Term
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Definition
o Flow=pressure gradient/resistance
ΔP/R |
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Term
| What is the flow of a fluid governed by? |
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Definition
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Term
| What generates pressure difference in the flow equation? |
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Definition
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Term
| What has higher pressure? arteries or veins? |
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Definition
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Term
| What are the pressure gradients across the systemic and pulmonary circuits? |
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Definition
o Aortic mean arterial pressure = 90 mm Hg
o Central venous pressure in large returning veins = 2-8 mm Hg
o Pulmonary artery pressure = 15 mm Hg
o Pulmonary venous pressure = 0 |
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Term
| Why are the pressure gradients so different in pulmonary and systemic circuits? |
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Definition
o ΔP of pulmonary circuits is much lower than systemic circuit
o Flow in both circuits is same ~ 5 L/min
o How? Resistance has to be higher or lower to = 5 |
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Term
How is the flow rate equal in both the pulmonary and systemic circuits? |
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Definition
Resistance has to be higher or lower to = 5 |
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Term
Where is pressure drop the greatest as blood travels through the various types of vessels in the systemic and pulmonary circuits? |
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Definition
Pressure drops as blood travels through circuits – 14.3
i. Systemic circuit – starts at 90, ends at 0
ii. Pulmonary circuit – starts at 30, ends at 0
iii. Greatest pressure drop at arterioles |
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Term
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Definition
Resistance impedes blood flow |
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Term
| How does resistance change based on the properties of the vessel or blood itself? |
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Definition
i. Increased radius, decreased resistance
ii. Increased length, increased resistance
iii. Blood viscosity – increased concentration of cells/proteins, increased resistance |
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Term
What is total peripheral resistance? |
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Definition
Total peripheral resistance (TPR)
i. Combined resistance of all vessels in the systemic network
ii. Vasoconstriction – increased TPR
iii. Vasodilation – decreased TPR |
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Term
relationship between cardiac output, mean arterial pressure and total peripheral resistance. |
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Definition
a. Pressure gradients and resistance
i. Fact: flow = ΔP/R
ii. Flow is cardiac output (CO)
iii. ΔP=MAP
iv. Resistance = TPR
v. Therefore, CO=MAP/TPR |
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Term
What are common characteristics of all blood vessels? How does lumen size and thickness of smooth muscle vary between the different types of vessels? What is the order of vessels through which blood moves to and from the heart? |
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Definition
1. Lumen-hollow interior
2. Endothelium-lining, release and respond to chemical messengers
3. Smooth muscle-regulate vessel diameter
4. CT-vessel strength and elasticity |
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Term
| What does blood pressure detect? |
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Definition
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Term
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Definition
Brachial artery, close to and same height as heart |
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Term
| What exactly are systolic and diastolic blood pressures? |
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Definition
i. Systolic-highest pressure, ventricular contraction
ii. Diastolic-minimum pressure, ventricular relaxation |
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Term
| What is laminar and turbulent flow? |
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Definition
i. Laminar flow-free flow of blood through an artery
ii. Turbulent flow – blood cells hit side of wall, but can slowly flow through artery |
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Term
| How do you calculate pulse pressure? |
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Definition
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Term
| What does an elevated pulse pressure indicate? |
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Definition
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Term
| What is mean arterial pressure and how is it weighted? |
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Definition
Mean arterial pressure (MAP) is weighted mean, average pressure in arteries during one cardiac cycle:
MAP=[SP+(2 x DP)]/3 |
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Term
| What is the major function of arterioles? |
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Definition
a. Arterioles-major regulators of BP and direct blood flow
i. 60% of TPR attributable to arterioles
ii. Largest pressure drop
iii. Little elastic material, lots of SM |
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Term
| What properties do arterioles have that helps them perform their major function? |
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Definition
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Term
| What is arteriole diameter regulated by? |
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Definition
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Term
| Vessel smooth muscle is regulated by what intrinsic mechanisms? |
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Definition
i. Intrinsic mechanisms-local metabolites that regulated blood flow to match local needs
a. Intrinsic control
i. Blood flow between different organs and blood flow in regions of same organ
ii. Vasodilation-drop in 02, nutrients, rise in CO2, wastes
iii. vasodilation IRT increased metabolic activity
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Term
| Vessel smooth muscle is regulated by what extrinsic mechanisms? |
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Definition
i. Extrinsic-autonomic nervous system and hormones regulate MAP
a. extrinsic control by sympathetic innervations
i. NE-binfing to alpha1, receptors cause vasoconstriction
ii. Alpha1 receptors predominate in gut
iii. No parasympathetic innervations of most arteriolarism
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Term
| How do hormones affect smooth muscle? |
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Definition
i. Epinephrine-binding to B2 receptors à vasodilation…………………binding to alpha1 receptors àvasoconstriction
ii. Arteriolar SM of skeletal and cardiac has lots of B2
iii. Arteriolar SM of most other tissues (especially guts) has mostly alpha1 |
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Term
| How does ADH regulate blood pressure? |
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Definition
It acts on the kidneys
i. Antidiuretic hormone (ADH) – posterior pituitary limits urine output, increases blood volume
1. AKA vasopressinàvasoconstriction in most tissues (at very high doses)
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Term
| How does angiotensin II regulate blood pressure by acting on the kidneys? |
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Definition
i. Other plasma precursors converted to angiotensin II which promotes vasoconstriction Ang I à Ang II à increased BP
1. Increased ACE ang converting enzyme
2. ACE inhibitors-lower BP |
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Term
| How does exchange occur at capillary beds? |
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Definition
i. Walls are one cell thick
ii. O2, CO2, monosaccharides, amino acids, H20, need to cross only a short distance
iii. Body capillary surface area >600m2
iv. Easy access for all cells
v. Exists in networks (beds) |
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Term
| What are two types of capillaries? |
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Definition
a. Most capillaries are continuous
i. 14.17
ii. Continuous- relatively tight, proteins cannot leave lumen
iii. Fenestrated- porous, proteins and large species can leave lumen (kidneys and intestines) |
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Term
| Describe the pressure gradient that exists between capillary and surrounding tissue. |
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Definition
i. ΔP causes flow
ii. ΔP varies along length of capillary
iii. Fluid exchange between capillary and surrounding tissue |
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Term
| What are the 2 types of pressure that occur in capillaries? |
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Definition
i. Hydrostatic pressure (P)-fluid pressure
ii. Oncotic pressure (π) – osmotic pressure exerted by non-permeable proteins |
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Term
| What are the 4 types of pressures or "starling forces"? |
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Definition
i. Capillary hydrostatic pressure PCAP
ii. Capillary oncotic pressure πCAP
iii. Interstitual hydrostatic PIF
iv. Interstitual oncotic πIF |
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Term
| How do you calculate net filtration pressure? |
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Definition
Wet filtration pressure (NFP)=(PCAP+ πCAP) |
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Term
| What is the difference between filtration and absorption pressures? |
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Definition
i. Hydrostatic pressure is only thing that changes significance!
ii. Filtration occurs at arteriolar end, absorption at venule (14.20) |
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Term
Why is all filtered fluid not absorbed? Where does the remainder go to? What happens if the fluid is not returned back to the cardiovascular system? |
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Definition
a. Loss of fluid from CAP into IF is retrieved by lymphatic system
i. 3 L/day enters lymphatics, eventually returns to blood
ii. Lymph is clear with yellow tinge
iii. Failure of lymph-net accumulation of IF |
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Term
| What is the main function of veins? |
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Definition
a. Large veins are large diameter, thin walled
i. Highly compliant volume reservoir |
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Term
| What are the 2 types of veins and what is an important difference between them? |
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Definition
i. Central veins-in thoracic cavity
ii. Peripheral veins-outside thoracic cavity-equipped with one-way valves |
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Term
| In which vessels are majority of blood found at rest? During exercise? |
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Definition
Veins contain highest proportion of blood volume at rest |
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Term
| What are 4 ways to influence venous pressure and return? |
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Definition
- Skeletal muscle pump
- respiratory pump
- blood volume
- venomotor tone
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Term
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Definition
| Venous return is aided by skeletal muscle pump. |
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Term
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Definition
a. . Venous return is aided by respiratory pump
i. Inhalation expands rib cage, pulls diaphragm down
ii. Increases abdominal pressure, decreases thoracic pressure
iii. ΔP favors venous return
iv. Exhalation reverses ΔP, but valves in abdominal veins prevent backflow |
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Term
| Blood volume and venous return |
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Definition
a. Blood volume influences venous return
i. Increased blood volume=increased venous pressure and increased venous return
ii. Bleeding or dehydration=decreased venous return
iii. Failure to excrete H2O and salts leads to fluid accumulation, hypertension (high MAP) |
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Term
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Definition
i. Alpha receptors in SM of veins
ii. Contract in response to increased sympathetic output
iii. Increased venous pressure, increased venous return to heart |
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Term
1. How do baroreceptors regulate pressure via negative feedback mechanisms? |
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Definition
a. Baroreceptors are pressure sensors
i. Relay to control center in brainstem
ii. Increase stretch of vessel causes increased parasympathetic output to SA node, decreased sympathetic
iii. Decreased HR & SV àdecreased MAP
iv. Orthostatic hypotension |
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Term
What different dysfunctions lead to heart failure? |
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Definition
a. Heart failure is inability to maintain adequate CO
i. Weak myocardium (ie myocardial infarction)
ii. Reduced HR through conduction block
iii. Valve obstruction
iv. May affect 1 or both sides |
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Term
| What causes congestive heart failure? |
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Definition
a. Inadequate left ventricle activity leads to congestive heart failure
i. Failure to contract increases left atrial pressure
ii. Decrease in venous return from pulmonary circuit
Pulmonary congestion and edema- shortness of breath, fatigue, death |
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Term
| How is congestive heart failure treated? |
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Definition
a. Congestive heart failure treated with digitalis
i. Digitalis inhibits Na+/K+ ATPase
ii. Leads to accumulation of intracellular [Na+]i
iii. Increased [Na+]i leads to increased [Ca2+]i
iv. Increased [Ca2+]i gives stronger myocardium contraction |
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