Changes

#*Fertilisation produces a unicellular zygote which undergoes a series of mitotic divisions to eventually become a multicellular organism known as a [[Fertilisation, Implantation and Early Embryonic Development -Embryonic Development of the Blastocyst- Anatomy & Physiology|blastocyst]]. Mitosis produces (i) growth by hyperplasia (ii) an increased number of cells for greater diversity of function, and thus more complex organism. The first differentiation of cells includes trophoblasts that contain adhesion molecules to adhere to the endometrium during [[Developmental Biology - Implantation - Anatomy & Physiology|implantation]]. The extent of cellular growth and division and the time taken for implantation differs between [[Fertilisation, Implantation and Early Embryonic Development -Implantation- Anatomy & Physiology|species]].  

#*Fertilisation produces a unicellular zygote which undergoes a series of mitotic divisions to eventually become a multicellular organism known as a [[Fertilisation, Implantation and Early Embryonic Development -Embryonic Development of the Blastocyst- Anatomy & Physiology|blastocyst]]. Mitosis produces (i) growth by hyperplasia (ii) an increased number of cells for greater diversity of function, and thus more complex organism. The first differentiation of cells includes trophoblasts that contain adhesion molecules to adhere to the endometrium during [[Developmental Biology - Implantation - Anatomy & Physiology|implantation]]. The extent of cellular growth and division and the time taken for implantation differs between [[Fertilisation, Implantation and Early Embryonic Development -Implantation- Anatomy & Physiology|species]].  

#'''Cell differentiation'''

#'''Cell differentiation'''

#*As embryogenesis progresses, cells become specialised in structure and function. Regulation of gene expression allows different proteins to be expressed in some cells, allowing different tissues to exists despite all cells containing the same DNA. At the blastomere stage (16 cells) cells are '''totipotent''', meaning they have the capacity to form every adult cell type. As the embryo progresses and enters [[Developmental Biology - Gastrulation - Anatomy & Physiology|gastrulation]] cells become '''pluripotent''', meaning they can form several but not all cell types. Eventually, most cells terminally differentiate and can no longer form any other cell type.   

#*As embryogenesis progresses, cells become specialised in structure and function. Regulation of gene expression allows different proteins to be expressed in some cells, allowing different tissues to exists despite all cells containing the same DNA. At the blastomere stage (16 cells) cells are '''totipotent''', meaning they have the capacity to form every adult cell type. As the embryo progresses and enters [[Developmental Biology - Gastrulation - Anatomy & Physiology|gastrulation]] cells become '''pluripotent''', meaning they can form several but not all cell types. Gastrulation is the process of forming the three germ layers; ectoderm, mesoderm and endoderm. Eventually, most cells terminally differentiate and can no longer form any other cell type.   

#'''Morphogenesis'''

#'''Morphogenesis'''

#*During embryogenesis two cell types exist; mesenchymal and epithelial. Mesenchymal cells are single or loosely linked to other cells and irregularly shaped. Epithelial cells are tightly attached to each other or a membrane and have a regular shape (cuboidal or columnar).

#*During embryogenesis two cell types exist; mesenchymal and epithelial. Mesenchymal cells are single or loosely linked to other cells and irregularly shaped. Epithelial cells are tightly attached to each other or a membrane and have a regular shape (cuboidal or columnar).