circulation 5 Flashcards
blood vessel function
venous system: collect and store blood
arterial system: distribution and store blood
arterioles: flow and pressure control
importance of arterioles and poiseuille’s law:
vascular resistance=vessel length/radius^4
-bp decreases from ventricle to arteries, then decreases very rapidly at arterioles so blood flow does not damage capillaries and can exchange properly with tissues
arteriolar vascular smooth muscle (VSM) and blood flow at capillaries
- VSM controls vascular resistance through vasoconstriction/relaxation
- allow blood flow to be prioritized according to tissues that need it, ie. digestion vs exercise
- also because not all capillary beds can be fully perfused with each heartbeat, and cardiac output is finite, so there will always be vascular resistance at some points
2 vascular control mechanisms
- central control via ANS
2. local control (myogenic, paracrine, autocrine, or gasomitter)
central control via ans
-nerual and hormonal, ie. sympathetic nerves, alpha adrenergic vasocontrictions, and beta-adrenergic vasorelaxations
local control
myogenic: originate in the muscle, stretch of arterial wall=-ve feedback
paracrine: cell-cell stimulation, endothelin, histamine
autocrine: same-cell stimulation, ie metabolit like adp or H+
gasomitterL NO, CO, H2S
local control of arteriolar vr
-controlled by metobolic need (ie hypoxia), which alters vascular tone:
decreased o2 and increased waste causes arteriolar smooth muscle to vasodilate, decreasing resistance, increasing blood flow, and increasing o2 delivery, co2 and waste removal
-this is a negative feedback loop
vasoconstriction causing substances
stretch of arteriolar wall, endothelin, serotonin, vasopressin, norepinephrine
vasodilation causing substances
hypoxia, increased co2, H+, K+, nitric hoxide, epinephrine, ACh
regulating central arterial bp/mean arterial blood pressure (map)
MAP=Q*TPR
- controlled by ANS
- decreased sympathetic output=DECREASED NOREPIN RELEASE CAUSES vasodilation, decreased ventricle contraction, and slowing sa node rate
- vasodilation decreases peripheral resistance TPR, and decrease contractions and heart rate decreases output Q
blood pressure sensing system to regulate high map
-sensors: arterial baroreceptors/stretch receptors increase discharge to medulla in proportion to bp
-control centre, medulla: processes input and adjusts arteriolar tone
-effector system: symp/parasym innervation of heart and vessels (symp=less adrenal release)
MAP(or BP)=QTPR (cardiac outputtotal peripheral resistance)
human bp vs fish
human bp much higher than fish because terrestrial
guiding principles
- hearts generate bp
- pressure gradients needed for blood flow
- valves regulate direction
- bp lost primarily at arterioles and control distribution to capillary beds
- all caps cannot be fully perfused, priorities go to the tissues most needing
- central/mean arterial bp is regulated
