Diffusion ….
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Transcript of Diffusion ….
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DIFFUSION ….
Kausar Ahmad
Kulliyyah of Pharmacy, IIUM
http://staff.iium.edu.my/akausar
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Contents
• Diffusion process
Lecture 1
• Equations describing diffusion phenomena• Methods to study diffusion
Lecture 2
• Factors affecting diffusion process• Applications
Lecture 3
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Introduction
• Gas• Liquid• Solid
Diffusion occurs in
• The process by which a gas escapes from its container through a tiny hole into an evacuated space.
Effusion occurs in gas
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The Process of DiffusionMolecule migration from
region of HIGH to LOW concentration
Brownian movement of
solute molecule
Achieve equilibrium state
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Passive Diffusion of Ions or Molecules
dashed line is a membrane
red dots move out of membrane,
following their concentration gradient.
concentration of red dots inside/outside the same,
net diffusion ceases.
red dots still diffuse into and out of the membrane,
but the rates of the inward /diffusion the same 5
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Rate of DiffusionGas > liquid > solide.g. distances between molecules are much shorter in a liquid than in a gas.
Collisions are much more frequent.
Migration becomes lesser.
Thus, diffusion is slower.
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Example
Atmospheric gases mix so well that the 80 km of air closest to Earth has a uniform composition
Much less mixing occurs in the oceans, and the differences in composition at various depths support different species.
Rocky solids intermingle so little that adjacent strata remain separated for millions of years.
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Al-Quran 35:27
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Example: Pulmonary gas exchange
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Driven by passive diffusion. Substances move down a concentration
gradient.
Oxygen moves from the alveoli (high oxygen concentration) to the blood (lower oxygen
concentration, due to the continuous consumption of oxygen in the body).
Conversely, carbon dioxide is produced by metabolism and has a higher concentration
in the blood than in the air. Thus.
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Diffusion in Polymers
• diffusion of small molecules (permeants)
through a polymer
Permeation
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Permeation through Polymers
Permeant molecule migrates through the
voids between the polymer chains.
Rate of diffusion depends on
the size of the permeant
relative to the gaps between the polymer
molecules.
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Effect of polymer crystallinity Size effect is strongest for crystalline polymers, where the material has a
rigid structure.
I n elastomers , movement o f t he
po l ymer mo lecu les can a l l ow f r ee
passage o f t he pe rmea t i ng spec ies ,
giving higher diffusion rates which are less dependent on permeant size.
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Diffusion in liquids
Similar to diffusion of gas molecules BUT
the mean free path is very short (ca. the
size of a molecule).
Lack rigid lattice. Thus individual
atoms/molecules can move more freely.
Usually high diffusion rates.
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End Lecture 1/3
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Fick’s First Law of Diffusion
Amount of substance, dm,
diffusing in x direction,
in time dt,
across an area A,
Is proportional to concentration gradient dc/dx.
Thus, the diffusion rate is:
dm/dt = constant(A)(dc/dx)
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Constant is D, = diffusion coefficient (diffusivity)
Diffusion rate -> dm/dt= -DA(dc/dx)
‘D’ is not constant, varies slightly with concentration
‘D’ can be considered as mean value for concentration range covered
“-ve” because it is in the direction of decreasing concentration
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Fick’s Second Law of Diffusion
The concentration rate of change,
within diffusional field,
at a particular point,
is proportional to
rate of change in concentration gradient.
Dc/dt = D(d2c/dx2)
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Einstein’s Law of DiffusionFor diffusion of colloidal particles,
D = kT/f
f= friction coefficient
k = Boltzmann constant (1.38 x 10-23 JK-1)
T = absolute temperature (K)
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Stoke’s Law
For spherical particles, friction coefficient is:
f = 6r
= viscosity of medium
r = radius of particle
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Stoke-Einstein LawBoltzmann constant, k = R/N
R = gas constant (8.314 JK-1mol-1)N = Avogadro number (6.022 x 1023 mol-1)
From Einstein:D = kT/f
D = kT/ 6rD = RT/6Nr
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Measurement of DiffusionPorous disc method
m = -DA(c1 – c2)(t1 – t2)/L m = amount of solute diffused c1,c2 = solute concentration at either side of the
disc at time t1,t2
A = cross section of pores L= effective length of pores A/L is obtained by calibrating the cell in solute with
known D
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Solution: t1, c1
Path of a particle diffusing through porous disc
Solvent: t2, c2
A
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Limitation of Porous disc method
Calibration of cell with low molecular weight solute may not be valid for high molecular weight solutes. WHY????
Trapped air bubbles in pores.
Adsorption of molecules in pores.
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Diffusion through gels
Mt = Moe(-x2/4Dt)
ln Mt = ln Mo + (-x2/4Dt)
ln Mt = ln Mo - (x2/4Dt)
x2/4Dt = ln Mo - ln Mt
x2/t = 2.303 x 4D(log Mo - log Mt)
A plot of x2 against t gives a straight line,
Slope: 2.303 x 4D(log Mo - log Mt)
D can be calculated
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Solution: M0
Gel
x
x2
t
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Continue Diffusion through gels
Applications
Cup plate method of assay of antibiotics Diffusion through agar gels seeded
with test organism Zone of growth inhibition proportional
to antibiotic potency
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Continue Diffusion through gels
Zone of growth inhibition proportional to antibiotic potency
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inhibition of growth zone
filled with antibiotic
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Membrane Functions
A. Form selectively permeable
barriers
B. Transport phenomena• 1. Passive diffusion• 2. Mediated transport
• a. facilitated diffusion: carrier/channel proteins
• b. active transport
C. Cell communication and signaling
D. Cell-cell adhesion
and cellular attachment
E. Cell identity and antigenicity F. Conductivity
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Membrane allows separation of
small molecules from
big macromolecules
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Passive Diffusion
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Facilitated Diffusion
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Facilitated Diffusion
This animation illustrates protein mediated, facilitated diffusion out of a cell.
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Example: Diffusion across GIT
Absorption of weakly acidic/basic drugs
Passive diffusion of un-ionised molecule
across lipoidal membrane of GIT.
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Example: Purification by dialysis
Low MW impurities such as electrolytes are separated from colloidal particles.
Cellophane sac (Visking tube) containing the substance is immersed in large amount of water.
Pores of cellophane membrane are large enough for low MW solutes to pass through,but larger ones remain in the tube
Water into which the small solutes diffused, will be changed until the dialysate is free of electrolytes (monitored by change in conductivity).
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Diffusion through membrane
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Water renewed to establish
concentration gradient
Semi-permeable membraneSmall
molecules
Big molecule
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Example: Diffusion from Dosage Form
Drugs are incorporated in insoluble matrix e.g. wax, fatty
alcohol, polymer
GIT fluid penetrate the
pores and drug particles are leached out.
The diffusion of drug through the insoluble liquid-filled matrix is achieved via a tortuous path.
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Rate of drug released from one surface of insoluble matrix (Higuchi,1963):
Q = DeCs(2A – eCs)t/t)1/2
Q= amount of drug released per unit area at time, t
D = diffusion coefficient
e = porosity of matrix
Cs = solubility of drug
A = concentration/amount of drug in the tablet
= tortuosity of matrix
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End Lecture 2 /3
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Factors affecting DiffusionFick’s First Law: dm/dt= -DA(dc/dx), Stoke-Einstein Law: D = RT/6Nr
• As surface area /cross-sectional area of pores increases,amount of solutes diffused, dM or M,increases.• E.g. amount absorbed in small intestine is higher than
in stomach.
1) Area (A)
• As the concentration gradient (difference) increases, dM or M increases
2) Concentration gradient (dc/dx)
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Continue Factors affecting Diffusion
• As duration increases, dM or M increases,until saturation is obtained.
3) Time (t)
• As distance/thickness increases, dM or M decreases.• E.g. transdermal drug delivery depends on location due to
varying thickness of the skin: thigh, arm, chest, back, sole, palm, back of ear.
4) Distance or thickness (x or L)
• As temperature increases, diffusion coefficient, D,increases, dM or M increases
5) Temperature (T)
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Continue Factors affecting Diffusion
• As f increases, D decreases, dM or M decreases.
6) Frictional coeffiecient (f)
• f h and D 1/h, as h increases, dM or M decreases.
7) Viscosity (h)
• f r and D 1/r, as r increases, dM or M decreases.
8) Particle size (r)
• As porosity increases, dM or M increases.
9) Pore size or porosity
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Continue Factors affecting Diffusion
• As t increases, dM or M decreases.
10) Tortuosity
• Pore size of gel decreases.• Viscosity of liquid within the pores increases.• Affects network structure of gel.• Opposite charge of matrix ionised groups may result in
adsorption,thus retarding diffusion.• E.g. gelatin
11) Solute interaction with gel matrix or diffusion medium.
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Example of a membrane: Gelatin
Contain -NH2 (+) and -COOH (-) groups
pH influences ionisation
In acidic condition (+), gel is positively charged
In alkaline condition (-), gel is negatively charged
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Application of Diffusion
• E.g. D = kT/6rDetermine physical
parameters of particle
• Separation of molecules• Sample analysisChromatography
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Continue Application of Diffusion
• Isolation of impurities from colloidal particles• E.g. Removal of low MW
water-soluble proteins from natural rubber latex, a possible source of allergens
• Haemodialysis/purification of blood – remove small MW metabolic waste product while preserving high MW components.
Dialysis
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Continue Application of Diffusion
• Matrix system• Coating system• Transdermal system
Drug release from control-release preparations
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Continue Application of Diffusion
• Drugs release from carrierDrug release from ointment/cream
• Drugs pass through membraneGastro intestinal
absorption of drugs
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Continue Application of Diffusion
• Permeability coefficient for undissociated drugs
Transcorneal permeation
• Dissolution of drug in its vehicle• Diffusion of solubilised drug (solute) from
vehicle to surface of skin• Penetration of drug through layers of skin
esp. stratum corneum
Percutaneous absorption passage
through skin
• Drugs released from vehicle and absorbed through membraneBuccal absorption
• Drugs released from vehicle and absorbed through membraneSuppository
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Example in research: Lateral Diffusion of Proteins
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Source: http://bio.winona.msus.edu/berg/ANIMTNS/difusean.htm
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Example in research:Diffusion of Membrane Proteins
Source: http://bio.winona.msus.edu/berg/ANIMTNS/Prot-dif.htm
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References
Rawlins, E. A. (1984). Bentley’s Textbook of Pharmaceutics 8th Ed.
Bailliere Tindall. Chapter 8
http://bio.winona.msus.edu/berg/ANIMTNS/Prot-dif.htm
http://cr.middlebury.edu/biology/labbook/diffusion//
http://www.d.umn.edu/~sdowning/Membranes/lecturenotes.html
http://www.biologycorner.com/bio1/diffusion.html#
Thank you to contributors for images used in this presentation.
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