L32 - Renal System PDF

Summary

This document provides a summary of the renal system and its mechanisms. It includes information on glomerular filtration, tubular reabsorption, and secretion. The information is presented in a lecture format and covers topics from learning outcomes to practical aspects.

Full Transcript

L32- RENAL SYSTEM

Dr.Pugazhandhi Bakthavatchalam
Assistant Professor of Anatomy and Physiology,
AUACAS, American University of Antigua
 LEARNING OUTCOMES

At the end of this session the student would be able
to:
Mechanism of urine formation: filtration,
reabsorption, secretion.
Factors affecting filtration rate, Ki (Filtration
Coefficient) and net filtration pressure (Starling
forces.)
Regulation of GFR by altering the forces.

24-Oct-24 2
Blood supply to the kidney
Approximately one-fourth (1200 ml) of systemic
cardiac output flows through the kidneys each minute

The cortex receives more than 90% of the blood that
perfused into the kidney, which is perfused at a rate
of about 500 ml/min per 100 gm tissue.
(100 times greater than resting muscle blood flow)

The remainder of the renal blood supply goes to the
capsule and the renal adipose tissue.

Some of the cortical blood then passes to the medulla
3
 Capillary Beds of the Nephron
Every nephron has two capillary beds
Glomerulus
Peritubular capillaries

Each glomerulus is:
Fed by an afferent arteriole
Drained by an efferent arteriole

Blood pressure in the glomerulus is high because:
Arterioles are high-resistance vessels
Afferent arterioles have larger diameters than efferent
arterioles
4
 Capillary Beds

Peritubular beds are low-pressure, porous
capillaries adapted for absorption that:
Arise from efferent arterioles
adhere to adjacent renal tubules
Empty into the renal venous system

Vasa recta – long, straight efferent arterioles of
juxtamedullary nephrons

5
6
Vascular Resistance in Microcirculation

Afferent and efferent arterioles offer high resistance
to blood flow
Blood pressure declines from 95mm Hg in renal
arteries to 8 mm Hg in renal veins
Resistance in afferent arterioles:
Protects glomeruli from fluctuations in systemic blood
pressure
Resistance in efferent arterioles:
Reinforces high glomerular pressure
Reduces hydrostatic pressure in peritubular capillaries

7
 Proximal convoluted tubule

Bowman’s capsule

Afferent arteriole
Peritubular capillaries
Efferent arteriole

Glomerular capillary bed Peritubular capillary bed,
High pressure vascular bed, Low pressure vascular bed,
increasing oncotic pressure high oncotic pressure.

Good for filtration Good for re-absorption

8
Mechanisms of Urine Formation
The kidneys filter the body’s entire plasma volume
60 times each day.

The filtrate:
Contains all plasma components except protein
Loses water, nutrients, and essential ions to
become urine

The urine contains metabolic wastes and unneeded
substances
9
Mechanisms of Urine Formation
Urine formation and
adjustment of blood
composition involves
three major
processes
– Glomerular
filtration
– Tubular
reabsorption
– Secretion

10
Glomerular Filtration

The first step in urine formation

Blood flows through the glomerulus, allowing
protein-free plasma to be filtered through the
glomerular capillaries into the Bowman’s capsule.

~20% of plasma entering the glomerulus is filtered

125 ml/min filtered fluid

11
Tubular Reabsorption
Movement of substances from tubular lumen back
into the blood

Reabsorbed substances not lost in the urine, but
are carried by the peritubular capillaries to the
venous system

Most of the filtered plasma is reabsorbed

12
Tubular Secretion

The selective transfer of substances from the
peritubular capillary into the tubular lumen

Allows for rapid elimination of substances from the
plasma via extraction of the 80% of unfiltered
plasma in peritubular capillaries and adding it to
the substances already in tubule as result of
filtration

13
Urine Excretion “The end product”

The elimination of substances from the body in the
urine

All plasma constituents filtered or secreted, but not
reabsorbed remain in the tubules and pass into the
renal pelvis to be excreted as urine and eliminated
from the body

14
Types of Tubular Reabsorption

Reabsorption can be transcellular (across the cell)
or paracellular (between the cells)

Once the substance has moved pass the tubular
epithelium cell into the interstitial space bulk flow
then accounts for its movement back into the
peritubular capillaries

15
 Passive Reabsorption
Bulk flow results
from the imbalance
of osmotic or
hydrostatic forces
at the peritubular
capillary. Exactly
the same as at the
peripheral capillary
or the glomerulus

16
Active Reabsorption
Major substances are reabsorbed via active
transport. These are substances that are needed by
the body (e.g. Na+, glucose, aas, other electrolytes)

Sodium reabsorption-99.5% of filtered sodium is
absorbed
Proximal tubules (67%)
Loop of Henle (25%)
Distal/Collecting tubules (8%)

17
Active Reabsorption
Active reabsorption is via primary active transport
based on ATP hydrolysis (e.g. Na+) or secondary
active transport based on an ion gradient (e.g.
glucose)

Known transporters:
Na+/K+ ATPase
H+ ATPase
H+/K+ ATPase
Ca++ ATPase
18
Net Filtration Pressure (NFP)
The pressure responsible for filtrate formation

NFP equals the glomerular hydrostatic pressure
(HPg) minus the oncotic pressure of glomerular blood
(OPg) combined with the capsular hydrostatic
pressure (HPc)

NFP = HPg – (OPg + HPc)
Or
NFP = PGC – PBS - OGC
19
Glomerular Filtration Rate

Glomerular filtration rate (GFR) is the rate of
production of filtrate at the glomeruli from plasma
– Typically 80 – 140 ml/min depending on age, sex
etc
– Sum of the filtration rates of all functioning
nephrons
– Index of kidney function

20
GFR
Factors governing filtration rate at the
capillary bed are:
Total surface area available for filtration
Filtration membrane permeability
Net filtration pressure

GFR is directly proportional to the NFP
Changes in GFR normally result from
changes in glomerular blood pressure
21
GFR

If the GFR is too high:
Needed substances cannot be reabsorbed
quickly enough and are lost in the urine

If the GFR is too low:
Everything is reabsorbed, including wastes that
are normally disposed of

22
Filtration:

glomerular hydrostatic pressure (GHP)
push fluid out of vessels

capsular hydrostatic pressure (CsHP)
push fluid back into vessels

net hydrostatic pressure (NHP)

23
Filtration:

blood colloid osmotic pressure (BCOP)

proteins in blood (hyperosmotic)

draw water back into blood

~ 25 mm Hg

24
Filtration:

importance of blood pressure

20% drop in blood pressure
50mm Hg to 40mm Hg
filtration would stop

25
 Driven by Starling forces
Pressure inside capillaries > Pressure outside
 movement of fluid from blood

Forces in capillaries: hydrostatic pressure PGC
= + 60mmHg

Forces in capsule: hydrostatic pressure PBS = -
15mmHg

oncotic pressure GBS = 0 mmHg

Male adults GFR: ~ 90 – 140 ml/min

Female: 80 – 125 ml/min

125 ml/min usually good average

26
 REFERENCES
Drake R.L., Gray’s Anatomy for Students, 2nd
Edition, 2009, Churchill Livingstone

Moore, Clinically Oriented Anatomy, 6th Edition,
2009, Lippincott Williams & Wilkins

Textbook of Medical Physiology – Guyton & Hall

Medical Physiology – R.K Marya
24-Oct-24 27