Renal System

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what does the renal corpuscle consist of?

the glomerular capsule (aka Bowman's capsule) and the glomerulus (highly permeable capillary bed)

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what does the nephron consist of?

the renal corpuscle and the tubular portion: PCT, loop of Henle, DCT, collecting duct

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what 3 features must an anatomical structure have to be classified as a counter current system:

1) must consist of either 2 parallel tubes or a single U-shaped tube (vasa recta & loop of Henle), 2) the flow through these tubes must be in opposite directions, 3) the tubes must be in close proximity to each other

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what occurs in all counter current systems?

something (i.e. a substance or heat) is transferred from one tube to the others

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what makes a counter current system a multiplier?

active transport must occur in the transfer

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what makes a counter current system an exchanger?

if only diffusion occurs in the transfer

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What are the 2 types of nephrons? What percentage does each constitute?

cortical: 80%; juxtamedullary: 20%

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Describe cortical nephrons

have short loops which don't extend out of the cortex

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What type of urine do cortical nephrons form?

isotonic and hypotonic

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Describe juxtamedullary nephrons

have long loops of Henle which extend deep into the medulla of the kidney

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what is filtration?

the movement of liquid from high hydrostatic pressure to low hydrostatic pressure, thru the glomerular capillary

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how does liquid flow through the glomerulus?

thru the glomerular capillary into Bowman's capsule

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what methods are used for reabsorption?

active transport (for reabsorption of many solutes such as glucose & amino acids); simple diffusion (used for reabsorption of lipid soluble solutes); osmosis (reabsorption of water)

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what method is used for secretion?

active transport (it occurs against the concentration gradient)

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What types of urine do juxtamedullary nephrons form?

iso-, hypo-, and hypertonic urine

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How do juxtamedullary nephrons function?

as counter current multipliers as they actively concentrate urea & salts in the medulla of the kidneys

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what happens when urea & salts are concentrated in the medulla of the kidneys?

it creates an environment with a high osmotic pressure so that water may be reabsorbed from the forming urine by osmosis if needed

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What is the vasa recta?

a specialized system of blood vessels

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how does the vasa recta function?

as a counter current exchanger; it picks up reabsorbed waer and leaves the solutes (salts & urea) behind in the medullary tissue

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what is filtrate?

the fluid flowing from the blood to the glomerular capsule; contains the same substances as plasma, except it does not contain large proteins or RBCs

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what is the "raw material" for urine formation?

blood plasma; once filtered into Bowman's capsule, it is called filtrate; as filtrate traverses the nephron tubules, desirable substances are reabsorbed back to the blood and additional wastes are secreted into filtrate; end product is urine

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what are the 2 factors that drive glomerular filtration?

1) permeabillity of the glomerular capillary endothelium which is fenestrated (more porous) 2) pressure gradient

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what are the 3 components of the pressure gradient?

1) glomerular hydrostatic pressure; 2) glomerular osmotic pressure; 3) capsular hydrostatic pressure

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what is hydrostatic pressure?

pressure exerted by a fluid against the walls of its container; blood pressure is a hydrostatic pressure

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what is osmotic pressure?

pressure due to the number of solute particles in a solution; water will move from an area of lower osmotic pressure to higher osmotic pressure

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what is the glomerular hydrostatic pressure?

is is about 55 mm Hg; it is aka blood hydrostatic pressure; the pressure exerted by the blood against the glomerular capillaries; it is the blood pressure in the glomerulus (it pushes blood out of the capillaries and into Bowman's capsule

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what is the glomerular osmotic pressure?

aka colloid osmotic pressure; about 30 mm Hg; due to large plasma proteins in the blood; pressure w/in capillaries due to non-diffusable, non-filterable solutes in the blood; the pressure is negative, as it tends to pull fluid back from Bowman's capsule

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what is the capsular hydrostatic pressure?

it is about 15 mm Hg; it is the pressure of Bowman's capsule due to presence of filtrate; it is also negative because it tends to push fluid back into the glomerulus

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what is the capsular osmotic pressure?

pressure in Bowman's capsule due to solutes in the filtrate; normally 0, but can be > 0 in case of disease; in this case it would be an outward pressure, pulling filtrate into capsule

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what is the net filtration pressure?

the difference between opposing pressures: NFP = GHP - (GOP + CHP)

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how is the pressure gradient formed?

due to the difference in size of afferent & efferent arterioles

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what are the 2 outward pressures in the glomerulus?

GHP and COP (COP is normally 0)

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what are the 2 inward pressures in the glomerulus?

CHP and GOP

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what is the normal glomerular filtration rate?

125 ml/min; 180 L/day; 48 gallons/day

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what is the effect of GFR on urine production?

when rate increases, production increases; decrease in rate, decrease in urine

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what is renal autoregulation?

self-regulating mechanism which assures that GHP is the dominant pressure, assuring a net filtration pressure

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what are the 4 renal autoregulation mechanisms?

myogenic mechanism, tubuloglomerular feedback mechanism, renin-angiotensin mechanism, atrial natriuretic factor (ANF) aka atriopeptide

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how does the myogenic mechanism work?

it involves the smooth muscle of the afferent glomerular arterioles; when stretche, it responds by contracting or constricting

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what happens in the myogenic mechanism when there is an increase in systemic blood pressure?

the afferent arteriole is constricted, decreasing the amt of blood in the glomeruli and decreasing the GHP, preventing the loss of increased amts of blood plasma into the filtrate

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what happens in the myogenic mechanism when there is an decrease in systemic blood pressure?

the afferent arteriole is dilated, increasing the volume of blood in the glomeruli and increasing the glomerular hydrostatic pressure to ensure that filtrate will be made

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when is the myogenic mechanism most effective?

when blood pressure is between 110 and 200 mm Hg

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how does the tubuloglomerular feedback mechanism work?

it is controlled by the macula densa cells of the juxtaglomerular apparatus, located in the distal tubule; it monitors the flow and osmolarity of the filtrate in the distal tubule

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what happens in the tubuloglomerular feedback mechanism when there is low osmolarity and slow flow?

the afferent arteriole is dilated, resulting in an increase in GHP, increase in GFR, and accordingly more filtrate formed

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what happens in the tubuloglomerular feedback mechanism when there is high osmolarity and fast flow?

the afferent arteriole is constricted, resulting in an decrease in GHP, decrease in GFR, and accordingly less filtrate formed

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how does the renin-angiotensin mechanism work?

it is a powerful, long-term regulator of blood pressure and glomerular filtration and is controlled by the hormone renin?

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what is renin work and what is its stimulus?

it is a hormone produced by the juxtaglomerular cells of the juxtaglomerular apparatus and its stimulus is decreased blood pressure or decreased flow in the afferent arteriole

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what does renin do?

it activates the plasma protein angiotensinogen into angiotensin I

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what is angiotensinogen?

it is the inactive form of angiotensin I and it is produced by the liver and circulates in the plasma

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what is angiotensin convertine enzyme?

aka ACE; it converts angiotensin I to angiotensin II

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what are the 2 effects of the renin-angiotensin mechanism?

1) systemic vasoconstriction, which increases blood pressure; 2) release of aldosterone from the adrenal cortex, causing reabsorption of sodium chloride, and water

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how does aldosterone impact GFR?

the reabsorption of water and NaCl increases blood pressure because by reabsorbing more NaCl, more water is drawn into the blood, increasing systemic blood volume

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what is atrial natriueretic factor?

aka ANF, aka atriopeptide, aka atriopeptin; it is a hormone produced by the atria (right atrium?) of the heart

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what is the stimulus and action of ANF?

stimulus: increased pressure in the right atrium; action: inhibits the secretion of renin and aldosterone, causing vasodilation which decreases blood pressure and volume

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what is renal reabsorption?

the uptake of desirable substances from the filtrate back into the blood by way of the peritubular capillaries

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where does renal reabsorption take place?

desirable substances are moved from the lumen of the renal tubules into the lumen of the peritubular capillaries

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how much water is reabsorbed in the peritubular capillaries and where does it occur?

99% of water is reabsorbed; 60-80% of filtered water is reabsorbed in the proximal convoluted tubule; 15% of filtered water is reabsorbed in the loop of Henle

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how much solute is reabsorbed?

it varies depending on the solute; nearly all glucose, amino acids, and small proteins are reabsorbed in the PCT

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how are glucose, amino acids, and small proteins reabsorbed?

in the PCT, by active transport

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what is the role of the collecting duct in reabsorption?

only water is reabsorbed here; it is the 2nd largest place where water is reabsorbed; regulated by ADH

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what is the impact of aldosterone on the reabsorption of water?

aldosterone regulates the reabsorption of extra sodium; stimulated when body fluids are too dilute

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what is the impact of ADH on reabsorption of water?

ADH regulates the reabsorption of water from the collecting duct and is released when body fluids become too concentrated; it targets the water channels in the collecting duct, opening them, to cause water to be reabsorbed

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where is ADH released from?

the psterior pituitary

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what happens to urine volume and urine concentration when ADH is released?

because water is reabsorbed into the peritubular capillaries, urine volume decreases and becomes more concentrated

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what is the relationship between ADH and aldosterone

when aldosterone is released, ADH is suppressed, closing up the water channels in the collecting duct

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what is secretion?

movement of substances from the peritubular capillaries to the epithelial cells of the tubules into the lumen of the tubules

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how is secretion accomplished and regulated?

by active transport; regulated by hormones

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what substances are secreted?

creatinine, H+, K+, many organic molecules, drugs, and drug metabolites

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what is creatinine?

a metabolic waste product

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where is H+ secreted? What is it linked with?

H+ is secreted in the distal nephron tubules and is coupled with bicarbonate reabsorption by the tubular cells to control pH of body fluids

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what is the secretion of potassium linked with? How is it regulated?

potassium secretion is linked with Na+ reasborption; it is regulated by aldosterone from the adrenal cortex

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what happens to most substances secreted?

they eventually are excreted in the urine

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what are the 2 components of the countercurrent mechanism in the nephron?

both involve the juxtamedullary nephron; 1) the vasa recta serves as a counter current exchanger; 2) the long loop of Henle serves as a counter current multiplier

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what is the importance of the juxtamedullary nephron?

it is capable of forming hypertonic urine

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how is hypertonic urine formed?

ADH opens water channels in the collecting ducts; because of high solute concentration in the medulla, H2O flows down its concentration gradient so that it is reabsorbed into the blood

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what is the normal osmolarity of body fluids? What is the maximum concentration of urine?

320 mOsm; 1800 mOsm

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describe the permeability of the descending and ascending limbs of the loop of Henle

the descending limb is impermeable to solutes, permeable to H2O; the ascending limb is permeable to solutes, impermeable to H2O

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how and what is moved in the ascending limb of Henle?

active transport is used to transport solutes out to the medulla; solutes include Na+, K+, Cl-; the transport of these solutes depends on the Na+/K+ pump; Na+, K+, Cl- are co-transported all at the same time

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what is the vasa recta and what is its function?

it is a special portion of the peritubular network of blood vessels that surrounds and runs parallel to the nephron tubules (inc. loop of Henle) and functions to maintain solute concentration

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how does the vasa recta maintain solute concentration?

it carries off reabsorbed water, keeping solutes behind in the medulla, due to the slow flow of blood in the vasa recta and concentration gradients

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describe osmolarity in the medullary tissue

osmolarity increases as you get deeper into the medulla, due to active transport of solutes (primarily sodium and urea) from filtrate to medulla

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where is ADH produced and released from?

produced by the supraoptic nuclei of the hypothalamus; released from the posterior pituitary

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when is ADH released?

when body fluids become too concentrated

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where are the receptors for ADH release?

osmoreceptors in the hypothalamus and baroreceptors in the carotid bifurcation and aortic arch

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what is the purpose of the osmoreceptors?

they monitor osmotic concentration of blood; stimulates ADH release when osmolarity increases

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what is the purpose of the baroreceptors?

they detect changes in systemic blood pressure; when pressure increases, ADH is inhibited (i.e. if blood pressure increases, the blood already contains enough water)

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what is the target of ADH?

the collecting ducts; it increases permeability of the collecting duct by opening water channels (aquaporins)

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what is the function of ADH and its result?

water reabsorption; result - production of small volume of concentrated urine

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what happens to the contents of the tubule once it flows thru the collecting duct?

no further processing occurs; the finished product is called urine

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what is the pathway for urine elimination?

collecting ducts -> renal calyces -> renal pelvis -> ureter -> urinary bladder -> ureter -> out

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how is urine carried from the kidneys to the urinary bladder?

by ureteral peristalsis

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what is the stimulus for micturition?

stretch of bladder wall stimulates stretch receptors

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which nerve signals are involved in micturition?

1) afferent nerve signal to sacral spinal cord 2) efferent nerve signal to the parasympathetic motor fibers of the pelvic nerve

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which muscles are involved in micturition?

1) contraction of detrusor muscle of the bladder 2) relaxation of internal urethral sphincter 3) voluntary relaxation of external urethral sphincter (skeletal muscle)

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which part of the nervous system controls the relaxation of the external urethral sphincter?

CNS both facilitates and inhibits the external sphincter; voiding is voluntary and the reflex can be overridden

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what happens in the body when an individual is well hydrated?

decreased serum osmolarity (<270 mOsm), increased blood pressure, decreased serum sodium concentration

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What is the body's response to decreased serum osmolarity?

osmoreceptors in the hypothalamus sense the decreased osmolarity, thirst is decreased, and ADH secretion is decreased

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What is the body's response to increased blood pressure?

baroreceptors in the carotid bifurcation and aortic arch (sinuses) and volume receptors in the atria detect the increase in pressure; increased secretion of atriopeptide (ANF), which causes inhibition of renin (which accordingly reduces angiotensin I and

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does vasoconstriction increase or decrease systemic blood pressure?

vasoconstriction increases blood pressure (think of high blood pressure caused by arteriosclerosis); vasodilation decreases blood pressure

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what is the body's response to decreased serum sodium concentration?

aldosterone production is increased, causing increased reabsorption of sodium

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what is the renal response to large volume of dilute urine (well hydrated)?

vasodilation of the afferent glomerular arteriole to increase filtration

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what causes vasodilation and vasoconstriction of the afferent glomerular arteriole?

1) myogenic mechanism and 2) juxtaglomerular apparatus

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what happens in the body when an individual is poorly hydrated or dehydrated?

increased serum osmolarity (>320 or >300 mOsm), decreased blood pressure

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What is the body's response to increased serum osmolarity?

osmoreceptors in the hypothalamus sense the increased osmolarity, thirst is increased, and ADH secretion is increased, causing increased reabsorption of water from tubules

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What is the body's response to decreased blood pressure?

baroreceptors and volume receptors in the atria detect the decrease in pressure; secretion of ANF is decreased, allowing production of renin (which accordingly increases angiotensin I and II), increasing vasoconstriction and aldosterone production

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what is the renal response to small volume of concentrated urine (poorly hydrated)?

vasoconstriction of the afferent glomerular arteriole to decrease filtration

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where is renin produced?

in the walls of the afferent & efferent arterioles

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where does angiotensin I come from?

converted from the inactive protein angiotensinogen, which is produced in the liver

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what is the relationship between ANF, renin, angiotensin I and II, and aldosterone?

increase in ANF, decreases renin, angiotensin I and II; decrease in ANF, increases renin, angiotensin I and II and aldosterone

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how is calcium homeostatis regulated?

by parathyroid hormone (PTH) and calcitonin

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how does PTH work? What are its targets?

parathyroid hormone is released from the parathyroid glands when calcium levels are low; its targets are bone (increased osteoclast activity and release of calcium from the bone), kidney (increased absorption of calcium), and small intestine (increase abs

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how does calcitonin work? What is its target?

calcitonin is released from the thyroid gland when calcium levels are high; it targets the bone by increasing the bones' uptake of calcium

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how is sodium homeostasis regulated?

by the renin-angiotensin system; by aldosterone and atriopeptide (ANF)

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what is aldosterone and where is it produced?

it is a steroid hormone, produced by the adrenal glands and is secreted in response to angiotensin II

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what is the trigger for aldosterone secretion? When is aldosterone secretion inhibited?

when Na+ levels are low; it causes increased reabsorption of Na+ from the nephron tubules; also triggered in response to angiotensin II; aldosterone secretion is inhibited by ANF, which is released when Na+ levels are high

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what is the role of atriopeptide in sodium homeostatis?

atriopeptide, aka ANF, is released when Na+ levels are high, which inhibits renin, angiotensin I and II, and aldosterone

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how is potassium homeostasis regulated?

by the reninangiotensin system

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what is the role of aldosterone in potassium homeostatis?

increase in potassium levels, increase in aldosterone (so K+ is secreted into tubules), increase in potassium excretion; decrease in potassium levels, decrease in aldosterone, less potassium excreted

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what is the role of atriopeptide in sodium homeostasis?

atriopeptide, aka ANF, is inhibited when K+ levels are high, which stimulates renin, angiotensin I and II, and aldosterone

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