Zerbinati C, Caponecchia L, Rago R, Leoncini E, Bottaccioli A G, Ciacciarelli M, Pacelli A, Salacone P, Sebastianelli A, Pastore A, Palleschi G, Boccia S, Carbone A, Iuliano L
Vascular Biology & Mass Spectrometry Laboratory, Department of Medico-Surgical Sciences and Biotechnologies, Sapienza University of Rome, Latina, Italy.
Center for Couple Infertility and Andrology, S. M. Goretti Hospital, Latina, Italy.
Andrology. 2016 Nov;4(6):1094-1101. doi: 10.1111/andr.12236. Epub 2016 Sep 27.
Previous reports showed altered fatty acid content in subjects with altered sperm parameters compared to normozoospermic individuals. However, these studies focused on a limited number of fatty acids, included a short number of subjects and results varied widely. We conducted a case-control study involving 155 patients allocated into four groups, including normozoospermia (n = 33), oligoasthenoteratozoospermia (n = 32), asthenozoospermia (n = 25), and varicocoele (n = 44). Fatty acid profiling, including 30 species, was analyzed by a validated gas chromatography (GC) method on the whole seminal fluid sample. Multinomial logistic regression modeling was used to identify the associations between fatty acids and the four groups. Specimens from 15 normozoospermic subjects were also analyzed for fatty acids content in the seminal plasma and spermatozoa to study the distribution in the two compartments. Fatty acids lipidome varied markedly between the four groups. Multinomial logistic regression modeling revealed that high levels of palmitic acid, behenic acid, oleic acid, and docosahexaenoic acid (DHA) confer a low risk to stay out of the normozoospermic group. In the whole population, seminal fluid stearic acid was negatively correlated (r = -0.53), and DHA was positively correlated (r = 0.65) with sperm motility. Some fatty acids were preferentially accumulated in spermatozoa and the highest difference was observed for DHA, which was 6.2 times higher in spermatozoa than in seminal plasma. The results of this study highlight complete fatty acids profile in patients with different semen parameters. Given the easy-to-follow and rapid method of analysis, fatty acid profiling by GC method can be used for therapeutic purposes and to measure compliance in infertility trials using fatty acids supplements.
先前的报告显示,与正常精子的个体相比,精子参数改变的受试者体内脂肪酸含量发生了变化。然而,这些研究集中于数量有限的脂肪酸,纳入的受试者数量较少,且结果差异很大。我们进行了一项病例对照研究,涉及155名患者,分为四组,包括正常精子症(n = 33)、少弱畸精子症(n = 32)、弱精子症(n = 25)和精索静脉曲张(n = 44)。采用经过验证的气相色谱(GC)方法,对整个精液样本分析了包括30种脂肪酸的谱图。采用多项逻辑回归模型来确定脂肪酸与这四组之间的关联。还对15名正常精子症受试者的样本进行了精浆和精子中的脂肪酸含量分析,以研究这两个部分中的分布情况。四组之间的脂肪酸脂质组有明显差异。多项逻辑回归模型显示,高水平的棕榈酸、山嵛酸、油酸和二十二碳六烯酸(DHA)使处于非正常精子症组的风险较低。在整个人群中,精液中的硬脂酸与精子活力呈负相关(r = -0.53),而DHA与精子活力呈正相关(r = 0.65)。一些脂肪酸优先在精子中积累,DHA的差异最为显著,其在精子中的含量比精浆中高6.2倍。本研究结果突出了不同精液参数患者的完整脂肪酸谱图。鉴于气相色谱法易于操作且分析快速,通过该方法进行的脂肪酸谱图分析可用于治疗目的,并用于衡量使用脂肪酸补充剂的不孕症试验中的依从性。
