Embryology- General and Cardio

Question 1

Ectoderm Derivatives

Answer 1

Can be divided into
- Surface ectoderm (MOO DEAD PEEL)

• Neural ectoderm (COARNEE)
• Neural crest cells (PASS DR PAM the two-Faced PESO)

Question 2

Neural crest cell derivatives

Answer 2

Pia mater, Peripheral nervous system neurons
Arachnoid mater
Schwann cells
Sympathetic chain (autonomic postganglionic neurons)

Dorsal Root ganglia
Pigment cells (melanocytes)
Adrenal Medulla chromaffin cells (vs. adrenal cortex, which is derived from mesoderm)

Facial and skull bones
Facial cartilage

Parafollicular C cells
Endocardial cushions of the heart
Spiral septum (aorticopulmonary septum)
Odontoblasts (creates dentin)

Question 3

Endoderm Derivatives

Answer 3

HIT EMU, BURPS

Hepatocytes
Inferior 2/3 of vagina
Thymus and Thyroid

Entire gastrointestinal lumen (oral cavity through superior pectinate line)
Middle ear cavity and eustachian canal
Urethra (except distal male urethra derived from ectoderm), Urinary bladder

Bulbourethral glands (Cowper's)
Urethral glands (Littre's)
Respiratory tract
Parathyroid and Pancreas
Sublingual and submandibular glands

Question 4

Lateral plate mesoderm derivatives

Answer 4

• Parietal serous lining of body cavities (somatic portion of lateral plate mesoderm aka Somatopleure)
• Cardiovascular system (splanchnic portion of lateral plate mesoderm aka Splanchnopleure)
• Limb buds development
• Visceral serosal linings of organs
• Dorsal mesentery (ultimately the spleen)

Question 5

Notochord derivatives

Answer 5

Nucleus pulposus of the intervertebral discs

Question 6

Paraxial mesoderm

Derivatives

Answer 6

Sclerotome, forming the cartilage and bone of the axial skeleton (including the vertebral column, sternum, and ribs)
Myotome, forming the skeletal muscles
Dermatome, forming the dermis of the dorsal skin

Question 7

Intermediate mesoderm

Derivatives

Answer 7

Kidneys
Adrenal cortices
Superior ureters
Superior one third of the vagina
Uterus and cervix
Testes
Ovaries

Question 8

Hypaxial Mesoderm

Derivatives

Answer 8

Differentiates into Ribs, Intercostal muscles, Oblique muscles (thoracoabdominal walls)
Limbs
(part of paraxial mesoderm)

Question 9

Surface Ectoderm

Derivatives

Answer 9

MOO DEAD PEEL

Mammary Glands
Oral Cavity
Olfactory Epithelium

Distal anal canal below the pectinate line
Enamel (ameloblasts are derived from surface ectoderm)
Adenohypophysis (via Rathke pouch)
Distal male urethra

Parotid salivary glands
Epidermis and accessory structures (e.g. hair, nails, sweat glands, sebaceous glands)
Ear; both the internal and external ear (not middle ear)
Lens of the eye

Question 10

Neural Ectoderm

Derivatives

Answer 10

COARNEE

CNS neurons within the brain and spinal cord
Oligodendrocytes
Astrocytes
Retina, iris, and optic nerve
Neurohypophysis (aka the posterior pituitary)
Epithalamus (aka the pineal gland)
Ependymal cells

Question 11

When does Meiosis arrest in females, and when does it restart?
When does it end?

Answer 11

• Meiosis arrests in Prophase I at 5 months in utero
• Meiosis restarts during ovulation
• Fertilization completes meiosis

Question 12

What is an ectopic pregnancy?

Answer 12

• A fertilized ovum fails to enter the oviduct from the ovary
• Instead lands on (any) abdominal surface

Fertilized ovum can also stay in ovary instead of going to uterus

Question 13

What secretes hormones for ovum to promote/maintain pregnancy?

Answer 13

1. Corpus luteum- secretes PROGESTERONE until ~10 days in
   - If egg is not fertilized by then, it stops and degenerates into Corpus albicans (fibrous scar tissue)
2. Trophoblasts- secrete chemical messages to avoid autoimmune rejection by mother
3. Synctiotrophoblasts secrete hCG ~9 days post-fertilization
   - Signal to Corpus luteum to keep secreting PROGESTERONE (now called corpus luteum graviditatis)
   NOTE: Secretion of prostaglandins at this point will result in abortion of fetus
4. Eventually, in humans, placenta will take over PROGESTERONE production

Question 14

What are the parts of the bilaminar disc embryo?

Answer 14

• Amnion (above epiblast cells)
• Epiblast layer (top)
• Hypoblast layer (bottom)
• Yolk sac (underneath hypoblast)
• Everything is enclosed by chorionic cavity (derived from original trophoblasts)
  
  • Smooth chorion
  • Villous chorion (forms placenta)

[Note, Villi consist of: cytotrophoblasts (surround epiblasts/hypoblasts), then surrounding that are Syncytiotrophoblasts]

Question 15

What germ layer forms the vasculature?

Answer 15

Lateral plate mesoderm

Question 16

What germ layer forms the original kidneys of the body?

Answer 16

Intermediate mesoderm

Question 17

What are the four primary body cavity membranes?

Answer 17

• Pleural membranes (one for each lung)
• Pericardial membrane (surrounds heart)
• Peritoneal membrane (surrounds stomach/intestine/liver, other abdominal cavity organs)

Question 18

What forms the periosteal membranes

Answer 18

Lateral plate mesoderm

Question 19

What germ layer makes the smooth muscles?

Answer 19

Lateral plate mesoderm

Question 20

What do the sclerotomes eventually become?

Answer 20

Vertebrae (they resegment, then differentiate)

Question 21

What does the dermatome become?

Answer 21

Dermis of the skin, overlying muscles

Question 22

What does the myotome become?

Answer 22

Skeletal Muscles

Question 23

What does the hypaxial mesoderm form?

Answer 23

• Ribs
• intercostal muscles
• oblique muscles of abdominal wall
• limbs (upper limb externally rotates, lower limb medially rotates)

Question 24

Where are the four major celomic cavities?

Answer 24

Celom= space b/w parietal and visceral layers

• One for each lung
• One for the heart
• One for entire abdomen

Question 25

What is the stromadeum?

Answer 25

Region that eventually forms the oral cavity (ectoderm lined with endoderm)
- Buccopharyngeal membrane covers opening to the oral cavity

Question 26

What is the proctodeum?

Answer 26

Region that forms the cloaca (ectoderm line with endoderm)

- Eventually forms anus, vagina, urethra

Question 27

What is the function of the vitelline duct?

Answer 27

Forms connection between yolk sac and the gut, nutritious yolk fluid can enter developing GI tract

Question 28

What is the function of the vitelline veins?

Answer 28

Bring oxygenated blood produced by surface of the yolk sac to the forming liver/heart

Question 29

What do the diverticula that bud of the primitive GI tract become?

Answer 29

• Liver
• Gall bladder
• Dorsal/ventral pancreas
• Caecum and appendix

Question 30

What is the function of the vitelline arteries?

Answer 30

Return fetal blood to yolk sac

- Branch off embryonic aorta

Question 31

What do the vitelline arteries become in the adult?

Answer 31

• Celiac artery
• Superior mesenteric artery
• Inferior mesenteric artery

Question 32

What does the vitelline vein become in the adult?

Answer 32

The portal vein

Question 33

What are the parts of a blastocyst?

Answer 33

• Inner cell mass/embryoblast (differentiate into primordial germ cells and somatic cells)
  
  • > Below inner cell mass is blastocyst cavity
• Trophoblasts surround the inner cell mass = becomes nourishment structure for embryo
• Syncitotrophoblasts eventually become the placenta

Question 34

What are the phases of fertilization?

Answer 34

Phase 1: penetration of the corona radiata

Phase 2: penetration of the zona pellucida

Phase 3: fusion of the oocyte and sperm cell membranes

Question 35

Where does implantation of the blastocyst commonly occur?

Answer 35

The upper part of the uterus

Question 36

What are the parts of an ovum undergoing ovulation/waiting to be fertilized?

Answer 36

• Ovum
• Zona pellucida surrounds ovum
• Cumulus oöphorous surrounds the whole thing, supporting cells are called “follicular”

Question 37

What happens immediately after fertilization?

Answer 37

• Fertilized ovum divides to form 2- cell stage (~30 hrs post fertilization)
• Then 4-cell stage
• Then 16-cell morula (~3-4 days post fertilization)
  Blastocyst forms shortly after (~4th day post fertilization, when morula begins to enter uterus)

Question 38

1. When does bilaminar disc form?

2. When does trilaminar disc form?

Answer 38

1. During the second week (Day ~8)

2. During the third week (starting Day ~15-16)

Question 39

How does trilaminar disc form?

Answer 39

1. Cells of the epiblast (of the bilaminar disc) begin to migrate inwards
2. Cells form a “crack and a pit”- the primitive streak and the primitive node
3. Epiblasts eat at the hypoblasts and take their place
4. Notochord forms
5. Mesoderm and Endoderm form
6. Epiblasts differentiate to form Ectoderm

Question 40

How does nerulation occur?

Answer 40

• Once notochord forms, it signals formation of neural tube
• Center of ectoderm folds up forming two ridges (neurula formation)
• Neural plate closes over ridge (neural plate is parts of the ectoderm overlying neurula/groove)
• Before left and right ridges close completely, a population of cells dispatch from the edge –> neural crest cells
• Neural tube forms – becomes brain/spinal cord

Question 41

What is derived from the bulbus cordis?

Answer 41

• MAINLY: Aortic arch and the pulmonary trunk (along with truncus arteriosus)
• Aortic vestibule of left ventricle
• Conus arteriosus of right ventricle

Question 42

What forms the aortic arch and pulmonary trunk?

Answer 42

• Truncus arteriosus (top part) and bulbus cordis (bottom part)

Question 43

Sinous venosus derivatives

Answer 43

• Coronary sinus (left horn of sinus venosus)

- Smooth wall of right atrium

Question 44

What structure later becomes the coronary sinus?

Answer 44

Left horn of the sinus venosus

Question 45

What induces separation of truncus arteriosus into the aorta and pulmonary trunk?

Answer 45

Neural crest cells

Question 46

What are septa?

What are ostea?

Answer 46

Septa are walls formed to separate chambers and vessels of the heart

Ostea are openings in the walls

Question 47

How does foramen ovale form?

Answer 47

• Endocardial cushion migrates up to meet septum secondum and septum primum
  - Foramen primum exists between endocardial cushion and septum primum
• Septum primum and endocardial cushion meet, foramen primum closes
• Septum secundum migrates towards endocardial cushion as it migrates up, BUT they do not meet (foramen ovale forms)
• Cell apoptosis occurs in fused wall of septum primum and the endocardial cushion, resulting in foramen secundum
• This is how blood can flow from right atrium to left atrium during fetal circulation

Question 48

What specific structure often malfunctions in children with Down Syndrome?

Answer 48

Endocardial cushions, which also forms valves

Question 49

How do atrial-ventricular septums form?

Answer 49

Endocardial cushion grows laterally to form wall

Question 50

How do interventricular septums form?

Answer 50

• Endocardial cushion and membranous portion of interventricular septum migrates down
• Muscular portion of interventricular septum migrates up
• Aorticopulmonary septum is not yet spiraled

Question 51

How do aorta and pulmonary trunk form?

Answer 51

• Both arise from bulbus cordis and truncus arteriosus
• The separate halves of truncus arteriosus/bulbus cordis twist and separate
• Neural crest cells facilitate separation

Question 52

Types of ventricular septal defects? h

How do they arise?

Answer 52

1. Membranous (Most common, usually must be fixed with surgery)
   - -> Defect in endocardial cushion growth, does not expand all the way
2. Muscular portion (likely to spontaneously fuse, surgery not usually necessary)
   - -> Defect in ingrowth of muscular ventricular wall

Question 53

What is the transposition of great vessels?

Answer 53

• Truncus arteriosus fails to spiral
• Usually due to malfunction with neural crest cells (and their messaging)
• Aorta is located above right ventricle, pulmonary trunk is located above left ventricle

-Need cardioprotective shunts to survive past utero

Question 54

What is Persistent truncus arteriosus?

Answer 54

-Truncus arteriosus does not split properly,
so ascending aorta and pulmonary trunk are not separated
-Also occurs with VSD, so blood from both sides of heart flow through both systemic and pulmonary circulation
- There is no membranous ventricular septum, only muscular portion

• Results in CYANOSIS
• Can coexist with other neural crest migration defects!

Question 55

What happens to the heart around day ~23?

Answer 55

Heart begins to rotate and twirl iteself upward –> “cardiac loop”
- Four chambers are in place

Question 56

How does heart form?

Answer 56

• Smooth muscle cells differentiate, migrate from capillary bed near the pharynx
• They join together to form a tube, which later becomes the heart

Question 57

How does the liver form?

Answer 57

• Cells from the gut differentiate into liver cells
• They migrate down underneath the heart to form the liver
• Heart and liver are connected by vitelline vein (later becomes the portal vein)

Note that the liver is formed also formed from diverticula of the gut (like most gut organs)

Question 58

What structures form from the septum transversum?

Answer 58

• Diaphragm
• Endocardial cushions
• Fibrous pericardium (cytoskeleton of heart)
• Valves of the heart

Children with down syndrome often have defects with septum transversum (issues with valves)

Question 59

What structures are within the umbilical cord?

Answer 59

• Vitelline duct
• Vitelline arteries
• Vitelline veins
• Umbilical arteries
• Umbilical veins
• STEM CELLS

Question 60

What is a remnant of the vitelline duct?

Answer 60

Meckel’s diverticulum (appendage from intestines)

Question 61

How does placental circulation work?

Answer 61

• Oxygen rich blood is delivered to fetus via umbilical vein
• Oxygen poor blood is returned to the placenta/mom via umbilical artery
• Chorionic villi (mainstem, then branch) take up nutrients in space between endometrium and amniochorionic membrane
• Endometrial arteries and veins allow for circulation in placenta

Question 62

What do these structures in the embryo become in the adult?

1. Ductus arteriosus
2. Foramen ovale
3. Ductus venosus

Answer 62

1. Ligamentum arteriosum
2. Fossa ovalis
3. Ligamentum venosum