Post on 18-Nov-2014
description
REGULATION OF FLUID AND ELECTROLYTE BALANCE
• Body Fluids and Fluid Compartments
• Body Fluid and Electrolyte Balance – fluid and electrolyte homeostasis
Why do we care about this?
ECF volume
Osmolarity
9781429208567
T h e B o d y a s a n O p e n S y s t e mT h e B o d y a s a n O p e n S y s t e m
“ O p e n S y s t e m ” . T h e b o d y e x c h a n g e s m a t e r i a l a n d e n e r g y w i t h i t s s u r r o u n d i n g s .
Water Steady State• Amount Ingested = Amount Eliminated
• Pathological losses
vascular bleeding (H20, Na+)
vomiting (H20, H+)
diarrhea (H20, HCO3-).
Electrolyte (Na+, K+, Ca++) Steady State
• Amount Ingested = Amount Excreted.
• Normal entry: Mainly ingestion in food.
• Clinical entry: Can include parenteral administration.
Electrolyte losses
• Renal excretion
• Stool losses
• Sweating
• Abnormal routes: e.g.. vomit and diarrhea
Body Fluids and Fluid Compartments
• The percentage of total body water: 45-75%• Intracellular compartment
– 2/3 of body water (40% body weight)
• Extracellular compartment– 1/3 of body water (20% body weight) – the blood plasma (water=4.5% body weight)– interstitial fluid and lymph (water=15% body weight)– transcellular fluids: e.g. cerebrospinal fluid, aqueous
humor (1.5% BW)
• Distribution of substances within the body is NOT HOMOGENEOUS.
Body Water Distribution
CELL WATERCELL WATER40% 28 L
RBC
INTERSTITIALFLUID
COMPARTMENT
15% 10 L
PLASMA WATER
5% 3 L
TRANSCELLULAR WATER
1% 1 L
Input
ECFECF20% 14 L
•Individual variability (lean body mass)
–55 - 60% of body weight in adult males
–50 - 55% of body weight in adult female
–~42 L For a 70 Kg man.
Electrochemical Equivalence
• Equivalent (Eq/L) = moles x valence
• Monovalent Ions (Na+, K+, Cl-):– 1 milliequivalent (mEq/L) = 1 millimole
• Divalent Ions (Ca++, Mg++, and HPO42-)
– 1 milliequivalent = 0.5 millimole
Solute Overview: Intracellular vs. Extracellular
• Ionic composition very different
• Total ionic concentration very similar
• Total osmotic concentrations virtually identical
0
100
200
300
400
Protein
Organic Phos.
Inorganic Phos.
Bicarbonate
Chloride
Magnesium
Calcium
Potassium
Sodium
Summary of Ionic composition
InterstitialH2O
PlasmaH2O
CellH2O
Net Osmotic Force Development
• Semipermeable membrane• Movement some solute obstructed• H2O (solvent) crosses freely• End point:
– Water moves until solute concentration on both sides of the membrane is equal
– OR, an opposing force prevents further movement
Osmotic Pressure ()
• The force/area tending to cause water movement.
SS
S
S S S
S S SS
S
S S
= p
Glucose Example
Gl Gl Gl Gl
Gl Gl Gl Gl
Initial
Final
10 L 10 L
15 L 5 L
Osmotic Concentration
• Proportional to the number of osmotic particles formed: Osm/L = moles x n (n, # of particles in solution)
• Assuming complete dissociation:– 1mole of NaCl forms a 2 osmolar solution in 1L– 1mole of CaCl2 forms a 3 osmolar solution in 1L
• Physiological concentrations:– milliOsmolar units most appropriate– 1 mOSM = 10-3 osmoles/L
e.g. 1 M NaCl = 2 M Glu in Osm/L
Principles of Body Water Distribution
• Body control systems regulate ingestion and excretion:– constant total body water– constant total body osmolarity
• Osmolarity is identical in all body fluid compartments (steady state conditions)– Body water will redistribute itself as
necessary to accomplish this
Intra-ECF Water Redistribution
Plasma vs. Interstitium
• Balance of Starling Forces acting across the capillary membrane– osmotic forces– hydrostatic forces
Intracellular Fluid Volume
• ICFV altered by: changes in extracellular fluid osmolarity.
• ICFV NOT altered by: iso-osmotic changes in extracellular fluid volume.
• ECF undergoes proportional changes in:– Interstitial water volume– Plasma water volume
Primary Disturbance: Increased ECF Osmolarity
• Water moves out of cells– ICF Volume decreases (Cells shrink)– ICF Osmolarity increases
• Total body osmolarity remains higher than normal
Primary Disturbance: Decreased ECF Osmolarity
• Water moves into the cells– ICF Volume increases (Cells swell)– ICF Osmolarity decreases
• Total body osmolarity remains lower than normal.
Plasma Osmolarity Measures ECF Osmolarity
• Plasma is clinically accessible
• Dominated by [Na+] and the associated anions
• Under normal conditions, ECF osmolarity can be roughly estimated as:
POSM = 2 [Na+]p 270-290 mOSM
• Isotonic Solutions --> n.c. ICF
• Hypertonic Solutions --> Decrease ICF
• Hypotonic --> Increase ICF
SOLUTIONS USED CLINICALLY FOR VOLUME REPLACEMENT
THERAPY
Type of solutions• Saline solutions
– Come in a variety of concentrations: hypotonic (eg., 0.2%), isotonic (0.9%), and hypertonic (eg. 5%).
• Dextrose in Saline– Glucose is rapidly metabolized to CO2 + H2O– The volume therefore is distributed intracellularly as well as
extracellularly– Again available in various concentrations– Used for simultaneous volume replacement and caloric
supplement
• Dextran, a long chain polysaccharide– Solutions are confined to the vascular compartment and
preferentially expand this portion of the ECF
Body Fluid and Electrolyte Balance
• Water input and output
The role of the kidneys in maintaining balance of water and electrolytes
The regulation of body water balance
thirst sensation
control of renal water excretion by ADH
Thirst centers in the hypothalamus
relay information to the cerebral cortex where thirst becomes a conscious sensation
controls the release of ADH
Stimuli for thirst sensation
Baroreceptors and stretch receptors as detectors
impulses sent to the thirst control centers in the hypothalamus
Effect of ADH (vasopressin)
Factors affecting ADH release
• Sodium balance
The kidneys - the major site of control of sodium output
Influence of dietary input on appropriate changes in sodium excretion by the kidneys
Effector mechanisms include changes in:
- glomerular filtration rate
- plasma aldosterone levels
- peritubular capillary Starling forces
- renal sympathetic nerve activity
- intrarenal blood flow distribution
- plasma atrial natriuretic factor (ANF
Effects of aldosterone
The renin-angiotensin system
release of renin
action of renin on the formation of angiotensin II
effects of angiotensin II: a.blood pressure; b. synthesis and release of aldosterone; c. stimulation of the hypothalamic thirst centers; d. release of ADH
Pathway of RAAS
Principal cells & aldosterone
Net reabsorption of salt and water by the proximal convoluted tubule
peritubular capillary hydrostatic forces
colloid osmotic pressure
Decrease in renal sodium excretion by stimulation of renal sympathetic nerves
Release of Atrial natriuretic peptide (ANP)
in response to an increase in blood volume
increase sodium excretion by increasing GFR and inhibiting sodium reabsorption
• Atrial natriuretic peptide
• Decreased blood pressure stimulates renin secretion
The regulated variable affecting sodium excretion - effective arterial blood volume
Changes in effective arterial blood volume can elicit the appropriate renal response by three possible mechanisms
a change in blood volume glomerular blood flow and capillary pressure GFR
a change in blood volume detected by an intrarenal baroreceptor release of renin
a change in blood volume could change peritubular capillary Starling forces
Other factors affecting sodium excretion include:
glucocorticoids
estrogen
osmotic diuretics
poorly reabsorbed anions
diuretic drugs
Ho
meo
stas
is:s
ever
e d
ehyd
rati
on
• Potassium balance
Potassium plays a number of important roles in the body
electrical excitability of cells
major osmotically active solute in cells
acid-base balance
cell metabolism
The kidneys are the major site in control of potassium balance
Factors affecting the distribution of potassium between cells and extracellular fluid include:
activity of the sodium-potassium pump
acid-base status of body fluids
availability of insulin
cellular breakdown due to trauma, infection, ischemia, and heavy exercise
The regulation of plasma potassium by hormones
insulin
epinephrine
aldosterone,
Factors affecting potassium excretion include:
intracellular potassium concentration
aldosterone
excretion of anions
urine flow rate