum afoxolaner plasma concentrations (tmax) was 2–4 h. The milbemycin tmax was 1–2 h. The terminal plasma half‐life (t1/2) and the oral bioavailability were 14 ± 3 days and 88.3% for afoxolaner, 1.6 ± 0.4 days and 80.5% for milbemycin oxime A3 and 3.3 ± 1.4 days and 65.1% for milbemycin oxime A4. The volume of distribution (Vd) and systemic clearance (Cls) were determined following an IV dose of afoxolaner or milbemycin oxime. The Vd was 2.6 ± 0.6, 2.7 ± 0.4 and 2.6 ± 0.6 L/kg for afoxolaner, milbemycin oxime A3 and milbemycin oxime A4, respectively. The Cls was 5.0 ± 1.2, 75 ± 22 and 41 ± 12 mL/h/kg for afoxolaner, milbemycin oxime A3 and milbemycin oxime A4, respectively. The pharmacokinetic profile for the combination of afoxolaner and milbemycin oxime supports the rapid onset and a sustained efficacy for afoxolaner against ectoparasites and the known endoparasitic activity of milbemycin oxime.  相似文献   

14.
为评价采用新包被工艺生产的氟苯尼考(受试制剂F)与国外同类产品(R1)、国内同类产品(R2)在猪体内的生物等效性并探索其药代动力学特性,本试验采用随机三制剂、三周期自身交叉试验设计,选取6头健康的阉割小公猪(体重15 kg±2 kg),分别灌胃给药3种制剂,给药剂量为20 mg/(kg·BW),采用高效液相色谱法测定血浆中氟苯尼考浓度,利用Kinetica 5.0软件分析药代动力学特性,SAS统计软件进行生物等效性评价。结果显示,受试制剂在猪体内的药时曲线符合带时滞的一级吸收一室开放模型,F、R1、R2的峰浓度(Cmax)分别为16.0845、18.3287和21.1678 μg/mL,药物达峰时间(Tmax)分别为5.0、1.9、1.5 h;药-时曲线下面积(0-∞)(AUC0-∞)分别为144.7327、118.2670和123.3715 μg/mL·h;受试制剂相比于两种参比制剂的相对生物利用度分别为122.51%(R1)和117.52%(R2)。结果表明,环糊精包被氟苯尼考有更好的缓释作用,具有更好的生物安全性,药效维持时间长,生物利用度有效提高。  相似文献   

15.
Two studies were performed to examine the efficacy of milbemycin oxime against fourth-stage larvae or adults of Toxocara cati. In the study to determine efficacy against fourth-stage larvae, 20 domestic shorthair cats were inoculated with 500 embryonated eggs. Four weeks after inoculation, the animals were allocated to two groups, and cats in one group were treated with medicated tablets containing 4 mg milbemycin oxime and 10mg praziquantel (MILBEMAX) and cats in the other group with placebo tablets. Seven days after treatment the animals were euthanatized and necropsied for worm counting. The number of worms found was significantly (p=0.0002) lower in cats treated with medicated tablets than in cats treated with placebo tablets. The reduction in the number of worms was 96.53%. In the study to determine efficacy against mature adult worms, 13 kittens were inoculated with T. cati embryonated eggs. On day 45 after inoculation and after the infection had been confirmed through faecal examinations for 11 out of the 13 animals, the 11 infected animals were allocated to two groups and treated as in the first study. Seven days after treatment, all animals were euthanatized and necropsied for worm counting. The number of worms found was significantly (p=0.0043) lower in kittens treated with medicated tablets than in kittens treated with placebo tablets. The reduction in the number of worms was 95.90%. No adverse effects were recorded during either study. It is concluded that the milbemycin oxime-praziquantel tablets that were used are efficacious for the control of T. cati infections in cats.  相似文献   

16.
The monodeiodination of thyroxine (T4) to triiodothyronine (T3) was studied in vitro using liver, kidney, and muscle obtained from two-year old Angus and Hereford steers. Tissues were homogenized in .1 M phosphate buffer-.25 M sucrose - 5 mM EDTA, pH 7.5, and centrifuged at 2000 × g for 30 min. Supernatants were incubated with T4 (1.3 μM) at 37 C and T3 generated was measured by radioimmunoassay of an ethanol extract of the incubation mixture. The T4 to T3 conversion in Angus liver homogenate was dependent upon pH, temperature, duration of incubation (5–120 min), homogenate (.025–.20 g-eq tissue/ml), and substrate concentration (.32–6.43 μM T4). The apparent Km and Vmax of the conversion were .64 μM T4 and 1.87 ng T3 generated/hr/mg protein, respectively. Mean T4 to T3 conversion in Angus liver and kidney was 1.37 and .22 ng T3/hr/mg protein. The presence of 2 mM dithiothreitol (DTT), a sulfhydryl protective agent, significantly increased T3 generation in liver and kidney (5.12 and 4.58 ng/hr/mg protein) and also revealed activity in muscle (05 ng/hr/mg protein). In liver and kidney from Hereford steers conversion activity was 2.89 and .48 in absence and 10.91 and 5.38 ng T3/hr/mg protein in presence of DTT, respectively. These results demonstrate the presence of a very active enzymatic system responsible for the peripheral 5′-monodeiodination of T4 to T3 in cattle.  相似文献   

17.
The purpose of this study was to evaluate the pharmacokinetics of lidocaine in mature Holstein cows following an inverted L and caudal epidural nerve block. Plasma and milk concentrations were determined using high-performance liquid chromatography assay. Pharmacokinetic parameters were estimated using a noncompartmental method. Following administration via inverted L nerve block, serum Tmax was 0.521 ± 0.226 h and serum Cmax was 572 ± 207 ng/mL. Serum AUC was 1348 ± 335 ng·h/mL. Apparent serum t½β was 4.19 ± 1.69 h and MRT was 5.13 ± 2.33 h with clearance uncorrected for the extent of absorption of 2.75 ± 0.68 L/kg/h. The last measurable time of lidocaine detection in serum was 8.5 ± 1.4 h with a mean concentration of 51 ± 30 ng/mL. Milk Tmax was detected at 1.75 ± 0.46 h with Cmax of 300 ± 139 ng/mL. Milk AUC till the last time was 1869 ± 450 ng·h/mL with the mean AUC milk to AUC serum ratio of 1.439 ± 0.374. The last measurable time of lidocaine detection in milk was 32.5 ± 16.2 h with a mean concentration of 46 ± 30 ng/mL. There was no detectable lidocaine concentration in any samples following caudal epidural administration.  相似文献   

18.
旨在制备并表征沙拉沙星/β-环糊精(SAR/β-CD)包合物微囊新制剂,测定增溶倍数和包封率,进行SAR/β-CD包合物微囊的体外溶出与体内药代动力学研究。采用搅拌法制备包合物微胶囊,用透射电镜、扫描电镜和粉末X光衍射技术进行物态表征。采用液相色谱法测定SAR/β-CD包合物微囊的增溶倍数和包封率,通过溶出试验研究SAR/β-CD包合物微囊在磷酸盐缓冲液(pH6.8)中的释放规律。最后,进行了环糊精包合物微囊在鸡体内的药代动力学评价。理化表征试验证明,药物进入β-环糊精空腔,成功获得了SAR/β-CD包合物微囊。3个试验批次的SAR/β-CD包合物微囊的平均增溶倍数和平均包封率分别为(25.3±1.15)倍和90.3%±0.15%。在磷酸盐缓冲液(pH6.8)中SAR/β-CD包合物微囊的溶出率为95.6%,而普通粉剂的溶出率仅为72.2%,包合反应后的制剂溶解度和溶出度均有显著提高。药代动力学试验中血药浓度检测的标准曲线为y=1.563 2x-0.189 6,R2=0.999 3,在0.25~10.00 μg·mL-1内呈良好的线性关系。分析方法的精密度RSD值小于10%,分析方法的准确度大于90%,同时小于110%;回收率试验表明,低浓度(0.50 μg·mL-1)回收率为90.55%±3.81%,中浓度(1.00 μg·mL-1)回收率为93.85%±3.14%,高浓度(2.50 μg·mL-1)回收率为98.19%±5.41%。冻融试验表明冻融稳定性(n=3)符合《中华人民共和国兽药典》(2015版)规定。鸡口服药代动力学试验表明,SAR/β-CD包合物微囊和沙拉沙星粉的AUC(mg·h-1·L-1)、Tmax(h)、Cmaxμg·mL-1)分别为43.59±0.50、2.18±0.09、5.99±0.30和17.27±0.30、0.98±0.07、1.19±0.10。成功制备沙拉沙星/β-环糊精包合物微囊新剂型,明显提高了药物的溶出率和生物利用度,对喹诺酮类药物的推广应用具有重要意义。  相似文献   

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