Human development days 1-4

77,000views

Human development days 1-4

1h

1h

Fat-soluble vitamin deficiency and toxicity: Pathology review
Water-soluble vitamin deficiency and toxicity: B1-B7: Pathology review
Relative and absolute risk
Study designs
Cross sectional study
Case-control study
Randomized control trial
Cohort study
Clinical trials
Selection bias
Cytoskeleton and intracellular motility
Endocytosis and exocytosis
Cell membrane
Extracellular matrix
Nuclear structure
DNA structure
Transcription of DNA
Translation of mRNA
Gene regulation
Amino acids and protein folding
DNA replication
DNA damage and repair
Cell cycle
Mitosis and meiosis
DNA mutations
Human development days 1-4
Human development week 2
Human development days 4-7
Human development week 3
Artery and vein histology
Arteriole, venule and capillary histology
Pancreas histology
Central nervous system histology
Peripheral nervous system histology
Bacterial structure and functions
Necrosis and apoptosis
Ischemia
Hypoxia
Inflammation
Wound healing
Hyperplasia and hypertrophy
Atrophy, aplasia, and hypoplasia
Hypertension
Deep vein thrombosis
Shock
Shock: Pathology review
Diabetes mellitus
Diabetic nephropathy
Diabetes mellitus: Pathology review
Non-alcoholic fatty liver disease
Type I hypersensitivity
Type II hypersensitivity
Type III hypersensitivity
Type IV hypersensitivity
Priapism
Enzyme function
Pharmacokinetics: Drug absorption and distribution
Pharmacokinetics: Drug metabolism
Pharmacokinetics: Drug elimination and clearance
Cholinergic receptors
Drug administration and dosing regimens
Adrenergic receptors
Lipid-lowering medications: Statins
Insulins
Anticoagulants: Warfarin
Anticoagulants: Heparin
Blood pressure, blood flow, and resistance
Microcirculation and Starling forces
Renin-angiotensin-aldosterone system
Endocrine system anatomy and physiology
Hunger and satiety
Insulin
Glucagon
Cortisol
Coagulation (secondary hemostasis)
Role of Vitamin K in coagulation
Clot retraction and fibrinolysis
Introduction to the immune system
Cytokines
Innate immune system
Complement system
T-cell development
B-cell development
MHC class I and MHC class II molecules
T-cell activation
B-cell activation, differentiation, and contraction
Cell-mediated immunity of CD4 cells
Cell-mediated immunity of natural killer and CD8 cells
Antibody classes
Somatic hypermutation and affinity maturation
Contracting the immune response and peripheral tolerance
B- and T-cell memory
Hair, skin and nails
Muscular system anatomy and physiology
Slow twitch and fast twitch muscle fibers
Sliding filament model of muscle contraction
Pyramidal and extrapyramidal tracts
Somatosensory receptors
Somatosensory pathways
Sympathetic nervous system
Parasympathetic nervous system
Body temperature regulation (thermoregulation)
Physiologic pH and buffers
Respiratory acidosis
Respiratory alkalosis
Metabolic acidosis
Metabolic alkalosis

Transcript

Watch video only

Content Reviewers

Rishi Desai, MD, MPH

Human development begins with fertilization, which is the moment when a sperm cell and an oocyte (or egg cell) fuse to form a zygote, the seed of what will eventually grow into a human baby.

During sex, semen containing about 200 million spermatozoa (or sperm) enters the vagina.

This seminal fluid is alkaline, which means it’s capable of neutralizing acidic vaginal fluids.

The sperm quickly make their way through the cervix and uterus and swim into the fallopian tubes, which are also called the uterine tubes.

Eventually, these millions of sperm enter the ampulla of the uterine tube and then the infundibulum, an opening which flowers out next to the ovary.

By this point, most of the 200 million sperm that entered the body during sex have died for numerous reasons: some got stuck in the vaginal mucus, others ended up lost in the cervix, and the rest were killed and absorbed by the white blood cells.

About a thousand lucky survivors are left to wait in the uterine tube for the egg to arrive.

As the sperm wait, they start to rub up against the walls of the uterine tube, and that helps them remove the protective glycoprotein coat and plasma membrane covering the acrosome, a cap-like structure covering what you might think of as the sperm’s head. This process is called capacitation.

Once these protective outer layers are gone, the sperm are able to secrete an enzyme called hyaluronidase which can break down hyaluronic acid, a major component of the extracellular matrix protecting the egg.

Now, the egg is the largest cell in the human body, big and round, the size of a grain of sand.

As you’ll soon see, it’s kind of like an onion, as it’s made up of many layers.

The sperm trying to enter and fertilize this big egg are the smallest cells in the human body—about 1/30th the size of the egg—and they’re long and thin.

The most intrepid sperm make their way past the extracellular matrix surrounding the egg to a deeper layer called the corona radiata, which is made up of follicular cells.

The sperm then make their way through the corona radiata to the zona pellucida, another layer of extracellular matrix made of glycoproteins, which protects the egg. Only about 500 sperm cells make it this far!

The zona pellucida is also called the jelly coat, since it’s a clear, jelly-like covering wrapped around the egg.

The jelly coat/zona pellucida lies over another layer, this one made up of a protein called zona pellucida sperm-binding protein 3, or ZP3 protein for short.

As sperm close in on the zona pellucida, they undergo a process called the acrosome reaction, which happens in two parts.

First, the sperm release acrosin, a hydrolytic enzyme that bores a hole in the jelly-like coating of the zona pellucida.

After that, the sperm start assembling actin proteins, which fold out like a large protein crane, anchoring and binding the sperm to the ZP3 proteins.

Once the sperm is anchored to the surface of the egg, the plasma membrane overlying the sperm and the egg begin to fuse together—this is called sperm-binding.

Now, the egg contains cortical granules which are like bags of enzymes, one being peroxidase.

Key Takeaways

Human development starts with fertilization on day one. This involves the fusion of an oocyte and a spermatozoon to form a single-celled zygote. During the next 36 hours after fertilization, mitotic division or cleavage takes place, leading to two cells (known as blastomeres). Series of cleavages continue, with the second cleavage giving four blastomeres, and eight blastomeres after the third cleavage.

Around day three following fertilization, we have a mulberry-shaped 16-celled mass known as a morula. At day four to five after fertilization, the embryo now has around 100 cells. It has a single layer of large and flat cells originating from its outer cell mass, which will later give rise to the placenta. There is also another part called embryoblast made up of 10 to 30 pluripotent cells, which originate from the inner cell mass. Later on, the embryoblast becomes the fetus.