Phase 3 - Week 2 (Blood vessels, Blood Pressure, Postural Hypotension) Flashcards
List the types of blood vessels
- Arteries
- Arterioles
- Capillaries
- Venules
- Veins
List the layers of all blood vessels
From outside -> lumen
- Tunica adventitia
- Tunica media
- Tunica intima
Describe the structure of the tunica adventitia
- Outer layer
- Loose, thick layer of connective tissue
- Consists of elastic + collagen fibres
- Network of tiny nerves, lymphatics + capillaries that supply the vessel wall
What is the function of the tunica adventitia?
- Anchors vessel wall to surrounding structure
- Gives some protection
Tunica media
- Middle, muscular + connective tissue layer
- Consists mainly of muscle cells + elastic fibres
- External elastic lamina - helps artery recoil after it has stretched due to increase in BP during each heartbeat
- Smooth muscle - arranged concentrically around lumen, adjust vessel diameter through contraction (vasoconstriction) and relaxation (vasodilation), regulates blood pressure + blood flow
Tunica Intima
- Innermost epithelial lining, forms perimeter of lumen
- 4 components - internal elastic lamina, lamina propria, basement membrane, endothelium
- Composition of layers depends on vessel size and position in circulatory system
Internal elastic lamina of BVs
Thin sheet of elastic fibres to help vessel recoil after it has been stretched by increased BP. Contains window-like openings that facilitate diffusion between tunica intima and tunica media
Lamina propria of BVs
Outer layer of elastic connective tissue that contains capillaries
Basement membrane of BVs
Framework of collagen fibres deep to endothelium. High tensile strength provides firm supportive base + anchorage for the endothelial lining to lamina propria, while retaining elasticity enough to ensure vessel’s ability to stretch + recoil. Regulates molecular movement, important role in tissue repair of BV walls.
Endothelium of BVs
Layer of simple squamous epithelial cells in direct contact with blood. Permeable to certain materials, regulates diffusion of substances, prevents cells sticking to its walls, contracts to prevent blood flow.
Describe the function of arteries
- Carry oxygenated blood away from heart to organs
- Blood is under high pressure so have strong, muscular walls to cope with surge of blood
List the types of arteries
- Elastic arteries
- Muscular arteries
- Arterioles
Elastic arteries
Aka conducting arteries - conduct blood from heart into muscular arteries
Describe the general structure of arteries
- Have all three layers of a typical BV
- Tunica media exhibits greater muscular + elastic thickness than veins, enabling walls to stretch easily with small increase in BP
Describe the structure of elastic arteries
- Well defined internal + external elastic laminae
- Tunica media is thick and full of elastic fibres, enabling walls to stretch easily with increase in BP, as seen during systole
Give examples of elastic arteries
- Aorta
- Subclavian
- Common iliac
- Common carotid
Describe the function of elastic arteries
- Propel blood from heart during ventricular diastole
- Elastic properties are essential to accommodate the volume of blood created when blood is expelled from the heart
- Elastic fibres convert mechanical -> kinetic energy as they recoil, force blood away from the heart
Muscular arteries
- Aka distributing arteries, repeatedly branch until reaching target organs
- Less elastic than conducting arteries, don’t have to deal with the same degree of pressure changes
Describe the structure of muscular arteries
- Well-defined internal but thin external elastic laminae
- Thick tunica media, concentrically arranged layers smooth muscle cells
- Tunica adventitia often thicker than tunica media - longitudinally oriented fibroblasts, collagen fibres + elastic fibres. Loose arrangement of cells enables arteries to alter diameter
Give examples of muscular arteries
- Renal
- Splenic
- Internal carotid
- Femoral
- Popliteal
- Axillary
- Radial
- Ulnar
- Smaller brachial arteries
Describe the function of muscular arteries
- Lack of elastic fibres in walls means that recoil doesn’t propel blood
- Maintain a state of partial contraction or vascular tone - ensuring that vessel pressure and efficient blood flow are sustained + enable efficient adjustment of rate of blood flow by vasoconstriction + vasodilation
Arterioles
- Aka resistance vessels
- Numerous, microscopic arteries that feed blood into capillary networks
Describe the structure of arterioles
- Tunica intima is thin with fenestrated (porous) internal elastic lamina that diminishes as the arteriole tapers towards its terminal end and continues as a capillary - region referred to as the metarteriole
- Muscular tunica media made of 1-2 concentrically arranged layers of smooth muscle cells
- Smooth muscle cell forming the precapillary sphincter demarcates, controls flow of blood between metarteriole and its adjoining capillary
- Tunica adventitia contains unmyelinated sympathetic nerves + loose connective tissue
Describe the function of arterioles
Local chemical mediators and sympathetic nerve supply of arteriole triggers vasoconstriction + vasodilation, regulating rate of blood flow, BP and vascular resistance
Capillaries
- Short, branched, interconnecting vessels that form networks in every structure of the body
- Bridge gap between arterioles and venules
- Microcirculation - blood flows from a metarteriole, through capillaries into a post-capillary venule
- Lack tunica media and tunica adventitia
- Thin, one-layer epithelial structure and huge surface area allows rapid exchange of small molecules e.g. glucose, and diffusion of gases e.g. oxygen/carbon dioxide between blood and cellular interstitial fluid
- Aka exchange vessels
What is the function of capillaries?
Provide large surface area in contact with tissues throughout the body for exchange of nutrients/waste products
Describe the function of veins
Carry blood back to the heart from extremities and organs of the body. More numerous than arteries, often appear as pairs.
Describe the structure of veins
- Generally have very thin walls in relation to their diameter, with large lumen
- Form vascular/venous sinuses in certain regions - widened areas which are structurally different to regular veins
- Thin endothelial walls, with complete lack of smooth muscle - reliant on surrounding connective tissue for support
Where are veins located?
- Superficial veins spread throughout subcutaneous layer, deep to skin and deep veins run between skeletal muscles
- Connections between deep and superficial called anastomotic veins
Venules
- Like arterioles - numerous + microscopic, walls are much thinner
- Post-capillary venules are continuous with capillary networks - small diameter, gaps between endothelial cells in walls
- As venules continue further from capillary diameter increases, become more muscular with more layers of concentrically arranged smooth muscle cells
- Function = drain blood from capillary networks and feed the return flow of blood to the veins. Post-capillary venules function as an exchange unit, larger thicker walled venules don’t
Medium veins
- Have all 3 layers of typical BV - tunica adventitia is thickest layer, consisting of collagen and elastic fibres, tunica media, thin and lacking in smooth muscle, elastic fibres and tunica intima
- Do not have internal or elastic laminae, not able to withstand high pressure
- BP in veins is relatively low, rely on contraction of surrounding skeletal muscle and pumping action of heart to boost venous return
- Many contain valves, small extensions/infoldings of tunica intima into the lumen, creating flap-like cusps
Give examples of medium veins
- Renal
- Internal carotid
- Ulnar
- Splenic
- Popliteal
Describe the structure of large veins
Thick tunica adventitia, similar to that of medium veins, but lack valves
Give examples of large veins
- Superior vena cava
- Internal jugular veins
- Common iliac veins
Describe the function of large veins
Drain from their tributaries into the heart
List the types of capillaries
- Continuous capillaries
- Fenestrated capillaries
- Sinusoids
Continuous capillaries
- Majority of capillaries
- E.g. in brain, lungs, smooth muscle, skeletal muscle and connective tissue
- Walls made of continuous layer of endothelial cels with small gaps between (intercellular clefts)
- Have a complete outer basement membrane
Fenestrated capillaries
- In kidneys, villi of small intestine, choroid plexus of brain and endocrine glands
- Walls are fenestrated (porous) - plasma membranes of endothelial cells in walls covered in small holes (fenestrations)
- Have a complete outer basement membrane
Sinusoids
- In bone marrow, liver, spleen, anterior pituitary gland, parathyroid gland and lymph nodes
- Wide and meandering, large fenestrations in endothelium
- Have large intercellular clefts + incomplete outer basement membrane
- Allow larger structures e.g. complex proteins and blood cells to pass from tissue -> bloodstream
- Specialised lining cells extend across lumen - function differs depends on tissue e.g. in liver they are phagocytic, removing bacteria/foreign bodies from blood
Vasomotion
Process by which blood passes from arterioles -> capillaries or capillaries -> venules. Intermittent contraction and relaxation of pre-capillary sphincters that pushes blood from a metarteriole to a capillary. Controlled by chemicals released by endothelial cells.
How is blood hydrostatic pressure generated?
Pumping action of heart as ventricles contract, results in pressure exerted by blood on walls of vessels
List the physiological factors which effect blood pressure
- Cardiac output
- Blood volume
- Vascular resistance
When/where is blood pressure highest?
In the aorta during ventricular systole
When/where is blood pressure lowest?
During ventricular diastole in the right ventricle (reaches 0 mmHg)
Normal blood pressure
120/80 mmHg
