Long Term Control of Blood Pressure Flashcards

1
Q

Which organ is responsible for long term control of blood pressure?

A

•Revolves around the control of plasma volume by the kidney

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2
Q

What are the functions of the kidney?

A

–Excretion of waste products

–Maintenance of ion balance

–Regulation of pH

–Regulation of osmolarity

–Regulation of plasma volume

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3
Q

What are the following areas labelled on this nephron?

A
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4
Q

What is the effect of the renal counter current system?

A

Creates a very high osmolarity outside the collecting duct

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5
Q

How is control over how much water is lost with urine acheived?

A

Osmotic gradient exists between the collecting duct and outside the collecting duct.

Na+ transport determines this gradient

•Control over the permeability of the collecting duct to water determines if water follows that osmotic gradient or not

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6
Q

Where is sodium pumped?

A

Pumped outside of the distal tube - concentration of the solute therefore decreases significantly before it reaches the collecting duct

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7
Q

What is the affect of varying the permeability of the collecting duct?

A
  • If collecting duct very permeable to water will result in lots of water reabsorption, little urine, and conserve plasma volume
  • Making the collecting duct very impermeable to water will result in little reabsorption, lots of urine (= diuresis), and a reduction in plasma volume
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8
Q

What are the three main hormones that regulate water reabsorption?

A

Renin - angiotensin - aldosterone system

Antidiuretic factor (ADH, vasopressin)

Atrial natriuretic peptide

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9
Q

Where is the renin produced?

A

–From the juxtaglomerular (= granule cells) of the kidney

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10
Q

What triggers renin production?

A

–Activation of sympathetic nerves to the juxtaglomerular apparatus

–Decreased distension of afferent arterioles (the “renal baroreflex”)

–Decreased delivery of Na+/Cl- through the tubule

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11
Q

What is responsible for detecting a reduced delivery of sodium and chlorine ions?

A

Macula densa

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12
Q

Where do you find the macula densa?

A

The ascending loop of henle

(distal convulated tubule)

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13
Q

Where is renin produced?

A

In the juxtaglomerular of the kidneys - granule cells

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14
Q

What triggers renin production?

A

Signs of low mean arterial pressure:

  • Activation of sympathetic nerves to the juxtaglomerular apparatus
  • Decreased distension of afferent arterioles (renal baroreflex)
  • Decreased delivery of sodium and chlorine through the tubule
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15
Q

What does renin do?

A

Converts angiotensinogen to angiotensin 1

Angiotensin converting enzyme

Angiotensin 2

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16
Q

How does angiotensin increase MAP?

A

Stimulates release of aldosterone from the adrenal cortex.

(this increases the amount of sodium reabsorption in the loop of henle - less diuresis and increased plasma volume)

Increases the release of ADH from the pituitary

(increases the permeability of the collecting duct, reduces diuresis. Increases sense of thirst)

Is a vasoconstrictor

(increases total peripheral resistance)

17
Q

How is the formation of angiotensin 2 a form of negative feedback?

A
  • Multiple mechanism detect any decrease in MAP
  • Stimulates release of renin
  • This evokes multiple mechanisms which increase MAP
18
Q

Where is ADH produced?

A

–Synthesised in the hypothalamus

–Released from the posterior pituitary

19
Q

What triggers ADH release?

A

A decrease in blood volume - (Baroreceptors from CVS relayed by medullary cardiovascular centres)

An increase in osmolarity in interstitial fluid (osmoreceptors in the hypothalamus)

Circulating angiotensin 2 (triggered by the renin-angiotensin-aldosterone system)

20
Q

What is the effect of ADH?

A

Increases the permability of the collecting duct to H2O

Causes vasoconstriction (hence why it is sometimes known as vasopressin)

21
Q

Why is the release of ADH classed as a negative feedback mechanism?

A

–Multiple mechanism detect any decrease in MAP

–Stimulates release of ADH

–This evokes multiple mechanisms which increase MAP

22
Q

What does ANP stand for?

A

Atrial natriuretic peptide

23
Q

Where is atrial natriuretic peptide formed?

A

Produced in and released from the myocardial cells in the atria

24
Q

What triggers release of ANP?

A

Increased distension of the atrium ( a sign of increased MAP)

25
Q

What does ANP do?

A

Increases the excretion of sodium (natriuresis) - (opposes the act of angiotensin 2 which causes lots of sodium to be reabsorbed by the loop of henle)

Inhibits the release of renin

Acts on the medullary CV centres to reduce MAP

26
Q

Why is the release of ANP described as a negative feedback mechanism?

A

–A mechanism that detects any increase in MAP

–Stimulates release of ANP

–This evokes multiple mechanisms which reduce MAP

27
Q

What percentage of hypertension cases are as a result of secondary (knoown) causes?

A

Only 5% to 10%

28
Q

What are the rational drug treatments for hypertension?

A

–Ca2+ channel antagonists

–b-adrenoceptor antagonists – specifically beta 1 receptor antagonist – reduces cardiac output and blood pressure

Thiazide diuretics – work in sodium transporter in kidney – stops build up of sodium gradient – makes you excrete more water

Angiotensin converting enzyme inhibitors

Angiotensin 2 antagonist