1. Chapter 26 Urinary System
2. Urinary System Functions Removal of metabolic waste products from the blood and their excretion in the urine
Removal of foreign chemicals from the blood and their excretion in the urine.
Regulation of
Blood volume
Concentration of blood solutes: Na+, Cl-, K+, Ca2+, HPO4-2
Acid-base balance
Blood cell synthesis
Production of hormones (EPO) and enzymes (Renin)
Production of 1,25-dihydroxyvitamin D3
3. Nephron Functions: Overview
9. Filtration Movement of fluid, derived from blood flowing through the glomerulus, across filtration membrane
Filtrate: water, small molecules, ions that can pass through membrane
Pressure difference forces filtrate across filtration membrane
Renal fraction: part of total cardiac output that passes through the kidneys. Varies from 12-30%; averages 21%
Renal blood flow rate: 1176 mL/min
Renal plasma flow rate: renal blood flow rate X fraction of blood that is plasma: 650 mL/min
Filtration fraction: part of plasma that is filtered into lumen of Bowmans capsules; average 19%
Glomerular filtration rate (GFR): amount of filtrate produced each minute. About 125 ml/min = 180 L/day (45 gallons/day!!)
Average urine production/day: 1-2 L. Most of filtrate must be reabsorbed
11. Filtration Pressure
12. Glomerular Filtration Rate (GFR) Defined as: The volume of filtrate produced by both kidneys per min
Averages 115 ml/min in women; 125 ml/min in men
Totals about 180L/day (45 gallons)
So most filtered water must be reabsorbed or death would ensue from water lost through urination
GFR is directly proportional to the NFP
Increase GFR leads to an increase in NFP
Decrease in GFR leads to a decrease in NFP
Changes in GFR normally result from changes in
glomerular blood pressure (Gcp)
13. Regulation of GFR�Glomerular Filtration Rate If the GFR is too high:
Fluid flows through tubules too rapidly to be absorbed
Urine output rises
Creates threat of dehydration and electrolyte depletion
If the GFR is too low:
Fluid flows sluggishly through tubules
Tubules reabsorb wastes that should be eliminated
Azotemia develops (high levels of nitrogen-containing substances in the blood)
Only way to adjust GFR moment to moment is to change glomerular blood pressure
15. Renal Autoregulation Renal autoregulation: the ability of nephrons to adjust their own blood flow and GFR
IF there were no renal autoregulation and MAP rose from 100 mmHg to 125 mmHg, urine output would rise from 1.5 L/day to 45 L/day!!
Two mechanisms used to renal autoregulate:
Myogenic Response
When average BP drops to 70 mm Hg afferent arteriole dilates
When average BP increases, afferent arterioles constrict
Allows kidney to maintain a constant GFR over wide range of BPs
Tubuloglomerular feedback
Increased flow of filtrate sensed by macula densa (MD)
Macula densa signals afferent arterioles to constrict
16. Extrinsic Control of GFR When the sympathetic nervous system is at rest:
Renal blood vessels are maximally dilated
Autoregulation mechanisms prevail
Under stress:
Norepinephrine is released by the sympathetic nervous system
Epinephrine is released by the adrenal medulla
Afferent arterioles constrict and filtration is inhibited
Note: during fight or flight blood is shunted away from kidneys
The sympathetic nervous system also stimulates the renin-angiotensin mechanism
17. Sympathetic Effects Sympathetic activity constricts afferent arteriole
Helps maintain BP & shunts blood to heart & muscles
19. Tubular Reabsorption�(In Reference to Previous Slide) Filtered loads are enormous
E.g. only 40 L of water in body, but 180 L filtered per day
Reabsorption of waste products is relatively incomplete
Thus, large fractions of their filtered load are excreted in the urine
Reabsorption of most useful plasma components is relatively complete
Thus, amounts excreted in urine represent very small fraction of filtered load
20. Tubular Reabsorption: Overview Tubular reabsorption: occurs as filtrate flows through the lumens of proximal tubule, loop of Henle, distal tubule, and collecting ducts
Processes used in reabsorption include:
Diffusion
Facilitated diffusion
Active transport
Cotransport
Osmosis
Reabsorbed substances are transported to interstitial fluid and reabsorbed into peritubular capillaries.
21. Tubular Reabsorption and Secretion
23. Peritubular Capillaries Blood has unusually high COP here, and BHP is only 8 mm Hg
This favors reabsorption
Water absorbed by osmosis and carries other solutes with it (solvent drag)
24. Reabsorption of Salt & H20 The PCT returns most molecules & H20 from filtrate back to peritubular capillaries
About 180 L/day of ultrafiltrate produced; only 12 L of urine excreted/24 hours
Urine volume varies according to needs of body
Minimum of 400 ml/day urine necessary to excrete metabolic wastes (obligatory water loss)
25. PCT Filtrate in PCT is isosmotic to blood (300 mOsm/L)
Thus reabsorption of H20 by osmosis cannot occur without active transport (AT)
Is achieved by AT of Na+ out of filtrate
Loss of + charges causes Cl- to passively follow Na+
Water follows salt by osmosis
27. Glucose & Amino Acid Reabsorption Filtered glucose & amino acids are normally 100% reabsorbed from filtrate
Occurs in PCT by carrier-mediated cotransport with Na+
Transporter displays saturation if ligand concentration in filtrate is too high
Level needed to saturate carriers & achieve maximum transport rate is transport maximum (Tm)
Glucose & amino acid transporters don't saturate under normal conditions
28. Tubular Maximum Tubular Maximum (TM: Defined as
Maximum rate at which a substance can be actively absorbed
Each substance has its own tubular maximum
Normally, glucose concentration in the plasma (and thus filtrate) is lower than the tubular maximum and all of it is reabsorbed.
In diabetes mellitus, tubular load exceeds tubular maximum and glucose appears in urine.
Urine volume increases because glucose in filtrate increases osmolality of filtrate reducing the effectiveness of water reabsorption
29. Significance of PCT Reabsorption 65% Na+, Cl-, & H20 is reabsorbed in PCT & returned to bloodstream
An additional 20% is reabsorbed in descending limb of the loop of Henle
Thus 85% of filtered H20 & salt are reabsorbed early in tubule
This is constant & independent of hydration levels
Energy cost is 6% of calories consumed at rest
The remaining 15% is reabsorbed variably, depending on level of hydration
30. Medullary Concentration Gradient In order to concentrate urine (and prevent a large volume of water from being lost), the kidney must maintain a high concentration of solutes in the medulla
Interstitial fluid concentration (mOsm/kg) is 300 in the cortical region and gradually increases to 1400 at the tip of the pyramids in the medulla
Maintenance of this gradient depends upon
Functions of loops of Henle
Vasa recta flowing countercurrent to filtrate in loops of Henle
Distribution and recycling of urea
31. Descending Limb Is permeable to H20
Is impermeable to salt
Because deep regions of medulla are 1400 �mOsm, H20 diffuses out of filtrate until it equilibrates with interstitial fluid
This H20 is reabsorbed by capillaries
32. Ascending Limb LH Has a thin segment in depths of medulla & thick part toward cortex
Impermeable to H20
Permeable to salt
Thick part ATs salt out of filtrate
AT of salt causes filtrate to become dilute (100 �mOsm) by end of LH
33. AT in Ascending Limb NaCl is actively extruded from thick ascending limb into interstitial fluid
Na+ diffuses into tubular cell with secondary active transport of K+ and Cl-
34. Na+ is AT across basolateral mem-brane by Na+/ K+ pump
Cl- passively follows Na+ down electrical gradient
K+ passively diffuses back into filtrate AT in Ascending Limb continued
35. Countercurrent Multiplier System Countercurrent flow & proximity allow descending & ascending limbs of LH to interact in way that causes osmolarity to build in medulla
Salt pumping in thick ascending part raises osmolarity around descending limb, causing more H20 to diffuse out of filtrate
This raises osmolarity of filtrate in descending limb which causes more concentrated filtrate to be delivered to ascending limb
As this concentrated filtrate is subjected to AT of salts, it causes even higher osmolarity around descending limb (positive feedback)
Process repeats until equilibrium is reached when osmolarity of medulla is 1400
36. Vasa Recta Is important component of countercurrent multiplier
Permeable to salt, H20 (via aquaporins), & urea
Recirculates salt, trapping some in medulla interstitial fluid
Reabsorbs H20 coming out of descending limb
Descending section has urea transporters
Ascending section has fenestrated capillaries
37. Effects of Urea Urea contributes to high osmolality in medulla
Deep region of collecting duct is permeable to urea & transports it
38. Osmotic Gradient in the Renal Medulla
39. Urine Concentrating Mechanisms
41. Collecting Duct (CD) Plays important role in water conservation
Is impermeable to salt in medulla
Permeability to H20 depends on levels of ADH
42. ADH Is secreted by posterior pituitary in response to dehydration
Stimulates insertion of aquaporins (water channels) into plasma membrane of CD
When ADH is high, H20 is drawn out of CD by high osmolality of interstitial fluid
& reabsorbed by vasa recta
43. Formation of Concentrated Urine ADH-dependent water reabsorption is called facultative water reabsorption
ADH is the signal to produce concentrated urine
ADH stimulates formation of aquaporins in membrane of tubule cells. Increases water reabsorption from filtrate
The kidneys ability to respond depends upon the high medullary osmotic gradient
44. Urine Movement Hydrostatic pressure forces urine through nephron
Peristalsis moves urine through ureters from region of renal pelvis to urinary bladder. Occur from once every few seconds to once every 2-3 minutes
Parasympathetic stimulation: increase frequency
Sympathetic stimulation: decrease frequency
Ureters enter bladder obliquely through trigone. Pressure in bladder compresses ureter and prevents backflow
45. Composition and Properties of Urine Appearance
almost colorless to deep amber; yellow color due to urochrome, from breakdown of hemoglobin (RBCs)
Odor - as it stands bacteria degrade urea to ammonia
Specific gravity
density of urine ranges from 1.001 -1.028
Osmolarity - (blood - 300 mOsm/L) ranges from �50 mOsm/L to 1,200 mOsm/L in dehydrated person
pH - range: 4.5 - 8.2, usually 6.0
Chemical composition: 95% water, 5% solutes
urea, NaCl, KCl, creatinine, uric acid
46. Neural Control of Micturition
47. Micturition Reflex
48. Micturition Reflex Filling of bladder stimulates stretch receptors.
Stimulate parasympathetic fibers which:
inhibits contraction of the external urethral sphincter
stimulates contraction of the detrusor muscle of the bladder
49. Urine Volume Normal volume - 1 to 2 L/day
Polyuria > 2L/day
Oliguria < 500 mL/day
Anuria - 0 to 100 mL/day
50. Diuretics Effects
? urine output
? blood volume
Uses
hypertension and congestive heart failure
Mechanisms of action
? GFR
? tubular reabsorption
51. Kidney Diseases In acute renal failure, ability of kidneys to excrete wastes & regulate blood volume, pH, & electrolytes is impaired
Rise in blood creatinine & decrease in renal plasma clearance of creatinine
Can result from atherosclerosis, inflammation of tubules, kidney ischemia, or overuse of NSAIDs
Glomerulonephritis is inflammation of glomeruli
Autoimmune attack against glomerular capillary basement membranes
Causes leakage of protein into urine resulting in decreased colloid osmotic pressure & resulting edema
52. In renal insufficiency, nephrons have been destroyed as a result of a disease
Clinical manifestations include salt & H20 retention & uremia (high plasma urea levels)
Uremia is accompanied by high plasma H+ & K+ which can cause uremic coma
Treatment includes hemodialysis
Patient's blood is passed through a dialysis machine which separates molecules on basis of ability to diffuse through selectively permeable membrane
Urea & other wastes are removed Kidney Diseases continued
53. Diabetes Chronic polyuria of metabolic origin
With hyperglycemia and glycosuria
diabetes mellitus I and II, insulin hyposecretion/insensitivity
gestational diabetes, 1 to 3% of pregnancies
ADH hyposecretion
diabetes insipidus; CD ? water reabsorption
