NRAN 80323 Diffusion and Dilution.pptx

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Diffusion
and
Dilution

NRAN 80323

Casey Crow DNP, CRNA

Objectives
• Diffusion
• Graham’s Law
• Osmosis
• Osmotic Pressure
• Osmolarity/osmolality
• Fick’s Law

Diffusion

• The net movement of one type of molecule through space
as a result of random motion to minimize a concentration
gradient
• Space- liquid or gas

• Brownian Motion: Random, uncontrolled movement of
particles in a fluid as they constantly collide with other
molecules
• Random walk
• Driven by the inherent kinetic energy
of the molecules

Diffusion
• Diffusion constant (D)
decreases with
• Increasing molecular mass
• Heavy molecular mass diffuses a
shorter distance over time

xrms= distance

• Increasing density of solvent
(root

meter square)

D = diffusion
constant
assigned per particular
molecule

• Diffusion constant (D) increases
with
• Increasing temperature
• Molecules moving quicker, then
diffusion distance increases over time

Diffusion
• Graham’s Law
• Rate of diffusion of a gas is inversely proportional to the square root
of the molecular weight
• Think: molecular weight and rate of diffusion
• Important factor: molecular weight

r = rate of
diffusion
mw = molecular
weight

Diffusion
• Diffusion of solute through a permeable
membrane is dependent on 5 factors
• How solutes can pass through a membrane

Directly
proportional

Inversely
proportional

Concentration Gradient

Membrane Thickness

Tissue Area

Molecular Weight

Fluid:Tissue Solubility

Diffusion

• Fick’s Law: explains the directly
proportional and indirectly proportional
factors
of diffusion
DIFFUSION
= DP x (area
/thickness
) x (solubility
gas

gas

molecular weightgas)

mem

mem

gas

/

1. Delta P- concentration gradient, directly
proportional, example:
overpressurizing VA
2. Tissue area/membrane area, directly
proportional, example: lungs, COPD,
atelectasis, surface area of alveoli
3. Fluid/tissue solubility, directly
proportional, example: lipophilicity of
drugs
4. Membrane thickness, indirectly
proportional, example: pulmonary
edema, ARDs, pulmonary fibrosis
5. Molecular weight, indirectly
proportional, example: heavy

Diffusion
• Fick’s Law: cellular respiration

Diffusion
• Fick’s Law: movement of O2 and CO2 at
alveolar capillary membrane

Diffusion
• Nitrous Oxide (N2O)
• Highly diffusible: across the
membrane
• Low molecular weight
• Inversely proportional, increased rate of
diffusion

• Low blood:gas partition coefficient

Diffusion into closed air
spaces
Diffusion Hypoxia

• Almost* insoluble in blood

Diffusion
• Diffusion into closed spaces
• While N2O has low blood solubility, it is still 34 times more soluble
than N
• B:G partition coefficient is 0.46

• N2O will rapidly diffuse into closed spaces containing “air”

Middle Ear
Bowel

Pneumothorax
Air Embolism
Bowel
Obstruction

ETT Cuff
PA Catheter
Cuff

• N2O inspired at 70% will double the size of a pneumothorax in 10
min
• Compliant spaces will continue to expand
• Non-compliant spaces will increase in pressure

Diffusion
• Diffusion Hypoxia
• Discontinuation of N2O
on emergence results
in rapid diffusion of
N2O from bloodstream
into alveolus
• Results in significant,
but transient, dilution
of O2 and CO2 in
alveolus
• Attenuated by
administration of 100%
O2

We need CO2 to diffuse out from capillary to
alveolus
We need O2 to diffuse in from the alveolus to
capillary to be delivered to the tissue
LIMITED AMOUNT of molecules of gas that we
can put into the alveolus, set partial pressure
SO, this leads to increased concentration of
N20 and decreased concentration of O2 leading

Diffusion

• Second-Gas Effect
• Applies to coadministration of volatile anesthetic (more
soluble, less diffusible) with N2O (less soluble, more
diffusible)
• Rapid uptake (immediate diffusion) of N2O from alveolus
into bloodstream concentrates the amount of volatile
anesthetic in alveolus
• Greater concentration of alveolar volatile anesthetic
speeds onset- overpressurizing, increase FA increase Fa
• Also applies on emergence when rapid diffusion of N2O from
bloodstream into alveolus concentrates amount of volatile
anesthetic in bloodstream (“pulling” from tissue compartments)
• Emptying the physiologic compartments more quickly

Diffusion

Diffusion
• Factors affecting diffusion for NON-GASES
across membranes
• Concentration gradient from NON-IONIZED molecules
• Electrochemical gradient for IONIZED molecules
• Lipid Solubility
• Size of Molecule

Diffusion
• Semipermeable Membrane
• Process in which molecules of a solvent (what something is dissolved in)
pass through a semipermeable membrane from a less concentrated
solution into a more concentrated one, thus equalizing the concentration
on each side of the membrane
• NOT permeable to the solute
• Solvent is freely permeable and moves to dilute the solute and establish
equilibrium
• When WATER is solvent, process is known as OSMOSIS

Osmosis
• Osmotic Pressure
• Pressure, exerted by the solutes, required to stop osmosis
• Related to the number of non-permeable molecules
(solute)
• Physiologic osmotic pressure in capillaries results from
#1 factor for osmotic pressure in
plasma proteins
CAPILLARIES: PLASMA PROTEINS
• ONCOTIC Pressure
• Normal: 24-27 mmHg

• Osmole

Plasma proteins hold fluid in even
though we have a very
semipermeable membrane

• One-gram molecular weight of undissociated solute
• Can be measured as osmoles per liter of solvent or
osmoles per kilogram of solvent

Osmosis
Osmolarity: Concentration of solute in terms of osmoles per
liter VOLUME
Osmolality: Concentration of solute in terms of osmoles per
•kilogram
ClinicalWEIGHT
Application

• Lab typically reports serum osmolality
• Normal: 285-295 mOsm/kg

• Osmolarity can be calculated at bedside:
2(Na+ + K+) + glucose + BUN
• Difference is Osmotic Gap
• Normally <10-15 mmOsm/kg
• Value >15 is indicative of large presence of foreign
SOLUTE

Osmosis
• Osmolarity

• Concentration of solute expressed in terms of osmoles per liter
VOLUME
• Avogadro’s Hypothesis: One mole of solute in molar volume
(22.4L) will exert 1 atmP at 0 degrees C
• In mixed solution, osmotic pressure is the SUM of individual
molarities: the added osmotic pressures of Na, K, Glucose and
BUN
• Over 99% of plasma osmolarity due to serum electrolytes,
remainder is plasma protein, exception: CAPILLARIES
• Plasma protein play role in capillaries
• Oncotic pressure 24-27 mmHg or 285-2295 mOsm/kg

• In dilute solutions such as plasma, differences between
osmolality and osmolarity are generally <1%
• RBC’s will lyse at osmolarities below 200 mOsm/L

Osmosis
• Physiologic Membranes
• For osmosis to occur
• Across cell membranes
• Membranes must be impermeable to one or more
solutes
• Must have difference in concentration of solutes

• Across capillary walls
• Most capillary walls are permeable to small solutes
(Na+, Cl-, etc)
• Not permeable to albumin/plasma proteins, which is
why they contribute to oncotic pressure

Summary
• Define diffusion and Brownian Motion
• Describe diffusion in terms of molecular mass, density of solvent and
temperature
• Graham’s Law considers which particular characteristic of diffusion?
• Describe diffusion across a permeable membrane
• Define Fick’s Law in terms of the 5 factors of diffusion across a permeable
membrane
• How does Fick’s Law apply to physiologic gas exchange in lungs?
• Apply diffusion into closed spaces, diffusion hypoxia, and second-gas effect to the
application of N2O
• What are the factors affecting diffusion of non-gas particles across physiologic
membranes?
• What is osmosis?
• Define and describe osmotic pressure, osmolarity, and osmolality
• What are the physiologic implications of serum osmolarity?
• Describe osmosis across human cell membranes and capillary walls

References
• Shubert / Chapter 6 / 152-153
• Nagelhout / Chapter 15