Pimentel José Rodrigo Valim, Maturana Filho Milton, Cardozo-Filho Lucio, Agnelli José Augusto M, Nascimento Jefter, Madureira Ed Hoffmann
Universidade de São Paulo, Faculdade de Medicina Veterinária e Zootecnia, Pirassununga, SP, Brazil.
Universidade Estadual de Maringá, SP, Brazil.
Anim Sci J. 2017 Oct;88(10):1658-1669. doi: 10.1111/asj.12755. Epub 2017 Apr 25.
The usage of timed artificial insemination (TAI) at a low cost leading to better reproductive rates has been the aim of several research groups in the field. Usually during TAI protocols, sustained progesterone (P ) release devices are employed. Most devices are constituted of a nylon skeleton covered with a silicon layer with P . A device based on biopolymers was developed in order to reduce costs and decrease its environmental impact. In this study, we compared the kinetics of sustained progesterone release among devices manufactured with a polymeric blend made of polyhydroxybutyrate-valerate (PHBV) and poly-ε-caprolactone (PCL) (DISP) which were compared with DIB® (Internal Bovine Device) used as the control. In the in vitro and in vivo progesterone release tests, two types of biopolymer-based devices with a superficial area of 147 cm were used: DISP8 (46% PHBV, 46% PCL and 8% P ; n = 4), DISP10 (45% PHBV, 45% PCL, 10% P ; n = 4) and DIB® (1 g P , 120 cm area; n = 3). The in vitro tests were carried out according to USP XXIII specifications and were performed in a dissolutor sink using an alcohol/water mixture (60/40 v/v) as a release media and samples were collected at 2 min, 2, 4, 8, 12, 24, 48, 60, 72, 84 and 96 h. P concentrations were measured through spectrophotometry in a 244 nm long wave. Three to 3 comparisons of angular coefficients of the straight lines obtained by regression analysis of accumulated P concentrations as a function of square root of time were carried out. Furthermore, the diffusion coefficient values of P were also determined for DISP8 and DISP10. The results showed that the concentrations of P were higher in the DISP10 (774.63 ± 45.26 μg/cm /t ) compared to DISP8 (566.17 ± 3.68 μg/cm /t ) (P < 0.05). However, both DISP10 and DISP8 P concentrations did not differ from DIB® (677.39 ± 16.13 μg/cm /t ). For the analysis of released quantities per day of the in vitro test, four periods were considered: 0-24, 24-48, 48-72 and 72-96 h. In the first 24 h, DISP8 released significantly less P than DISP10 or DIB®, which did not differ among them. Between 24 and 48 h, DISP10 released significantly more P than DIB®. DISP8 released an intermediate P amount and did not differ significantly from DIB® or DISP10. Between 48 and 72 h, P quantity released by DISP10 was significant higher (P < 0.01) than that of DIB® and DISP8, which did not differ among themselves. Between 72 and 96 h, DISP10 released significantly more P than DIB®, and DISP8 released an intermediate amount which did not differ from DIB® or DISP10 (P < 0.01). There was interaction between treatment and time (P = 0.0024). The diffusion coefficient values were: 1.36 × 10 (cm /s) for DISP10 and 1.12 × 10 (cm /s) for DISP8. For the in vivo test, ovariectomized crossbred cows received DIB® (n = 4) or DISP8 (n = 8) in an alternate design with a non-balanced sequence (cross-over) added of measures repeated in time referring to 16 days of blood samples collection. Samples were analyzed through radioimmunoassay in solid phase using the commercial kit of DPC (Diagnostics Products Corporation). Plasma concentrations of P peaked at 4 h after the placement of the device, this being the only time in which plasma P concentrations differed between DIB® (11.45 ± 1.96) compared with DISP8 (9.23 ± 1.15 ng/mL) (P = 0.027). On day 8, plasma P concentrations were similar for DIB® (2.44 ± 0.09) and DISP8 (1.89 ± 0.13 ng/mL) (P = 0.58) showing that both devices were able to keep P concentrations above 1 ng/mL in the plasma of the cow during the 16 day in vivo test. In conclusion, devices manufactured with the blend of PHBV/PCL biopolymers can sustain the release of P in a similar manner as silicon.
以低成本使用定时人工授精(TAI)并实现更高繁殖率,一直是该领域多个研究团队的目标。通常在TAI方案中,会使用持续释放孕酮(P)的装置。大多数装置由覆盖有含P硅层的尼龙骨架构成。为了降低成本并减少其对环境的影响,开发了一种基于生物聚合物的装置。在本研究中,我们比较了由聚羟基丁酸戊酸酯(PHBV)和聚ε-己内酯(PCL)制成的聚合物共混物制造的装置(DISP)与用作对照的DIB®(牛用内置装置)之间孕酮持续释放的动力学。在体外和体内孕酮释放试验中,使用了两种表面积为147 cm²的基于生物聚合物的装置:DISP8(46% PHBV、46% PCL和8% P;n = 4)、DISP10(45% PHBV、45% PCL、10% P;n = 4)和DIB®(1 g P,面积120 cm²;n = 3)。体外试验按照美国药典XXIII规范进行,在溶出度测定仪中使用乙醇/水混合物(60/40 v/v)作为释放介质,在2分钟、2、4、8、12、24、48、60、72、84和96小时采集样品。通过分光光度法在244 nm长波下测量P浓度。对累积P浓度作为时间平方根的函数进行回归分析得到的直线的角系数进行了3至3次比较。此外,还测定了DISP8和DISP10的P扩散系数值。结果表明,与DISP8(566.17 ± 3.68 μg/cm²/t)相比,DISP10(774.63 ± 45.26 μg/cm²/t)中的P浓度更高(P < 0.05)。然而,DISP10和DISP8的P浓度与DIB®(677.39 ± 16.13 μg/cm²/t)并无差异。对于体外试验每天释放量的分析,考虑了四个时间段:0 - 24、24 - 48、48 - 72和72 - 96小时。在最初的24小时内,DISP8释放的P明显少于DISP10或DIB®,后两者之间无差异。在24至48小时之间,DISP10释放的P明显多于DIB®。DISP8释放的P量居中,与DIB®或DISP10无显著差异。在48至72小时之间,DISP10释放的P量显著高于(P < 0.01)DIB®和DISP8,后两者之间无差异。在72至96小时之间,DISP10释放的P明显多于DIB®,DISP8释放的量居中,与DIB®或DISP10无差异(P < 0.01)。处理和时间之间存在交互作用(P = 0.0024)。扩散系数值分别为:DISP10为1.36 × 10⁻⁶(cm²/s),DISP8为1.12 × 10⁻⁶(cm²/s)。对于体内试验,去卵巢杂交奶牛以交替设计接受DIB®(n = 4)或DISP8(n = 8),采用非平衡序列(交叉),并在16天的血样采集过程中重复测量。使用DPC(诊断产品公司)的商业试剂盒通过固相放射免疫分析法对样品进行分析。放置装置后4小时血浆P浓度达到峰值,这是DIB®(11.45 ± 1.96)与DISP8(9.23 ± 1.15 ng/mL)之间血浆P浓度唯一存在差异的时间(P = 0.027)。在第8天,DIB®(2.44 ± 0.09)和DISP8(1.89 ± 0.13 ng/mL)的血浆P浓度相似(P = 0.58),表明在16天的体内试验期间,两种装置都能够使奶牛血浆中的P浓度保持在1 ng/mL以上。总之,由PHBV/PCL生物聚合物共混物制造的装置能够以与硅类似的方式持续释放P。
