猪胎盘的发育。

J. Vallet, J. Miles, B. Freking
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引用次数: 41

摘要

胎盘功能不全导致胎儿丢失,低出生体重,死胎,断奶前死亡率和生长不良。胎盘发育开始于妊娠期延长,这是控制胎盘大小的主要因素。延长后,尿囊从胚胎向外发育,形成尿囊绒毛膜,这决定了功能性胎盘的大小。在植入过程中,绒毛膜滋养细胞粘附在子宫内膜上皮细胞上。被称为乳晕的胎盘结构在子宫内膜腺的开口处发育,并吸收子宫内膜腺分泌的产物(组织细胞)。在妊娠第30 ~ 35天,粘附的滋养细胞-子宫内膜上皮双分子层发生显微折叠。胎儿和母亲的毛细血管在双分子层附近发育,血流以交叉逆流的方式排列。除了由腺体分泌营养物质外,营养物质在这些褶皱内的毛细血管之间进行交换。到第85天,褶皱加深,变得更加复杂,表面积增加。上皮双分子层变薄,毛细血管缩进每层的平面(但不穿透),减少毛细血管之间的距离。折叠的双分子层被母体侧的子宫内膜间质和胎儿侧的胎盘间质所包围。胎儿-胎盘间质部分由糖胺聚糖组成,其中最丰富的是透明质酸和硫酸肝素。胎盘发育过程中透明质糖氨基酶和肝素酶的变化表明这些酶在胎盘发育中起作用。除了结构变化外,还存在多种营养物质特异性运输机制。这些机制可能与胎盘的大小或结构一样重要。
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Development of the pig placenta.
Placental insufficiency results in fetal loss, low birth weight, stillbirth, preweaning mortality and poor growth. Placental development begins at conceptus elongation, which is a primary factor controlling the size of the placenta. After elongation, the allantois develops outward from the embryo to establish the allantochorion, which defines the size of the functional placenta. During implantation, chorionic trophoblasts adhere to endometrial epithelial cells. Placental structures known as areolae develop at the openings of the endometrial glands and take up endometrial gland secreted products (histotrophe). Between day 30 and 35 of gestation, the adhered trophoblast-endometrial epithelial bilayer undergoes microscopic folding. Fetal and maternal capillaries develop adjacent to the bilayer and blood flows are arranged in a cross-countercurrent manner. Except for nutrients secreted by the glands, nutrient exchange takes place between these capillaries within these folds. By day 85, the folds deepen and become more complex, increasing surface area. The epithelial bilayer thins and capillaries indent the plane of each layer (but do not penetrate), reducing distance between capillaries. The folded bilayer is surrounded by endometrial stroma on the maternal side and placental stroma on the fetal side. The fetal-placental stroma is partially composed of glycosaminoglycans, the most abundant being hyaluronan and heparan sulfate. Changes in both hyaluronoglucosaminidase and heparanase during placental development suggest that these enzymes play a role in placental development. In addition to structural modifications, various nutrient specific transport mechanisms exist. These mechanisms are likely to be as important to transport of specific nutrients as placental size or structure.
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Development of the pig placenta. Conceptus-uterus interactions in pigs: endometrial gene expression in response to estrogens and interferons from conceptuses. Temporal candidate gene expression patterns in the sow placenta during early gestation and the effect of maternal L-arginine supplementation. Genetic selection for lifetime reproductive performance. Global protein profiling of porcine cumulus cells in response to native oocyte secreted factors in vitro.
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