Battut I Barrier, Kempfer A, Lemasson N, Chevrier L, Camugli S
I.F.C.E, E.S.C.E., la Jumenterie du Pin, 61310 Exmes, France.
I.F.C.E, E.S.C.E., la Jumenterie du Pin, 61310 Exmes, France.
Theriogenology. 2017 Jul 15;97:186-200. doi: 10.1016/j.theriogenology.2017.04.036. Epub 2017 Apr 27.
Spermatozoa from some stallions do not maintain an acceptable fertility after freezing and thawing. The selection of frozen ejaculates that would be suitable for insemination is mainly based on post-thaw motility, but the prediction of fertility remains limited. A recent study in our laboratory has enabled the determination of a new protocol for the evaluation of fresh stallion semen, combining microscopical observation, computer-assisted motility analysis and flow cytometry, and providing a high level of fertility prediction. The purpose of the present experiment was to perform similar investigations on frozen semen. A panel of tests evaluating a large number of compartments or functions of the spermatozoa was applied to a population of 42 stallions, 33 of which showing widely differing fertilities (17-67% pregnancy rate per cycle [PRC]). Variability was evaluated by calculating the coefficient of variation (CV=SD/mean) and the intra-class correlation or "repeatability" for each variable. For paired variables, mean within-stallion CV% was significantly lower than between-stallion CV%, which was significantly lower than total CV%. Within-ejaculate repeatability, determined by analysing 6 straws for each of 10 ejaculates, ranged from 0.60 to 0.97. Within-stallion repeatability, determined by analysing at least 5 ejaculates for each of 38 stallions, ranged from 0.12 to 0.95. Principal component regression using a combination of 25 variables, including motility, morphology, viability, oxidation level, acrosome integrity, DNA integrity and hypoosmotic resistance, accounted for 94.5% of the variability regarding fertility, and was used to calculate a prediction of the PRC with a mean standard deviation of 2.2. The difference between the observed PRC and the calculated value ranged from -3.4 to 4.2. The 90% confidence interval (90CI) for the prediction of the PRC for the stallions of unknown fertility ranged from 8 to 30 (mean = 17). The best-fit model using only motility variables, evaluated after 10 min at 36 °C and 2 h at 36 °C or room temperature, accounted for only 74.2% of the variability. The difference between the observed PRC and the calculated value ranged from -7.2 to 14. The 90CI for the prediction of the PRC for the stallions of unknown fertility ranged from 23 to 48 (mean = 33). In conclusion, this study demonstrated that an appropriate combination of computer-assisted motility analysis, microscopical observation and flow cytometry can provide a higher prediction of fertility than motility analysis alone.
一些种公马的精子在冷冻和解冻后无法保持可接受的生育能力。选择适合授精的冷冻精液主要基于解冻后的活力,但生育能力的预测仍然有限。我们实验室最近的一项研究确定了一种评估新鲜种公马精液的新方案,该方案结合了显微镜观察、计算机辅助活力分析和流式细胞术,能够提供较高水平的生育能力预测。本实验的目的是对冷冻精液进行类似的研究。一组评估精子大量组成部分或功能的测试应用于42匹种公马,其中33匹的生育能力差异很大(每个周期的妊娠率[PRC]为17%-67%)。通过计算每个变量的变异系数(CV=标准差/平均值)和组内相关性或“重复性”来评估变异性。对于配对变量,种公马内的平均CV%显著低于种公马间的CV%,而种公马间的CV%又显著低于总CV%。通过分析10份精液中的每份6根细管确定的射精内重复性范围为0.60至0.97。通过分析38匹种公马中每匹至少5份精液确定种公马内重复性范围为0.12至0.95。使用包括活力、形态、活力、氧化水平、顶体完整性、DNA完整性和低渗抗性在内的25个变量组合的主成分回归解释了生育能力变异性的94.5%,并用于计算PRC的预测值,平均标准差为2.2。观察到的PRC与计算值之间的差异范围为-3.4至4.2。未知生育能力种公马PRC预测的90%置信区间(90CI)为8至30(平均值=17)。仅使用活力变量的最佳拟合模型,在36°C下10分钟和36°C或室温下2小时后进行评估,仅解释了74.2%的变异性。观察到的PRC与计算值之间的差异范围为-7.2至14。未知生育能力种公马PRC预测的90CI为23至48(平均值=33)。总之,本研究表明,计算机辅助活力分析、显微镜观察和流式细胞术的适当组合比单独的活力分析能提供更高的生育能力预测。
