Many changes occur throughout the embryonic stage, and each one is significant in its way. First and foremost, the cells of the embryo (known as embryonic stem cells) multiply and progress in their development. They develop into the hundreds of different types of cells that are required to construct a complete human body. The primary organs and body parts of your baby begin to take shape at this point.
During the embryonic stage, the placenta begins to develop. The placenta absorbs nutrients, oxygen, and water from your blood and transfers them to your baby through the umbilical cord to keep him or her healthy. It also eliminates the trash produced by the baby. The placenta is responsible for filtering out the majority of potentially dangerous compounds that may be present in your body.
During this period, the amniotic sac is also formed. It is filled with amniotic fluid, which surrounds and protects the baby as it is growing inside your uterus during pregnancy.
Fertilisation
Fertilisation is the process by which gametes (egg and sperm) fuse to form a zygote, which is a fertilised egg. Every cell in the body, including the egg and sperm, contains one set of chromosomes. Only one sperm must fuse with a single egg to ensure that the offspring has a single full diploid pair of chromosomes. In mammals, the egg is protected by a layer of extracellular matrix termed the zona pellucida, which is composed primarily of glycoproteins and serves to keep the egg from becoming infected. When a sperm adheres to the zona pellucida, a series of biochemical activities known as acrosomal reactions take place, which is responsible for fertilisation. Among placental mammals, the acrosome contains digestive enzymes that begin the breakdown of the glycoprotein matrix that protects the egg, allowing the sperm plasma membrane to fuse with the egg plasma membrane. In humans, the acrosome contains digestive enzymes that help with the development of the embryo. It is through the fusing of these two membranes that the sperm nucleus is transmitted from the ovum to the sperm cell. In a process known as nuclear membrane breakdown, the two haploid genomes of the egg and sperm combine to produce a single diploid genome.
Stages of Cleavage and Blastula
The development of multi-cellular organisms begins with the formation of a single-celled zygote, which divides rapidly to become the blastula, the first stage of development. Cleavage is the term used to describe the rapid, repeated rounds of cell division that occur. The embryo is referred to be a blastula if it contains more than 100 cells after the cleavage. It is customary for the blastula to be composed of a spherical layer of cells (the blastoderm) enclosing a fluid- or yolk-filled cavity (the blastocoel). At this stage, mammals create a structure known as the blastocyst, which is distinguished from the surrounding blastula by the presence of an inner cell mass that is separate from the surrounding blastula. Cleavage occurs when cells divide without increasing in mass, resulting in several smaller cells being formed from a single big single-celled zygote during development. The blastomere is the name given to each cell within the blastula.
Cleavage can occur in two ways: either through holoblastic (complete) cleavage or meroblastic (partial) cleavage. The amount of yolk in the eggs determines the sort of cleavage that occurs. Placental mammals (including humans) that rely on the mother’s body for food have very little yolk and suffer holoblastic cleavage, which means they have very little yolk and cleave very quickly. Another group of species, such as birds, that have an abundant amount (and therefore need) of yolk in their eggs to support the embryo during development, go through meroblastic cleavage.
In mammals, the blastula is responsible for the formation of the blastocyst during the following stage of development. The cells in the blastula form two layers: an inner cell mass and an outer layer known as the trophoblast. The inner cell mass is composed of cells that are arranged in a spiral pattern. The inner cell mass, also known as the embryoblast, is the collection of cells that will eventually come together to create the embryo. The inner cell mass of the organism during this stage of development is made up of embryonic stem cells, which will differentiate into the many cell types required by the organism as it grows. The trophoblast will contribute to the formation of the placenta and the nourishment of the embryo.
Gastrulation
A blastula is a clump of cells that is common in embryonic development. The construction of the body plan is the next stage in the development of the embryonic body. The cells in the blastula rearrange themselves spatially, resulting in three layers of cells in the final structure. Gastrulation is the term used to describe this process. In gastrulation, the blastula folds within itself to generate the three layers of cells that are visible on the surface of the embryo. Each of these layers is referred to as a germ layer, and each of these germ layers divides into a separate organ system as the layers progress.
The endoderm, the ectoderm, and the mesoderm are the three germ layers that make up the embryo. The ectoderm is responsible for the development of the nervous system and the epidermis. The mesoderm is responsible for the formation of muscle cells and connective tissue throughout the body. The endoderm is responsible for the formation of columnar cells, which are found in the digestive system and many other internal organs.
Conclusion
The process of fertilisation marks the beginning of the embryonic development process. To ensure that only one sperm fuses with a single egg, the fertilisation process is meticulously monitored and controlled. Following fertilisation, the zygote undergoes cleavage, which results in the formation of the blastula. It is during the process of gastrulation that the blastula, which is a hollow ball of cells in some species, is formed, and this is when the three germ layers are formed. The nervous system and epidermal skin cells are produced by the ectoderm, while muscle cells and connective tissue are produced by the mesoderm, and columnar cells and internal organs are produced by the endoderm.
The ectoderm is responsible for the development of the nervous system and epidermal skin cells, the mesoderm is responsible for the development of muscle cells and connective tissue in the body, and the endoderm is responsible for the development of columnar cells and internal organs.