Lecture 12: Control Of Blood Flow

Question 1

What are the two phases and characteristics of each for local blood flow control?

Answer 1

• Acute control:
• Rapid changes in local vasodilation/vasoconstriction
• Occurs in seconds to minutes
• Basic theories:
• • Vasodilator theory
• • Oxygen (nutrient) lack theory
• Long-term control:
• Increase in sizes/numbers of vessels
• Occurs over a period of days, weeks, or months

Question 2

Describe the vasodilator theory

Answer 2

• As metabolism increases, oxygen levels decrease.
• This initiates the formation of Vasodilators
• Examples: Adenosine Carbon dioxide Adenosine phosphate compounds Histamine Potassium ions Hydrogen ions

Question 3

Describe the oxygen (nutrient) Lack Theory:

Answer 3

As Oxygen levels go down, the blood vessels must relax through Vasodilation

Question 4

Define Vasomotion

Answer 4

Def: Cyclical opening and closing of precapillary sphincters.

• Number of precapillary sphincters open at any given time is roughly proportional to nutritional requirements of tissues. The assumption is that smooth muscles require oxygen to remain contracted.

Question 5

Describe Hyperemia

Answer 5

Can be either reactive or active.

• Reactive:
• • Tissue blood flow is blocked; can be for seconds, hours, or more.
• • When unblocked, blood flow increases up to 4-7x normal. This is Reactive Hyperemia
• Active:
• • When any tissue becomes active, rate of blood flow 8 Active: increases.
• See Slides 9-11

Question 6

Describe autoregulation.

What are two views that potentially explain autoregulation

Answer 6

In any tissue:

• Rapid increase in arterial pressure leads to increased blood flow.
• Within minutes, blood flow returns to normal even with elevated pressure.

Views to explain autoregulation:

• Metabolic theory
• Myogenic theory

Question 7

What are the basic differences between metabolic and myogenic theory?

Answer 7

Metabolic:
Increase in Blood Flow -> Too Many Nutrients or Too Much Oxygen -> Washes out Vasodilators, allowing reconstriction

Myogenic:
Stretching of Vessels -> Reactive Vasoconstriction

We aren’t sure which theory is true.
- See Slide 14

Question 8

Describe Blood Flow control Measures in the kidneys, brain, and skin

Answer 8

• Kidneys:
• Tubuloglomerular feedback:
• • Involves the macula densa/juxtaglomerular apparatus
• Brain
• Hydrogen and/or CO2 goes up -> Verebral Vessel Dilation -> Washing out of excess CO2/H+
• Skin
  Blood flow linked to body temperature
• Sympathetic nerves via CNS
• 3 ml/min/100 g tissue →7-8 L/min for entire body

Question 9

Describe Endothelial-Derived Mechanisms (For Control of Tissue Blood Flow)

Answer 9

• Healthy Endothelial Cells -> Nitric Oxide Release
• Nitric Oxide allows cGTP to be converted to cGMP in vascular smooth muscle cells…
• …which activates protein kinases that lead to Vasodilation

Hypertension occurs when:

• Damaged Cells, such as those that prevent Nitric Oxide to work properly, lead to the production of a peptide called endothelin,
• Which leads to vasoconstriction
• May wanna read this chapter for reals.
• And also, see slide 18

Question 10

Describe Humoral Circulation Controls for Vasoconstriction

Answer 10

• Norepinephrine
• Epinephrine
• Angiotensin II - Normally acts to increase total peripheral resistance
• Vasopressin - aka = ADH; very powerful vasoconstrictor; major function is to control body fluid volume

Question 11

Describe Humoral Circulation Control for Vasodilation

Answer 11

• Bradykinins - Causes both vasodilation and increased capillary permeability.
• Histamine - Powerful vasodilator derived from mast cells and basophils)

Question 12

What is the purpose of the sympathetic system?

Answer 12

• Innervates all vessels except capillaries
• Primarily results in vasoconstriction
• See Slides 22, 23

Question 13

Where is the vasoconstrictor and the vasodilator area of the brain located

Answer 13

• Vasoconstrictor area:
• Anterolateral portions of upper medulla
• Transmits continuous signals to blood vessels:
• • Continual firing results in sympathetic vasoconstrictor tone.
• • Partial state of contraction of blood vessels = vasomotor tone.
• Vasodilator area:
• Bilateral in the anterolateral portions of lower medulla
• Inhibits activity in vasoconstrictor area

Question 14

Where is the vasomotor sensory and the higher nervous control centers of the brain located?

Answer 14

• Sensory area:
• Bilateral in tractus solitarius in posterolateral portion of medulla
• Receives signals via:
• • Vagusnerves (CN X)
• • Glossopharyngeal nerves (CN IX)
• Controlled by higher nervous centers:
• Reticular substance (RAS)
• Hypothalamus
• Cerebral cortex

See Slides 26, 27

Question 15

What is the adrenal medulla

Answer 15

Secretes epinephrine and norepinephrine

Question 16

What occurs during neural rapid control of arterial pressure?

Answer 16

• Simultaneous changes:
• • Constriction of most systemic arteries
• • Constriction of veins
• • Increased heart rate
• Rapid response (within seconds)
• Increased blood pressure during exercise (accompanied by vasodilation)
• Alarm reaction (fight or flight)
• See Slide 30

Question 17

Where are baroreceptors located

Answer 17

• Located in carotid sinuses and aortic sinus:
• Stimulated by low arterial pressures:
• • Carotid sinuses are stimulated by pressure > 60 mm Hg
• • Aortic sinus is stimulated by pressure > 30 mm Hg
• • Vagus nerves (CN X)
• Glossopharyngeal nerves (CN IX) via small Herring’s nerves (carotid baroreceptors)
• Reticular substance (RAS)
• Hypothalamus
• Cerebral cortex

Question 18

Describe the signals from baroreceptors

Answer 18

• Inhibit vasoconstrictor center
• Excite vasodilator center
• Signals cause either increase or decrease in arterial pressure.
• Primary function is to reduce the minute-by-minute variation in arterial pressure.
• See Slides 34-38

Question 19

Describe Chemoreceptors

Answer 19

• Located in carotid bodies in bifurcation of the common carotids and in aortic bodies.
• Chemosensitive cells sensitive to lack of oxygen, carbon dioxide excess, and hydrogen ion excess.
• Signals pass through Herring’s nerves and vagus nerves.
• Play a more important role in respiratory control.

Question 20

Describe atrial reflexes

Answer 20

• Low pressure receptors are located in the atria and pulmonary arteries and play an important role in minimizing arterial pressure changes in response to changes in blood volume.
• Increase in atrial stretch results in:
• Reflex dilation of kidney afferent arterioles
• Increases kidney fluid loss
• Decreases blood volume
• Increase in heart rate (via CN X to medulla)
• Signals to hypothalamus to reduce [ADH]
• Atrial natriuretic peptide (ANP) -> Kidneys
• Peptide in Kidneys Increase GFR, and Decrease Sodium Reabsorption

Question 21

Describe arterial pressure relationship with kidneys

Answer 21

• Arterial pressure = cardiac output X total peripheral resistance
• Arterial pressure rises when total peripheral resistance is acutely increased.
• Normal functioning kidneys return the arterial pressure back to normal within a day or two:
• • Pressure diuresis
• • Pressure natriuresis
• See Slide 42

Question 22

What are the characteristics of primary hypertension

Answer 22

• Increased cardiac output
• Increased sympathetic nerve activity
• Increase in angiotensin II and aldosterone levels
• Impairment of renal-pressure natriuresis mechanism
• Inadequate secretion of salt and water
• Primary (essential hypertension):
• Hypertension of unknown origin
• 90 –95% of hypertension
• Major factors include:
• • Weight gain, characterized by: Increased cardiac output, Increased sympathetic nerve activity, Increased antiotensin II and aldosterone levels, and Impaired renal-pressure natriuresis mechanism
• -Sedentary life style

Question 23

Describe secondary hypertension

Answer 23

• Hypertension second to some other cause:
• Tumor affecting renin-secreting juxtaglomerular cells
• Renal artery constriction
• Coarctation of the aorta
• Preeclampsia
• Neurogenic hypertension
• Genetic causes

Question 24

What are renal-based causes of hypertension?

Answer 24

• Chronic renal disease
• Renal artery stenosis
• Renin-producing tumors
• Acute glomerulonephritis
• Polycystic disease
• Renal vasculitis

Question 25

What are endocrine-based causes of hypertension?

Answer 25

• Cushing syndrome (adrenocortical hyperfunction)
• Exogenous hormones (i.e., glucocorticoids, estrogen)
• Pheochromocytoma
• Acromegaly
• Hypothyroidism (myxedema)
• Hyperthyroidism (thyrotoxicosis)
• Pregnancy induced

Question 26

What are cardiovascular-based causes of hypertension

Answer 26

• Coarctation of the aorta
• Polyarteritis nodosa
• Increased intravascular volume
• Rigidity of the aorta
• Increased cardiac output

Question 27

What are neurological-based causes of hypertension?

Answer 27

• Psychogenic
• Increased intracranial pressure
• Sleep apnea
• Acute stress

Question 28

What are contributing factors to hypertension

Answer 28

• Genetic factors (Essential hypertension is a complex multifactorial disorder)
• Other single-gene disorders that alter sodium reabsorption by the kidneys
• Genetic variants in the renin-angiotensin system
• Stress
• Obesity
• Smoking
• Physical inactivity
• Heavy consumption of salt

Question 29

What are Factors resulting in decreased peripheral resistance (vessel dilation) leading to decreased blood pressure

Answer 29

• Increased production of nitric oxide
• Increased release of prostacyclin
• Increased release of kinins
• Increase in atrionatriuretic peptide (ANP)
• Decreased neural factors (β-adrenergic)

Question 30

What are Factors resulting in decreased cardiac output leading to decreased blood pressure

Answer 30

• Decreased blood volume
• Decreased heart rate
• Decreased contractility

Question 31

What are hypertension factors resulting in increased cardiac output leading to increased blood pressure

Answer 31

• Increased heart rate
• Increased contraction
• Increased blood volume (due to aldosterone)

Question 32

What are hypertension factors resulting in increased peripheral resistance leading to increased blood pressure

Answer 32

• Increased angiotensin II
• Increased catecholamines
• Increased thromboxane
• Increased neural factors (α-adrenergic)

Question 33

List examples of humoral vasoconstrictors and vasodilators.

Answer 33

• Vasoconstrictors:
• Angiotensin II
• Catecholamines
• Endothelin
• Vasodilators:
• Kinins
• Prostaglandins
• Nitric oxide

Question 34

What are the lethal effects of chronic hypertension?

Answer 34

• Early heart failure and coronary artery disease
• Cerebral infarct
• Kidney failure

Question 35

What are characteristics of atherosclerosis

Answer 35

• Atherosclerosis is a type of arteriosclerosis (“hardening of the arteries”).
• The major characteristic of atherosclerosis is the presence of lesions within the intima of the vessel wall that protrude into the vessel lumen.

Question 36

What are non-modifiable (constitutional) risk factors of atherosclerosis?

Answer 36

• Age:
• Risk increases between the ages of 40 and 60.
• Death rates from ischemic heart disease increase with each decade.
• Gender:
• Uncommon in premenopausal women without other risk factors
• Increases after menopause and eventually exceeds that of men
• Genetics:
• Some Mendelian disorders associated with atherosclerosis but mostly multifactorial

Question 37

What are modifiable risk factors of atherosclerosis?

Answer 37

• Hyperlipidemia (esp., hypercholesterolemia):
• Major risk factor
• Correlated with high levels of LDL (carries cholesterol to peripheral tissues) as opposed to HDL (carries cholesterol to liver)
• Hypertension
• Increases risk of IHD by 60%
• Most important cause of left ventricular hypertrophy
• Cigarette smoking
• Diabetes

Question 38

What are other risk factors of atherosclerosis?

Answer 38

• Inflammation
• Hyperhomocystinemia
• Metabolic Syndrome
• Lipoprotein(a)
• Factors affecting Hemostasis
• Lifestyle (Including Lack of Exercise, Competitive/Stressful lifestyle, and Obesity)

Question 39

How does inflammation contribute as a risk factor to atherosclerosis?

Answer 39

• Intimately linked with atherosclerotic plaque formation
• C-reactive protein (CRP) is a major marker for inflammation.
• Synthesized by liver
• Plays important role in opsonizing bacteria and activating complement
• Correlated with high levels of LDL (carries cholesterol to peripheral tissues) as opposed to HDL (carries cholesterol to liver)

Question 40

How does hyperhomocystinemia contribute as a risk factor to atherosclerosis?

Answer 40

• Inborn error of metabolism

- Associated with premature vascular disease

Question 41

How does metabolic syndrome contribute as a risk factor to atherosclerosis?

Answer 41

• Associated with insulin resistance:
• Characteristics:
• • Obesity (esp. abdominal fat)
• • Insulin resistance
• • Fasting hyperglycemia
• • Increased lipid triglycerides
• • Decreased HDL levels
• • Hypertension

Question 42

What factors can cause endothelial injury or dysfunction?

Answer 42

• Results in intimal thickening
• May lead to formation of atheroma in presence of hyperlipidemia
• Factors related to endothelial dysfunction:
• • Hypertension
• • Hyperlipidemia
• • Cigarette smoke
• • Homocysteine
• • Infectious agents
• • Hemodynamic disturbances
• • Hypercholesterolemia

Question 43

What can cause an accumulation of lipoproteins? (Especially LDL)

Answer 43

• Result of chronic hyperlipidemia (esp. hypercholesterolemia)
• Lipoproteins accumulate in the intima and are oxidized by oxygen free radicals generated by macrophages or endothelial cells.
• Oxidized LDL is ingested by macrophages which become foam cells.
• Oxidized LDL stimulates release of growth factors, cytokines, and chemokines.
• Oxidized LDL is toxic to endothelial cells and smooth muscle cells.

Question 44

What factors are associated with monocyte adhesion to the endothelium?

Answer 44

• Endothelial cells express VCAM-1 adhesion molecules that bind monocytes and T cells to endothelium.
• Monocytes transform into macrophages and engulf lipoproteins.
• T cells stimulate a chronic inflammatory response.
• Activated leukocytes and endothelial cells release growth factors that promote smooth muscle cell proliferation

Question 45

How is smooth muscle proliferation linked as a risk factor to atherosclerosis?

Answer 45

• Intimal smooth muscle cell proliferation and extracellular matrix deposition converts a fatty streak into a mature atheroma.

Question 46

What is the morphology of atheroma?

Answer 46

An atheroma consists of a cap of smooth muscle cells, macrophages, foam cells (converted macrophages), and other extracellular components, overlying a necrotic center composed of cell debris, cholesterol, foam cells, and calcium.

Question 47

What are the developmental stages of atherosclerosis?

Answer 47

• Earliest lesions are fatty streaks:
• • Note these are also seen in all children older than 10.
• Atherosclerotic plaques impinge on the lumen of the artery and grossly appear white or yellow.
• Plaques progressively enlarge due to cell death and degeneration and synthesis/degradation of extracellular matrix.
• Plaques often undergo calcification.
• Plaques may rupture, ulcerate, or erode.

Question 48

What are the most common arterial sites for atherosclerosis?

Answer 48

Ranked from Most Involved to Least:

• Lower abdominal aorta
• Coronary arteries
• Popliteal arteries
• Internal carotid arteries
• Circle of Willis
• See Slide 68

Question 49

What are short-term and long-term controls of arterial pressure?

Answer 49

• Short term control of arterial pressure:
• Via sympathetic nervous system effects on:
• • Total peripheral vascular resistance and capacitance
• • Cardiac pumping ability
• Long term control of arterial pressure:
• Via multiple nervous and hormonal controls
• Via local controls in kidney that regulate:
• • Salt and water excretion
• See Slide 70, 71

Question 50

What is the relation of arterial pressure and kidney output?

Answer 50

• As arterial pressure goes up, urine output goes up, causing pressure diuresis
• As arterial pressure goes up, sodium output goes up, causing pressure natriuresis
• Return of the arterial pressure always back to the equilibrium point = Near Infinite Feedback Gain Principle.
• Primary determinants of the long-term arterial pressure level:
• • Degree of pressure shift of the renal output curve for water/salt
• • Level of water/salt intake
• SEE SLIDES 73-76

Question 51

Define Chronic Hypertension

Answer 51

Definition:

• One’s mean arterial pressure is greater than the upper range of the accepted normal measure.
• Normal: 90 mm Hg (110/70)
• Hypertensive: 110 mm Hg (135/90)
• Severe hypertensive: 150/170 (250/130)
• See Slide 79-80

Question 52

What are the lethal effects of chronic hypertension?

Answer 52

• Early heart failure
• Coronary heart disease
• Heart attack
• Cerebral infarct
• Destruction of kidney areas->kidney failure->uremia->death

Question 53

See Slides 83-88

Answer 53

Consider making more flashcards on this part.