Renal

Question 1

Major renal functions

Answer 1

Regulation of water and electrolyte balance.
Hydrogen ion regulation (long term regulation of pH)
Excretion of wastes (metabolic and bio active substances)
Regulation of arterial blood pressure
Regulation of RBC production due to release of EPO
Regulation of vit D production
Gluconeogenesis

Question 2

Anatomy of kidneys and urinary system

Answer 2

Medulla (external surface)
Cortex (internal surface, houses nephrons, urine drains into renal pelvis and down into ureter)
Parietal fat is protective mechanism
Renal corpuscle:
- glomerulus- bed, tuff of capillaries
- Bowmans capsule- surround glomerulus for protection
Proximal tubule- high reabsorption
Descending limb/ ascending limb (loop of Henle)
Collecting duct- more towards bladder

Question 3

Vascular elements of kidneys

Answer 3

Two sets of capillaries: glomerular capillaries, peri tubular capillaries

Unique blood vessel arrangement: renal artery- small arteries- afferent arterioles- glomerulus (capillaries) - efferent arterioles- peri tubular capillaries / vasa recta- veins

Question 4

Nephron function

Answer 4

Glomerulus supplied blood by an afferent arteriole
Renal corpuscle forms a plasma derived fluid filtrate
Around 20% of plasma volume filters into capsule, remaining blood leaves the glomerulus by the efferent arteriole
Filtration barrier ensures filtrate is free of cells and most proteins
Filtrate leaves Bowmans capsule and enters the tubule
Fluid reaching end of nephron combines in the collecting ducts
Fluid drains from end of collecting duct into renal pelvis which is continuous with the ureter

Question 5

Renal processes

Answer 5

Glomerular filtration
- filtration of fluid from plasma
- initial filtrate has same composition as plasma but does not contain cells and most plasma proteins
Once in nephron tubule, filtrate composition adjusted by:
- tubular reabsorption: movement of substances from tubule to peritubular capillary plasma
- tubular secretion: movement of substances from peritubular capillary plasma to tubule

Question 6

Purpose of filtration

Answer 6

• clears body of wastes and foreign substances rapidly
• allows constant and rapid adjustments to maintain individual substance balance (eg. Maintain ion levels at set point)
• retain 100% glucose
• 50% urea
• more secretion than filtration of penicillin (try to get rid of drugs)

Question 7

Nephron filtration

Answer 7

• osmolarity in glomerulus is the same as plasma, but decreases at the end of loop of Henle to ~100- higher the osmolarity, the higher the urine concentration
• bulk of reabsorption occurs in proximal tubule all the way up to Distal tubule
• collecting duct is where fine tune filtration occurs

Question 8

Renal blood flow

Answer 8

Kidneys receive 1L/ min
All of this blood flows through glomeruli in cortex. The vast majority continues on via efferent arterioles to peritubular capillaries in cortex and then into renal venous system.
The vasculature of the cortex is unusual due ton2 sets of arterioles and 2 sets of capillaries

Question 9

Renal blood flow

Answer 9

RBF = change in pressure / resistance

R varied by changing arteriolar radii. Normally afferent and efferent are equal, but not always.
If either afferent or efferent constrict- decreased RBF
If either afferent or efferent dilate- increased RBF

Question 10

Glomerular filtration barriers

Answer 10

Filtration structures; renal corpuscles (glomerulus and Bowmans)
Filtrate composition = plasma, except filtration barrier prevents entry of RBC and proteins.
3 layers: fenestrated capillaries, basement membrane, podocytes- foot processed extensions
Each of these surfaces is neg charged so prevents entry of neg, LARGE charged proteins

Question 11

Glomerular filtration rate

Answer 11

Favouring filtration:
-Pgc (glomerular capillary BP) chief force pushing fluid across filtration membrane. Varied to control GFR
~55mmHg
Opposing filtration:
- piegc- osmotic force due to protein in plasma ~30mmHg
- Pbs - fluid pressure in Bowmans space ~15mmHg

Therefore net filtration pressure is 15

Question 12

Regulation of GFR: autoregulation

Answer 12

An intrinsic mechanism that constricts/ dilates afferent arterioles to offset and rise/ fall in BP and prevent change in Pgc
- important to maintain GFR and prevent damage to structures
When BP increases, GFR does not change from 80-180mmHg- kept constant in this range

Question 13

Autoregulation: myogenic mechanism

Answer 13

• vascular smooth muscle tends to contract when stretched (stretch sensitive ion channels open- depolarisation- voltage gated Ca2+ channels open- Ca2+ contracts smooth muscle
• if BP increases, afferent arterioles constrict and restrict blood flow into glomerulus, restricting increases Pgc and increases GFR
• if BP decreases, afferent arterioles dilate and promote blood flow into glomerulus, restricting decreases Pgc, decreases GFR

Question 14

Tubuloglomerular feedback mechanism

Answer 14

Local control pathway in which fluid flow through the nephron tubule influences GFR
Directed by macula densa cells (salt detectors)
- as filtration rate in an individual nephron increases, increased NaCl that escapes reabsorption (insufficient time). Increased filtrate (NaCl). Macula densa cells increase NaCl of filtrate and release a vasoconstrictor chemical. Vasoconstriction of afferent arteriole reduced Pgc and therefore GFR decreases

Question 15

Extrinsic control of GFR

Answer 15

Local controls for GFR can be overridden my sympathetic nerve fibres of autonomic NS due to importance of kidneys in maintaining arterial blood pressure.

Question 16

Tubular reabsorption

Answer 16

Some solutes and water move into and out of epithelial cells (transcellular transport). Other solutes move through junctions bw epithelial cells (paracellular pathway).

• Na+ reabsorbed by active transport
• electrochemical gradient drives anion reabsorption (Cl-)
• increased osmolarity of ECF decreases osmolarity of filtrate
• permeable solutes are reabsorbed by diffusion through membrane transporters or by the paracellular pathway. Therefore Na+ is the driving force

Question 17

Transport maximums: saturation of carriers

Answer 17

Diabetics can have glucose in urine. High level of blood glucose- more in filtrate - require specific transporters. If too much glucose, not enough transporters.

Question 18

Reabsorption of Na+, Cl- and water

Answer 18

1. Reabsorption of Na+ is mainly active, transcellular process driven by Na+/K+ATPase pumps in the basolateral membrane
2. Reabsorption of Cl- is both passive (paracellular) and active (transcellular), but id couple with the reabsorption of Na+ (due to electrical gradient created by Na+ reabsorption)
3. Reabsorption of water is by osmosis and is secondary to reabsorption of solute (particularly NaCl), if water directly followers Na+ - coupled

Question 19

Movement of Na+ into tubular epithelial cells

Answer 19

1. Intracellular concentration of Na+ is lower than extra cellular.
   Na+ moving down its electrochemical gradient uses SGLT protein to pull glucose into the cell against its concentration gradient.
2. Glucose diffuses out of the basolateral side of the cell using the GLUT protein
3. Na+ is pumped out by Na+k+ ATPase

Various mechanisms of this Na+ downhill movement across luminal membrane exist. Luminal entry mechanism varies from segment to segment (of nephron tubule) depending on which channels and/ or transport proteins are present

Question 20

How does water cross tubular epithelium

Answer 20

Three possible routes:

• simple net diffusion through the lipid bolster
• through aqua pores in plasma membrane
• through tight junctions in cells (paracellular movement)

Amount of H2O reabsorption depends on osmotic gradient and the H2O permeability of the region

Question 21

Tubular reabsorption: proximal tubule

Answer 21

-65% of sodium and chloride reabsorbed here
- virtually all nutrients reclaimed
- cations reclaimed
- bicarbonate
Osmolarity of filtrate at the end of proximal tubule remains at 300mOsM due to Iso-osmotic volume reabsorption (equal portions of solute and water reabsorption)
High surface area

Question 22

Tubular reabsorption: loop of Henle

Answer 22

Na+ and water NOT coupled
Descending limb: water only, less reabsorbed than solute reabsorption in ascending Limb.
Ascending limb: reabsorption of Na+ (active transport) and other solutes but NOT H2O (not water permeable)

Filtrate at end of loop is hypoosmotic (~100mOsM). Medullary interstitium is hyper osmotic (up to 1200mOsM surrounding juxtamedullary nephrons). Vital to the ability to form dilute or concentrated urine.

Question 23

Tubular reabsorption: distal tubule and collecting ducts

Answer 23

• by the time filtrate reaches distal tubule, 90% of NaCl and 75% of water originally filtered already reabsorbed
• most reabsorption from distal regions of DVT onwards depends on body’s requirements (at the time) and is regulated by hormones

Question 24

Kidney concentrates urine

Answer 24

ADH secreted into blood from brain- targets collecting ducts of kidney - if no ADH- water is not permeable to membrane.
ADH binds to receptor on luminal membranes- activates pathway to allow aqua pores to be inserted in luminal membrane of collecting ducts, therefore increased ADH means increased water reabsorption.
This is able to occur due to large osmotic gradient caused by hyperosmotic medullary interstitial fluid

Question 25

The renal countercurrent multiplier

Answer 25

Comprised of loops of Henle of juxtamedullary nephrons and vasa recta. Long loops of Henle create the osmotic gradient
The vasa recta preserve the gradient and reclaim water.
The collecting ducts use this gradient to adjust urine concentration.
Direction of fluid in loop of Henle is opposite to blood flow in vasa vecta.
Counter current exchanger - exchange bw filtrate in lumen and blood flow in vasa recta.
Water being transferred from descending to ascending vasa vecta, as moves in ECF due to saltiness- but then moves back into ascending limb

Question 26

Renal control of Na+ and water excretion

Answer 26

• maintain body fluid volume
• maintain osmolarity
• maintain arterial BP
  Regulation of blood pressure effectors:
• heart
• peripheral arterioles (peripheral resistance)
• large veins
• kidneys (vary output of salt and water)

Question 27

Change in arterial pressure speeds

Answer 27

Fast- baroreceptors (cardiac and vascular actions). Restoration of pressure within seconds

Intermediate- renal actions (peripheral resistance) - restoration of pressure in minutes

Slow- prolonged renal actions (exertion of salt and water) restoration in hours to days

Question 28

Arterial pressure change, vascular resistance

Answer 28

Kidneys have baroreceptors (intrarenal baroreceptors)- part of kidneys granular cells (located around afferent arterioles) which sense renal afferent arteriolar pressure.
Juxtaglomerular cells secrete renin into blood.
Triggers renin angiotensin system (RAS), impacts on vasculature and blood volume.
- liver constantly produced angiotensinogen in plasma
- renin cleaves off portion of angiotensinogen to form angiotensin 1 (small peptide)
- encounters angiotensin converting enzyme, converts AGN1 to AGN11 in plasma
- increased BP in a few ways

Question 29

Stimulation of production of renin

Answer 29

• decreased BP directly signals granular cells of afferent arteriole to produce renin
• decreased BP signals CV control centre, increases sympathetic pathway, causes granular cells of affairs to arterioles to produce renin
• decreased BP causes decreased GFR, decreases NACL across macula densa of distal tubule - stimulates paracejnes and then granular cells

Question 30

Decreased BP increase renin

Answer 30

1. Activity of renal sympathetic nerves- part of cardiovascular baroreceptors reflex- thus there is tight coordination between short and intermediate reflexes
2. Detect decrease in afferent arteriolar BP
3. Decreased NACL in macula densa cells due to decreased GFR due to drop on BP

Question 31

Long term renal control of blood volume

Answer 31

• adjustment to GFR and thus conservation of body fluid
  Direct effect of decreased arterial BP: lower than autoregulatory limit- decreased glomerular capillary blood pressure, decreased GFR, decreased excretion of sodium and water
• adjustment to NA reabsorption by aldosterone - increased NA reabsorption from distal region of Doral tubule and cortical ducts. NA reabsorption increases water retention (must be permeable) and blood volume - increased blood vol increases pressure (stimulated by ANG2) - aldosterone is lipid soluble- induced gene expression and protein synthesis of NA/K channels/
  pumps (basolateral membrane) acts slowly. Increases NA reabsorption and K secretion
• adjustment to water reabsorption by ADH- caused by plasma osmolarity and reduced blood pressure - more water to reclaim: ADH increases permeability of collecting ducts, allows increased water reabsorption for increased blood vol

Question 32

Pharmacological manipulation of RAS

Answer 32

• ace inhibitors

- angiotensin 2 by blocking recent sites on target tissue

Question 33

Renal response to increased plasma osmolarity

Answer 33

Osmolarity is monitored by osmoreceptors found in hypothalamus
If plasma osmolarity exceeds 280mOsm:
- osmoreceptors trigger posterior pituitary to secrete ADH into circulation
- increased plasma ADH
- increased collecting duct water permeability (insertion of aquaporins in luminal membrane)
- increased water reabsorption by collecting ducts (via osmosis due to hyperosmotic medulla)
- therefore decreased plasma osmolarity and urine low in volume, concentrated