Urinary System L 2, 3 Tubular Reabsorption & secretion
Prof. Madaya Dr Than Kyaw1, 8 October 2012
Reabsorption• For reabsorption a substance - must pass from tubular lumen through tubular epithelial cells - diffuse through interstitial fluid (ISF) - enter the capillarySecretion• For secretion a substance - must leave the capillary - diffuse through ISF - pass thru tubular epithelial cells into the lumen
Tubular Reabsorption & secretion
Reabsorption and secretion
Reabsorption of Na+, Cl-, glucose and A/A
• Substances important for body functions (e.g. glucose, a/a) enter tubular fluid by filtration at the glomerulus
• Due to their relatively small molecular size - pass easily thru’ glomerular membrane
• Concentration in the filtrate and plasma the same• If they are not returned (not reabsorbed) to blood – they are
excreted in the urine and lost from the body
Proximal convoluted tubules
Glucose or A/A in
Tubular lumen
Diffuse into peritubular capillary
Transport coupled with transport of Na
Na+ + glucose or
Na+ +A/A
Active transport (energy used - Na+ -K + -APTase)
Carrier protein
No additional energy needed
for glucose or A/A
Proximal convoluted tubules - the longest part; make up most of the renal cortex - cuboidal cells with a luminal border modified with microvilli (brush border) providing large surface area - important substances like glucose and amino acids - 100% reabsorption
• Once inside the tubular cell – A/A or glucose uncoupled from the carrier
• Diffuse basal or lateral border to ISF → capillaries• Na+ – actively transported from tubular epithelial cells to ISF
and then to capillaries• The carrier protein return to its previous conformation to
transport more glucose /amino acids/ Na+
• Unlike other tissues, glucose in the renal tubules and instestine is actively and continually transported even though its concentration in the lumen is minute; thereby loss of glucose from the body is prevented by active transport (uphill)
• Active transport needs both carrier and energy
Reabsorption and secretion
Reabsorption and secretion
Transport of Na+ from tubular lumen into the tubular epithelial cell and its co-transport with glucose.
Energy requirement is provided by the Na+ -K + -APTase (sodium pump)
Protein channel: - pores; contain a single or a cluster of proteins; - specificity for certain substances or restrictive due to the size. - Water easily diffuses through protein channel.
Protein channel (carrier protein):
- Transported molecule enters the carrier protein channel and bind with the receptor. After binding the carrier protein undertakes conformational change to open the channel on the opposite side.
- Then transported molecule is released and carrier protein returns to original conformation for transport of another molecules.
Reabsorption and secretion
Some low molecular weight substances - bound to plasma proteins - retained in the blood plasma E.g. - calcium, iron, hormones (e.g. thyroxine) - only a small fraction of them that are unbound pass through
Reabsorption of Water and Urea
Concentration of water in the lumen
Water reabsorbed by
osmosis into the ISF and
capillaries
Low HP
Colloidal osmotic Pressure
Absorption favoured by
• Na+, Cl- , • 65% water,• 85 – 90% HCO3
• 100% glucose, amino acids• Other substances
Removal from lumeninto ISF and capillaries
Some substances are removed (secreted)- from blood through the peritubular capillary network- into the distal convoluted tubules or collecting ducts.
- These include: H+ ions, K+, NH3 , creatinine, and drugs. - H+ ions – secreted throughout the length of nephron tubule
(except thin loop of Henle); - coupled with reabsorption of - K+ - secreted at DCT and CT and CD; - coupled with reabsorption of Na+
- NH3 - its secretion rate depends on acid-base equilibrium of body fluid
- Urine is a collection of substances that have not been reabsorbed during glomerular filtration or tubular secretion.
Tubular secretion
TM = Substances associated with membrane transporters (carrier or active transport) for reabsorption have a maximum rate at which they can be removed – e.g. glucose
Tubular Transport Maximum (TM)
Renal threshold = the plasma concentration of a substance when it first appears in the urine
- TM for the substance is exceeded its limit.
Renal threshold of gucose and diabetes mellitus
Deficient or lack of insulin
Glucose in the tubules & urine
(Glucosurea)
Impaired movement of glucose from plasma into body cells
↑plasma concentration of glucose
↑ Plasma and tubular load exceeds availability of carrier
molecules for glucose transport and reabsorption
1
2
3
Above renal threshold
Renal threshold of gucose and diabetes mellitus
Glucose contributes effective osmotic pressure
of the tubules
Water in the tubules & hence
in the urine
↑ Volume of water in the tubules &
hence in the urine
Frequent urinationDrink more water
Glycosuria (glucosuria): presence of glucose in urinePolyuria: frequent urinationPolydipsia : increased thirst Polyphagia : increased hunger
Osmotic diuresis
Renal counter-current mechanisms
1. Countercurrent multiplier system2. Countercurrent exchanger system
Countercurrent multiplier system: It is the process by which a progressively
increasing osmotic gradient is formed as a
result of countercurrent flow.
1. Descending limb of loop of Henle
2. Thin segment of ascending limb3. Thick segment of ascending limb4. Cortical collecting duct5. Outer medullary collecting duct6. Inner medullary collecting duct
Parts involved in countercurrent multiplier
system
• Impermeable to solutes but permeable to water
• Water diffuses by osmosis to the higher osmotic pressure of ISF
• Solute conc. (mainly NaCl) increasing while approaching hair-pin turn of loop of Henle
Countercurrent multiplier system
1
2• Thin segment of ascending
limb – permeabe for NaCl but impermeable to water
• Water remains in the tubule and NaCl difuses (due to concentration gradient) to ISF
• Thick segment of ascending limb – active transport of NaCl to the ISF
• Water continues to be retained• Osmolality of tubular fluid
entering descending limb is 300 mOsm/kg H2O
• Tubular fluid leaving ascending limb and entering distal tubule – diluted (osmolality 185 mOsm/kg H2O
Countercurrent multiplier system
3
Vertical osmotic gradient in ISF
Is lower in outer medulla and higher in inner medulla and at hair-pin turn; established and maintained bya) continued active transport of NaCl by thick segment of ascending imbb) conc of tubular fluid in the descending limbc) passive diffusion of NaCl from the lumen of thin segment of ascending limb into the inner medullary ISF
Countercurrent multiplier system
Countercurrent exchanger system
– It is a countercurrent system in which transport between
inflow and outflow is entirely passive.
– Vasa recta
- is a countercurrent exchanger
- Permeable to water and solutes throughout their length
Countercurrent exchange in vasa recta
1. Blood enter with 300 mOsm/kg water
2. Descends through increasingly hypertonic peritubular fluid in medulla.
3. Water diffuses out. Solutes diffuses in until hair-pin turn is reached.
4. Blood then ascents through decreasing hypertonicity and water diffuses in and solute diffuses out.5. Blood returns to the cortex. Milliosmolality is only slightly higher than when it entered Vasa recta.
Countercurrent exchanger system
In descending limb – water drawn by osmosis from vasa recta to ISF (hyperosmotic created by countercurrent multiplier)
– Solutes diffuse from ISF to vasa rectaIn ascending limb – solutes diffuse back into ISF- Water is drawn by osmosis back into vasa recta
- The function of countercurrent exchange- to retaine solutes in the ISF of medulla
- Increase rate of blood flow in vasa recta – reduce time for diffusion of solute from ascending limb back to ISF – gradual loss of solute from medulla – medullary washout
- This is prevented by low blood flow - 10 to 20% of kidney blood flow
Role of urea
Urea
- Contributes high solute concentration in ISF
- Recirculation of urea assists countercurrent multiplier system
and osmotic gradient
- Urea excretion is maintained almost at the same level
whether the urine is dilute or concentrated.
Concentration of Urine
ADH and Osmoregualtion
- Epithelial cells of CT, CD – variable permeability depending on ADH amount (Post Pit)
- ADH - permeability of these cells for water- ADH secretion - significant in 2% changes in plasma osmolality- Degree of ECF dehydration – Osmoreceptor cells in hypothalmus- Hyperosmolality - secretion of ADH
- ADH acts on cortical and medullary CDs- water reabsorption
Thirst center in hypothalamus - also stimulated by hyperosmolality
Relationship among hypothalamus, posterior pituitary and kidney in the regulation of extracellular dehydration
Control of hyperosmolality
Hypothalamus regulated
Thirst – predominant factor for correction of hyperosmolality
Diabetes insipidus
- Water is not reabsorbed in the CTs and CDs – excreted as urine- Hypotonic tubular condition – absence or severely decreased
amount of ADH- k/s diabetes insipidus- Animal with this condition
- polyuria ( excess amount of water in urine)- polydipsia (excessive thirst and excessive water intake)- urine formed - dilute, lower than normal specific gravity
What are the differences between diabetes melitus and diabetes insipidus
Diabetes insipidus and diabetes mellitus
What are the differences and similarities between diabetes mellitus and diabetes insipidus
Particular Diabetes insipidus Diabetes mellitus
cause Lack or deficient ADH +ce of glucose in urine
Osmotic diuresis -ce +ce
Polyuria + +
Polydipsia + +
Thirst + +
Specificiific gravity ow High
Urine content No glucose glucose
Urine concentration
Normally -• Urine concentration may vary depending on multiple factors• In extreme cases in domestic animals
– urine-to-plasma osmolal ratio may approach (2400:300); the urine concentration is 8 times that of plasma
• In desert rodents – urine-to-plasma ratio (16:1)-- extreme adaption for body water conservation-- water - not available; mostly gained water – metabolic-- water loss minimized for survival
Acute renal failure
- Normal : high O2 supply and high O2 use in renal tissue
- Persistently low renal perfusion (low renal blood supply as in shock or renal damage) = decrease in GFR over hours or days = causes acute renal failure
Chronic renal failure- If renal failure (impaired GFR) remains for months
Renal failure and reduced urine concentration
Renal failure and reduced urine concentration
Mostly found in chronic renal diseases - ↓ concentrating ability
• More solute remained in functional nephrons - contribute osmotic diuresis
• Hypertonicity in medullary ISF not maintained due to- loss of medullary t/s or ↓ blood flow in the vasa recta
- ↓Na and Cl transport from the thick segament of ascending limb of loop of Henlen
• Damage to cells in CTs and CDs – making less responsive to ADH
Reduced urine concentration Concentration failure