【佳學基因檢測】健康生育之路：什么是卵裂球、桑葚胚、囊胚、原腸胚及胚胎

受精（Fertilization）

當精子和卵細胞結合產生合子（或者是）受精卵時，這就是受精過程。當受精卵向子宮移動時，開始分裂過程。

如果妊娠過程是從植入開始，導致妊娠的雌性配子或者是卵細胞與雄性配子或者是精子的結合則發(fā)生在更早的時候。在醫(yī)學上，這個過程叫做受精，用非專業(yè)的話來講，也就是通俗的說，就是受孕。

受精后，雄性配子和雌性配子的結合產物被稱為合子或者受精卵。對于人來說，采用的是體內受精過程，雌性和雄性配子的結合實際上發(fā)生在性交之后。

但是，人工受精和體外受精的出現(xiàn)，使得沒有性交過程也可以開啟妊娠。這個方法可以是自愿選擇，也可以是因為不育的原因。

 

人類的受精: 精子和卵細胞通過受精而結合產生合子，在8天左右，合子植入到子宮壁上，長達9個月。

受精過程有多個bucu，其中任何一個收到干擾都會導致失敗。在這個過程的開始，精子經過一系列的變化，因為剛剛射出的精子不能夠受精，或者受精能力不足。

精子在女性生殖道里，經過幾個小時的獲能的過程，增加運動能力，降低膜的穩(wěn)定性。通過降低膜的穩(wěn)定性，精子為頂體反應做好準備。頂體反應穿過堅硬的透明帶膜的酶促反應過程。精子和從兩個卵巢中的一個釋放出來的卵細胞在輸卵管（fallopian tubes）結合。

受精卵，又稱為合子，然后移動到子宮，這個行程需要近一個星期的時間，才能植入到子宮壁上。通過受精，卵細胞活化，開啟發(fā)育過程，完成第二次減數(shù)分裂，兩個單倍體核結合在一起形成新的二倍體的基因組。

減數(shù)分裂過程中的不分離及從合子到囊胚的早期分裂過程的出現(xiàn)的問題會導致無法植入或者是妊娠失敗。

Cleavage of the Zygote

The process of cleavage is the step of embryogenesis where the zygote divides to produce a cluster of cells known as the morula.

Cell division with no significant growth that produces a cluster of cells that is the same size as the original zygote, is called cleavage. At least four initial cell divisions occur, resulting in a dense ball of at least sixteen cells called the morula.

The different cells derived from cleavage up to the blastula stage are called blastomeres. Depending mostly on the amount of yolk in the egg, the cleavage can be holoblastic (total) or meroblastic (partial).

 

Cell cleavage: Early development is characterized by cleavage of the zygote, which refers to cell divisions that are not associated with significant growth of the embryo.

Holoblastic cleavage occurs in animals with little yolk in their eggs. These species, such as humans and other mammals, receive nourishment as embryos from the mother via the placenta or milk after birth.

On the other hand, meroblastic cleavage occurs in animals whose eggs have more yolk, such as birds and oviparous reptiles (although some viviparous reptiles also exist). Since cleavage is impeded by the vegetal pole, there is a very uneven distribution and size of cells. Cells are more numerous and smaller at the animal pole of the zygote than at the vegetal pole.

In holoblastic eggs, the first cleavage always occurs along the vegetal–animal axis of the egg, and the second cleavage is perpendicular to the first. From here, the spatial arrangement of blastomeres can follow various patterns, due to different planes of cleavage in various organisms.The end of cleavage is known as the midblastula transition and coincides with the onset of zygotic transcription.

In amniotes, the cells of the morula are at first closely aggregated. However, they quickly become arranged into an outer or peripheral layer, the trophoblast, and an inner cell mass. The trophoblast does not contribute to the formation of the embryo proper; the embryo develops from the inner cell mass.

Fluid collects between the trophoblast and the greater part of the inner cell mass, and thus the morula, is converted into the blastodermic vesicle (also called the blastocyst or blastula). The inner cell mass remains in contact with the trophoblast at one pole of the ovum. This is named the embryonic pole, since it indicates the location where the future embryo will develop.

In the case of monozygotic twins (derived from one zygote), a zygote divides into two separate cells (embryos) at the first cleavage division. Monozygotic twins can also develop from two inner cell masses.

A rare occurrence is the division of a single inner cells mass giving rise to twins. However, if one inner cell mass divides incompletely, the result is conjoined twins. Dizygotic twins is the development of two embryos from two different zygotes.

Blastocyst Formation

The blastocyst forms early in embryonic development and has two layers that form the embryo and placenta.

In humans, the blastocyst is formed approximatelyy five days after fertilization. This stage is preceded by the morula. The morula is a solid ball of about 16 undifferentiated, spherical cells. As cell division continues in the morula, the blastomeres change their shape and tightly align themselves against each other. This is called compaction and is likely mediated by cell surface adhesion glycoproteins.

The blastocyst possesses an inner cell mass (ICM), or embryoblast, which subsequently forms the embryo, and an outer layer of cells, or trophoblast, which later forms the placenta. The trophoblast surrounds the inner cell mass and a fluid-filled, blastocyst cavity known as the blastocoele or the blastocystic cavity.

The embryoblast is the source of embryonic stem cells and gives rise to all later structures of the adult organism. The trophoblast combines with the maternal endometrium to form the placenta in eutherian mammals.

 

Blastocyst: The blastocyst possesses an inner cell mass from which the embryo will develop, and an outer layer of cells, called the trophoblast, which will eventually form the placenta.

Before gastrulation, the cells of the trophoblast become differentiated into two strata. The outer stratum forms a syncytium, which is a layer of protoplasm studded with nuclei that shows no evidence of subdivision into cells (termed the syncytiotrophoblast).

The inner layer, the cytotrophoblast or layer of Langhans, consists of well-defined cells. As already stated, the cells of the trophoblast do not contribute to the formation of the embryo proper; they form the ectoderm of the chorion and play an important part in the development of the placenta.

On the deep surface of the inner cell mass, a layer of flattened cells, called the endoderm, is differentiated and quickly assumes the form of a small sac, called the yolk sac. Spaces appear between the remaining cells of the mass and, by the enlargement and coalescence of these spaces, a cavity called the amniotic cavity is gradually developed.

The floor of this cavity is formed by the embryonic disk, which is composed of a layer of prismatic cells called the embryonic ectoderm. This layer is derived from the inner cell mass and lies in opposition to the endoderm.

Implantation

Implantation is the very early stage of pregnancy at which the embryo adheres to the wall of the uterus and begins to form the placenta.

Implantation is the very early stage of pregnancy during which the embryo embeds into the wall of the uterus. At this stage of prenatal development, the embryo is a blastocyst.

It is by this adhesion that the fetus receives oxygen and nutrients from the mother to be able to grow. In humans, implantation of a blastocyst occurs between 6 to 12 days after ovulation.

In preparation for implantation, the blastocyst sheds its outside layer, the zona pellucida, which binds sperm during fertilization. The zona pellucida degenerates and decomposes, and is replaced by a layer of underlying cells called the trophoblast.

The trophoblast will give rise to the placenta after implantation. During implantation, the trophoblast differentiates into two distinct layers: the inner cytotrophoblast, and the outer syncytiotrophoblast.

 

Chorionic villi: During implantation, extensions of the trophoblast, the syncytiotrophoblasts, embed within the endometrium and form chorionic villi.

The syncytiotrophoblast then implants the blastocyst into the endometrium of the uterus by forming finger-like projections into the uterine wall called chorionic villi. The chorionic villi grow outwards until they come into contact with the maternal blood supply.

The chorionic villi will be the border between maternal and fetal blood during the pregnancy, and the location of gas and nutrient exchange between the fetus and the mother. The creation of chorionic villi is assisted by hydrolytic enzymes that erode the uterine epithelium.

The syncytiotrophoblast also produces human chorionic gonadotropin (hCG), a hormone that notifies the mother’s body that she is pregnant and prevents menstruation by sustaining the function of the progesterone-producing corpus luteum within the ovary.

Human chorionic gonadotropin is the hormone that is detected by pregnancy tests, as it is found in the maternal bloodstream and urine.