Histology - Vasculature

Question 1

Medium size, continuous basal lamina, have small openings through plasma membrane that may or may not be closed by a diaphragm. Found in endocrine organs, GI tract, and kidney.

Answer 1

Fenestrated (type II) Capillaries

Question 2

Most external layer composed of fibroelastic connective tissue that is continuous with and blends into CT. Contains ANS postganglionic nerve fibers that innervate the smooth muscle cells in the TM and vasa vasorum for nutrients.

Answer 2

tunica adventitia (TA)

Question 3

Initially left and right associated with arch 6, but when arch 6 is lost from the right side, it ‘slides’ up to arch 4, while arch 6 remains in place (ductus arterosus).

Answer 3

Recurrent laryngeal nerve fetal development

Question 4

Secreted by endoderm & visceral mesoderm, upregulates expression of FGF8 gene

Answer 4

BMP 2, 4

Question 4

Directly controls amount of blood flow through capillary beds

Answer 4

Precapillary sphincter

Question 5

a small ligament attached to the superior surface of the left pulmonary artery and the proximal descending aorta. a nonfunctional vestige of the ductus arteriosus, and is formed within three weeks of birth.

Answer 5

ligamentum arteriosum

Question 5

L ventricle to left atrium -> foramen ovale to right atrium -> to right ventricle to pulmonary trunk -> DUCTUS ARTERIOSUS

Answer 5

Compensatory blood flow (prenatal) in preductal constriction of the aorta

Question 6

right sinus horn

Answer 6

upper part of the IVC fetal derivative

Question 6

6-8 microns in diameter (smallest), found in tightest tight junctions, prominent pinocytotic vesicles. Continuous and complete basal lamina, found everywhere.

Answer 6

Continuous (type I) capillary

Question 7

Tunica media: 5-40 layers smooth muscle arranged in a spiral fashion. Prominent IEL & EEL.

Answer 7

Muscular (distributing) arteries

Question 8

(1) SVC (2) upper part of the IVC (3) incorporated into the right atrium (smooth part)

Answer 8

Right sinus horn becomes

Question 9

Subclavian aa -> Internal thoracic arteries -> Anterior intercostal -> arteries -> Posterior intercostal arteries -> Thoracic aorta (to lower body & Les)

Answer 9

Postductal coarctation of the Aorta collateral circulation

Question 10

Partitioning of the heart into 4 chambers begins.

Answer 10

Week 5 Heart Development

Question 10

a collection of veins joined together to form a large vessel that collects blood from the heart muscle

Answer 10

coronary sinus

Question 11

1. Enlargement of collateral arteries. 2. X-ray: Notching of ribs (on posterior 1/3). 3. Despite compensation, blood pressure in UEs much higher than in LEs

Answer 11

Postductal coarctation of the Aorta presentation

Question 12

Thin tunica intima & adventita. Tunica media made of 1-4 layers smooth muscle. May have IEL but no EEL. They control blood flow into capillary beds by increasing or decreasing lumen diameter (thereby or vascular resistance to blood flow). They are the principal control of systemic blood pressure

Answer 12

Arterioles

Question 14

Aortic arches undergo primary changes to adult form.

Answer 14

Week 6 Heart Development

Question 15

common cardinal vein, Umbilical vein, Vitelline vein

Answer 15

intial sinus horn inflow

Question 16

Endothelium: Weibel-Palade bodies, Subendothelial connective tissue (CT) layer, Internal elastic lamina (IEL, where applicable)

Answer 16

Tunica intima

Question 17

Wedge-shaped portion of aortic arch, Ductus arteriosus (ligamentum arteriosum)

Answer 17

Aortic arches become…

Question 17

Each arch develops its own artery, nerve that controls a distinct muscle group, and skeletal tissue. The arches are numbed from 1 to 6, with 1 being the closest to the head of the embryo, and 5 existing only transiently. They develop during the fourth week crainal to caudal on both sides of the developing pharynx.

Answer 17

Aortic and associated pharyngeal arches

Question 17

1. Endothelial cell regrowth (from uninjured areas) 2. Smooth muscle cell migration into the tunica intima. 3. Smooth muscle cell proliferation. 4. Smooth muscle cell secretion of ECM.

Answer 17

Vascular injury associated with endothelial cells loss or dysfunction results in…

Question 18

a depression in the right atrium of the heart, the remnant of a thin fibrous sheet that covered the foramen ovale during fetal development.

Answer 18

fossa ovalis

Question 19

Smooth muscle layers: Fenestrated elastic sheets/laminae (elastic arteries), External elastic lamina (EEL, where applicable)

Answer 19

Tunica media

Question 19

contractile cell located within endothelial basal lamina that communicate with endothelial cell via gap junctions that are ctivated with injury & during wound healing. They are mesenchymal –type cells tha can act as stem cell and give rise to: endothelial cells & smooth muscle cells during angiogenesis.

Answer 19

Pericytes (Rouget cells)

Question 19

Relatively wide, irregular lumen, thinner walls, valves and no internal elastic lamina.

Answer 19

Medium vein (MV)

Question 19

Arranged in networks. Consist of endothelial cells, basal lamina, and pericytes.

Answer 19

Capillaries

Question 21

Blood flow into the right atrium from the IVC to the left atrium, bypassing pulmonary circulation.

Answer 21

Foramen ovale

Question 22

are the nerves of the sixth pharyngeal arch, right and left that emerge from the vagus nerve at the level of the arch of aorta, and then travel up the side of the trachea to the larynx.

Answer 22

Recurrent laryngeal nerve

Question 22

Constriction distal to ductus ateriosus. Separation of arterial circulation of Head/Upper trunk/UE from that of the Lower trunk/LEs that cannot be compensated for by the ductus arteriosus. Before birth have to develop extensive collateral circulation to bypass the narrowed aortic region and supply the lower trunk/LEs.

Answer 22

Postductal coarctation of the aorta

Question 22

Continuous (type I), Fenestrated (type II), Sinusoidal (or discontinuous)

Answer 22

types of capillaries

Question 24

Modified cardiac muscle fibers, located in subendoCARDial, (not epithelial). Large pale-looking (“moth-eaten) cells.

Answer 24

Purkinje Fibers

Question 25

Function: Regulation of regional blood flow (distribution). Examples: Axillary artery, Internal thoracic artery, Intercostal arteries

Answer 25

Muscular (distributing) arteries examples and functions

Question 26

Relatively small, regularly shaped lumen, thick walls with internal elastic lamina

Answer 26

Muscular artery (MA)

Question 27

The lungs are not oxygenating fetal blood. They need just enough blood to sustain.

Answer 27

Pulmonary bypass

Question 29

Master gene required for the formation and development of the primary heart field

Answer 29

NKX-2.5

Question 30

Tunica intima

Answer 30

Site of Atherosclerotic Plaque Formation

Question 32

Blood to/from fetus to/from yolk sac

Answer 32

Vitelline arteries and arteries

Question 34

sprouting of new vessels from existing vessels

Answer 34

Angiogenesis

Question 35

Large irregular lumen. Discontinuous basal lamina. Found in Bone marrow, liver, spleen (sites of fluid & cell migration in & out of BV).

Answer 35

Sinusoidal (discontinuous) capillary

Question 36

NKX-2.5 expression in visceral mesoderm (PHF)

Answer 36

BMPs + C & C cause

Question 37

Venous blood from fetus back to heart

Answer 37

Cardinal veins

Question 38

1. Cardiac myoblasts 2. Angioblasts

Answer 38

PHF cells induced to form

Question 40

(initially 2-fuse to form 1), Blood from heart to body, YS, Placenta

Answer 40

Dorsal aorta

Question 41

Secreted by neural tube, inhibitory to cardiogenesis.

Answer 41

WNT proteins

Question 42

the fibrous remnant of the ductus venosus of the fetal circulation. Usually, it is attached to the left branch of the portal vein within the porta hepatis (gateway to the liver).

Answer 42

ligamentum venosum

Question 44

Structures remain open or partially open past the normal range of closure times

Answer 44

Fetal Patency

Question 45

Functions: 1. Expand during systole & recoil during diastole 2. Propel blood along blood vessel system. Examples: Pulmonary trunk, Aorta (all parts), Brachiocephalic trunk, Common carotid arteries, Subclavian arteries

Answer 45

Elastic (conducting) arteries functions and examples

Question 47

Ductus Venous. Oxygenated blood in the umbilical vein does not need to be filtered by the fetal liver (placenta has done that job)

Answer 47

Liver bypass

Question 48

a blood vessel connecting the pulmonary artery to the proximal descending aorta, allowing most of the blood from the right ventricle to bypass the fetal lungs.

Answer 48

Ductus Arteriosus

Question 49

Important in expression of cardiac specific proteins.

Answer 49

FGF8 gene

Question 50

Heart and embryonic blood vessels begin to develop. Embryonic circulation established. Heart begins to beat. Cardiac lopping completed.

Answer 50

Weeks 3 + 4 Heart Development

Question 52

Umbilical vein (Placenta, Ox), Vitelline veins (YS, de-Ox), Cardinal veins (Body, de-Ox)

Answer 52

Fetal inflow to heart

Question 53

Aortic arches: Head & Neck, Dorsal aorta: Body; YS: Vitelline a; Placenta: Umbilical aa

Answer 53

Outflow from heart

Question 54

coronary sinus

Answer 54

Left sinus horn becomes

Question 55

Bypasses liver directly to the Inferior Vena Cava (IVC)

Answer 55

Ductus venosus

Question 56

Lateral Plate Mesoderm - Visceral Layer

Answer 56

Heart Embryonic Germ Layer

Question 58

a “horseshoe-shaped” cluster of cells cranial (& lateral) to the neural folds developed early in week 3.

Answer 58

Primary heart field (PHF)

Question 59

Specializations of the Endocardium (Tunica Intima). Extensions of fibroelastic tissue deep to endothelium. Covered on luminal surfaces by endothelium

Answer 59

Cardiac Valves

Question 60

Formation of heart valves is completed.

Answer 60

Week 8

Question 61

Functions: Transport blood to large veins (may have valves) Examples: Axillary vein, Internal thoracic veins, Intercostal veins, Cardiac veins (heart)

Answer 61

Medium veins examples and functions

Question 62

At birth: 1. Head, upper trunk & UEs have normal color 2. Lower trunk & LEs are cyanotic (blue).

Answer 62

Preductal coarctation of the aorta presentation

Question 63

First venules after the capillary bed, consisting of endothelial lining, basal lamina , pericytes (stem cells). Site of fluid movement and leukocyte extravasation.

Answer 63

Postcapillary Venules

Question 64

Secreted by endoderm, blocks WNT

Answer 64

crescent & cerberus

Question 65

Organs of the body, Connective tissues, Smooth & cardiac muscle, Circulatory system (blood & lymphatic vessels)

Answer 65

Visceral (splanchnic) mesoderm derivatives

Question 66

a vein running up the right side of the thoracic vertebral column. It can also provide an alternative path for blood to the right atriumby allowing the blood to flow between the venae cavae when one vena cava is blocked.

Answer 66

Azygos vein

Question 67

platelet adhesion at an injury site, secreted directly into the underlying subendothelial CT layer or stored within the endothelial cell cytoplasm in electron dense secretory vesicles.

Answer 67

Willebrand factor (vWF)

Question 68

Prostaglandin E2 administration to keep ductus open until repair can be done.

Answer 68

Treatment for constriction of the aorta

Question 69

Constriction just proximal to ductus ateriosus, blood flow to head/neck & UEs is OK, but blood to lower body affected. Is compensated for via an alternative pathway through ductus arteriosus.

Answer 69

Preductal constriction of the aorta

Question 70

Endothelium: General Functions

Answer 70

Barrier, Exchange Functions:

Paracellular and Transcellular Transport - Tight junctions, Basal lamina, Gap junctions (exchange between endothelial cells)

Synthetic & Secretory (affects):

1. Blood coagulation & thrombus (clot) formation
2. Inflammatory reactions - Fluid movement into tissues, WBC migration into tissues
3. Angiogenesis