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Actions of the RAAS 1. Dilates the afferent arteri ...
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Flashcards in this deck (62)

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  • What are the 4 main actions of the RAAS?

    • Dilates afferent arteriole, constricts efferent arteriole.
    • Stimulates sodium reabsorption in proximal convoluted tubule.
    • Triggers aldosterone release for sodium reabsorption and potassium excretion.
    • Triggers ADH release to stimulate water reabsorption.
    physiology raas

  • What is the role of the afferent and efferent arterioles in the RAAS?

    The RAAS dilates the afferent arteriole and constricts the efferent arteriole to regulate blood flow and pressure in the glomerulus.

    physiology raas kidney

  • How does the RAAS affect sodium reabsorption in the proximal convoluted tubule?

    The RAAS stimulates sodium reabsorption in the proximal convoluted tubule.

    physiology raas sodium

  • What hormone does the RAAS trigger the adrenal cortex to release?

    The RAAS triggers the adrenal cortex to release aldosterone.

    physiology raas aldosterone

  • What are the effects of aldosterone release triggered by the RAAS?

    Aldosterone causes sodium reabsorption and potassium excretion in the distal convoluted tubule and collecting duct.

    physiology raas aldosterone

  • What hormone does the RAAS trigger the hypothalamus to release?

    The RAAS triggers the hypothalamus to release antidiuretic hormone (ADH).

    physiology raas adh

  • What is the effect of ADH release stimulated by the RAAS?

    ADH stimulates water reabsorption in the collecting duct.

    physiology raas adh

  • Why is tubular reabsorption important?

    Tubular reabsorption is important because the body cannot lose 120 mL of water-containing essential substances every minute.

    physiology kidney

  • Where does tubular reabsorption primarily occur?

    Tubular reabsorption primarily occurs in the proximal convoluted tubule.

    physiology kidney

  • What structures within the nephrons facilitate reabsorption?

    Nephrons use cellular transport mechanisms to reabsorb essential substances and water.

    physiology kidney

  • What are the two main types of reabsorption mechanisms?

    Active transport and passive transport.

    physiology kidney

  • What is required for active transport to occur in tubular reabsorption?

    The substance to be reabsorbed must combine with a carrier protein in the membranes of renal tubular epithelial cells.

    physiology kidney active_transport

  • What is the role of electrochemical energy in active transport?

    Electrochemical energy transfers the substance across the cell membranes and back into the bloodstream.

    physiology kidney active_transport

  • What substances are reabsorbed via active transport in the proximal convoluted tubule?

    Glucose, amino acids, and salts.

    physiology kidney active_transport

  • What substance is reabsorbed via active transport in the ascending loop of Henle?

    Chloride.

    physiology kidney active_transport

  • What substance is reabsorbed via active transport in the distal convoluted tubule?

    Sodium.

    physiology kidney active_transport

  • What is passive transport?

    The movement of molecules across a membrane due to differences in concentration or electrical potential.

    physiology kidney passive_transport

  • What are gradients in the context of passive transport?

    Physical differences in concentration or electrical potential on opposite sides of the membrane.

    physiology kidney passive_transport

  • Where does passive reabsorption of water take place in the nephron?

    In all parts of the nephron except the ascending loop of Henle.

    physiology kidney passive_transport

  • Why does passive reabsorption of water not occur in the ascending loop of Henle?

    The walls of the ascending loop of Henle are impermeable to water.

    physiology kidney passive_transport

  • Where is urea passively reabsorbed?

    In the proximal convoluted tubule and the ascending loop of Henle.

    physiology kidney passive_transport

  • What accompanies the active transport of chloride in the ascending loop?

    Passive reabsorption of sodium.

    physiology kidney passive_transport

  • What is the maximal reabsorptive capacity (Tm)?

    The maximal reabsorptive capacity (Tm) is the limit to how much of a substance can be reabsorbed by the tubules.

    physiology kidney

  • What happens when the filtrate concentration exceeds the Tm?

    The substance begins appearing in the urine.

    physiology kidney

  • What is the renal threshold?

    The plasma concentration at which active transport stops.

    physiology kidney

  • What is the plasma renal threshold for glucose?

    160 to 180 mg/dL.

    physiology kidney glucose

  • What happens when the plasma glucose concentration reaches the renal threshold?

    Glucose appears in the urine.

    physiology kidney glucose

  • How can knowledge of the renal threshold and plasma concentration be used?

    To distinguish between excess solute filtration and renal tubular damage.

    physiology kidney

  • What accompanies the active transport of sodium out of the proximal convoluted tubule?

    Passive reabsorption of an equal amount of water.

    physiology kidney

  • What is the concentration of the fluid leaving the proximal convoluted tubule compared to the ultrafiltrate?

    The fluid maintains the same concentration as the ultrafiltrate.

    physiology kidney

  • Where does renal concentration begin?

    In the descending and ascending loops of Henle.

    physiology kidney

  • What is the filtrate exposed to in the loops of Henle?

    The high osmotic gradient of the renal medulla.

    physiology kidney

  • What happens to water in the descending loop of Henle?

    Water is removed by osmosis.

    physiology kidney

  • What is reabsorbed in the ascending loop of Henle?

    Sodium and chloride.

    physiology kidney

  • What prevents excessive reabsorption of water in the ascending loop of Henle?

    The water-impermeable walls of the ascending loop.

    physiology kidney

  • What is the countercurrent mechanism?

    A selective reabsorption process that maintains the osmotic gradient of the medulla.

    physiology kidney

  • What is the role of sodium and chloride leaving the filtrate in the ascending loop?

    They prevent dilution of the medullary interstitium by the water reabsorbed from the descending loop.

    physiology kidney

  • Why is maintaining the osmotic gradient essential?

    It is essential for the final concentration of the filtrate when it reaches the collecting duct.

    physiology kidney

  • Why is the filtrate leaving the ascending loop dilute?

    Due to reabsorption of salt but not water.

    renal physiology kidney

  • Where does sodium reabsorption continue after the ascending loop?

    Distal convoluted tubule.

    renal physiology kidney

  • What hormone regulates sodium reabsorption in the distal convoluted tubule?

    Aldosterone.

    renal physiology hormone

  • What is the role of aldosterone in the distal convoluted tubule?

    Regulates sodium reabsorption based on the body's needs.

    renal physiology hormone

  • Where does the final concentration of filtrate occur?

    Late distal convoluted tubule and collecting duct.

    renal physiology kidney

  • What factors influence water reabsorption in the collecting duct?

    • Osmotic gradient in the medulla
    • Vasopressin (ADH)
    renal physiology hormone

  • What is vasopressin?

    Antidiuretic hormone (ADH).

    renal physiology hormone

  • Where is ADH released from?

    Posterior pituitary gland.

    renal physiology hormone

  • What triggers the release of ADH?

    Decrease in the amount of water in the body.

    renal physiology hormone

  • How does ADH affect the permeability of the distal convoluted tubule and collecting duct?

    Controls whether the walls are permeable or impermeable to water.

    renal physiology hormone

  • What happens when ADH levels are high?

    • Increased permeability to water
    • Increased reabsorption of water
    • Low-volume concentrated urine
    renal physiology hormone

  • What happens when ADH is absent?

    • Walls become impermeable to water
    • Large volume of dilute urine
    renal physiology hormone

  • What determines the production of ADH?

    State of body hydration.

    renal physiology hormone

  • What ultimately determines urine volume and concentration?

    Chemical balance in the body.

    renal physiology kidney

  • Summarize the effect of increased body hydration on ADH and urine volume.

    ↑ Body Hydration = ↓ ADH = ↑ Urine Volume

    renal physiology hormone

  • Summarize the effect of decreased body hydration on ADH and urine volume.

    ↓ Body Hydration = ↑ ADH = ↓ Urine Volume

    renal physiology hormone

  • What is the primary function of the collecting duct?

    To fine-tune the concentration of urine by reabsorbing water.

    renal physiology kidney

  • How does the osmotic gradient in the medulla contribute to water reabsorption?

    It creates a concentration difference that drives passive reabsorption of water when ADH is present.

    renal physiology kidney

  • Explain the relationship between aldosterone and sodium concentration in the body.

    Aldosterone is released in response to low sodium levels, promoting sodium reabsorption in the distal tubule.

    renal physiology hormone

  • What is the significance of the ascending loop being impermeable to water?

    It allows for the reabsorption of solutes without water, creating a dilute filtrate.

    renal physiology kidney

  • How does ADH influence the aquaporins in the collecting duct?

    ADH increases the insertion of aquaporins into the collecting duct cell membranes, increasing water permeability.

    renal physiology hormone

  • What is the impact of alcohol consumption on ADH levels and urine production?

    Alcohol inhibits ADH release, leading to decreased water reabsorption and increased urine production.

    renal physiology hormone

  • Describe the role of the countercurrent multiplier system in maintaining the medullary osmotic gradient.

    It uses the loop of Henle to create a concentration gradient, with high solute concentration in the medulla.

    renal physiology kidney

  • How does the body respond to dehydration in terms of ADH and urine concentration?

    Dehydration increases ADH release, leading to increased water reabsorption and concentrated urine.

    renal physiology hormone