Download 15. Renal System Part 2

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Transcript 
Proximal Convoluted Tubule
• Active Reabsorption
– Nutrients (glucose, amino acids, Vitamins)
– Ions (K+, Na+, Cl-, Ca2+) ~70% of Filtrate is
– Small plasma proteins reabsorbed in PCT
– Some urea and uric acid
Question: How are these Reabsorbed?
Na+ is Actively
Reabsorbed:
Reabsorption of Na+ :
First – simple diffusion:
Then – 1o active transport:
Na+ linked 2o Active Transport
Symport with:
– Glucose
– Amino acids
– Ions (e.g., Ca2+)
Passive Transport of Water:
– As Na+ pumped out, H2O follows by osmosis.
(passive)
Passive Transport of Urea:
– As other solutes leave lumen, [urea] higher
than ECF, thus passively diffuses into ECF.
Transcytosis of Proteins:
– Small proteins can get into filtrate, due to size
they are reabsorbed via vesicular transport.
Reabsorption
of Urea
Transporter Characteristics
– Specificity:
glucose, fructose, tyrosine, valine, etc, all have own carriers.
– Competition:
maltose instead of glucose – takes a seat, but not transported.
– Saturation (# of carriers):
limited # of carriers to transport solutes back into body.
A substance can exceed renal threshold,
e.g., glucosuria.
H2O Reabsorption – Loop of Henle
a key site.
• First, Na+ transported out of filtrate.
• Osmolarity of ECF gets higher.
• Deeper into medulla, more H2O drawn out.
• Filtrate becomes Very concentrated!
• Collecting duct also a key site for H2O
reabsorption – (role of ADH).
Ascending Loop of Henle
• Region is impermeable to H2O.
• Thus, H2O can no longer leave filtrate in
this region, so Osmolarity becomes lower
again at start of DCT.
Secretion – DCT a key site.
• Active Transport into nephron tubules
+
+
e.g., K , H and HCO3
• Fine-tuning - eliminate unwanted items.
• This filtrate in tubules is destined to be
urine unless reabsorbed in collecting ducts.
Final Modification: Collecting Ducts
• Reabsorption of Na+
• Reabsorption of H2O
• Under Endocrine Control – ADH (vasopressin)
• After collecting duct, filtrate now called
urine (no longer modified).
Mictruition Reflex
Autoregulation of Renal System
Renin-Angiotensin-Aldosterone
Liver
Lungs
Kidneys
Adrenal
Cortex
___________
_________________________________
_____
______________
(inactive)
____________
(activated)
_______________
(active)
Kidneys
_______________________
(_____________)
Na+ _______
Vasoconstriction
Reabsorption of H2O
Thirst Stimulation
H2O _______
Liver
Lungs
Kidneys
Adrenal
Cortex
Aldosterone
Angiotensin Converting Enzyme (ACE)
Renin
Angiotensinogen
(inactive)
Angiotensin I
(activated)
Angiotensin II
(active)
Kidneys
Anti Diuretic Hormone (ADH)
(Vasopressin)
Na+ retention
Vasoconstriction
Reabsorption of H2O
Thirst Stimulation
H2O retention
Comparison of Fluids
Substance
(parameter)
Volume
Rate
pH
Osmolarity
Cells
Na+, K+
Glucose
Large ProSmall ProUrea
Blood
Plasma
Filtrate
Urine
Renal Failure
When kidney function disrupted to the point
they are unable to perform regulatory and
excretory functions sufficient to maintain
homeostasis.
Acute – sudden onset with rapid reduction in urine formation
(less than 500ml/day minimum being excreted).
Chronic – slow, progressive, insidious loss of renal function.
Up to 75% of function can be lost before detected.
Normal Healthy Kidney
Polycystic kidneys
Enlarged Polycystic kidneys (16 to 18 pounds combined).
Variety of Causes of Renal Failure:
1. Infectious organisms.
- Blood borne microbes
- UTI’s
2. Toxic agents.
- lead, arsenic, pesticides, additives, medications
- long-term exposure to high aspirin doses
3. Inflammatory immune response (allergic).
- glomerulonephritis, sepsis
- e.g., after strep throat (streptoccocus)
Variety of Causes:
4. Obstruction of urine flow.
- Kidney stone (calcium oxalate, uric acid crystals)
- Tumors
- Enlarged prostate gland
All create back pressure, decreasing GFR
5. Insufficient renal blood flow.
- 2o to heart failure
- Hemorrhage (e.g. shock)
- Atherosclerosis
Leads to inadequate
Filtration pressure
Potential Ramifications:
1. Uremic Toxicity
- Caused by retention of toxins/waste products in blood.
2. Metabolic Acidosis
- From inability of kidneys to secrete H+.
3. Potassium (K+) retention
- Inability to secrete K+ (effects RMP).
4. Na+, Ca2+ and phosphate and Imbalances
- Inability of kidneys to regulate ion reabsorption
and secretion.
5. Loss of plasma proteins
- Result of increased leakiness of glomerulus.
6. Anemia
- Inadequate erythropoiten production.
7. Depressed immune system
- Increased toxic waste and acidic conditions.
Possible Treatments for Renal Failure:
Stop or Treat the Cause
Dialysis
Kidney Transplant
Overall Processes of the Nephron
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