Colloids review questions

Question 1

Define disperse systems and their two main components

Answer 1

disperse system = system in where one substance (the disperse phase) is dispersed or distributed as particles [more or less uniformly] throughout another phase (the dispersion medium or continuous phase).

Question 2

Identify disperse systems based on the combination of their components’ states of matter and name each combination.

Answer 2

* cn be in solid, liq or gas, of the 9 possibilities 8 are colloidal dispersons

(gas in gas = molecular dispersion)

Question 3

Classify and describe dispersion based on their particle size

Answer 3

Molecular dispersions (true dispersions; i.e. SOLUTIONS, size \< 1nm) Colloidal dispersions (particle size of 1 nm - 1μm)
Fine and coarse dispersions (particle size \> 1 μm)

Question 4

What is the size range for colloidal dispersions?

Answer 4

1-1000 nm

Question 5

Define sol and gel as colloidal dispersions.

Answer 5

sol = dispersions of solids in liquid

Some colloidal dispersions under the proper conditions of concentration and temperature set to a solid or semi-solid ⇒ gels.

Question 6

difference between true solutions and colloidal dispersions

Answer 6

True solutions contain molecules, typically <1 nm
Colloidal dispersions contain particles > 1 nm < 1000nm

*some cases such as with macromolecules (proteins, polymers, nucleic acids) while they are molecular solutions they are also considered colloids due to the size of the molecules that can range approximately 1-20 nm

Question 7

three main types of colloidal systems?

Answer 7

Lyophobic (hydrophobic) Colloids
Lyophilic (hydrophilic) Colloids
Association Colloids

Question 8

Compare lyophobic and lyophilic colloidal particles:

solvation, thermodynamic stability, redispersibility, preparation method/formation, sensitivity to electrolytes.

Answer 8

lyophobic:

• the degree of attraction is small or non-existent
• often unstable
• particles aggregating rather than remaining in contact with the dispersion medium

Lyophilic

• dom by repulsion
• disperse phase interacts appreciably with the dispersion medium
• affinity exists between the dispersed particles and the dispersion medium. This contributes to the stability of the system.

Question 9

Gibbs free energy is defined as ∆G= ∆H-T∆S. How is this equation used to explain formation of lyophobic and lyophilic colloids.

Answer 9

Lyophobic

• little/no attraction, thermodynamically unstable so particles aggregate to lower surface free energy
• irreversible systems
• ∆G positive, ∆H positive
• Surface free energy NOT lowered by solvation; reverse process (agglomeration) spontaneous

Lyophillic

• thermodynamically stable and reversible
• ∆G = neg, ∆H = typically neg
• surface free enrgy lowered by solvation
• no floculation of coagulation

Question 10

What are the two main methods for preparing lyophobic colloids? What is the main factor playing a role in stabilizing lyophobic particles?

Answer 10

Lyophobic colloids are formed by either dispersion or condensation

• Dispersion – mechanical disintegration or by addition of deflocculating agents (also called peptization)
• Condensation – physical and chemical

Question 11

examples for lyophobic systems and formulations.

Answer 11

• water or aqueous solutions: water-insoluble drugs, clays (kaolin), colloidal sulfur, metal (colloidal gold, colloidal iron)
• Aurothioglucose colloidal dispersion, Iron Dextran Injection, Colloidal Sulfur topical preparation

Question 12

. What types of lyophilic systems exist? What is the main factor playing a role in stabilizing lyophilic particles?

Answer 12

Two major classes:

• Water soluble polymers – size of individual molecules are colloidal in dimension
• Particulate dispersions – highly solvated

Stabilizing forces: hydration layer (main), electrical double layer (if applicable)

Question 13

Give examples for lyophilic systems and formulations.

Answer 13

True Solutions

• water soluble polymers, acacia, povidone, protein solutions

Gelled Solutions

• high concentration of polymers
• e.g. gelatin or starch → set to gels on cooling
• methylcellulose → gels on heating

Particulate Dispersions

• contain solid particles, such as bentonite or microcrystalline cellulose

Question 14

Define association colloids.

Answer 14

micelles - contain both large lyophobic moieties with strongly lyophilic groups within the same molecule and orient themselves accordingly in the solution.

Question 15

What is ‘amphipatic’?

Answer 15

Lyophilic and lyophobic portions within the same molecule

Question 16

Why is particle size an important consideration in dispersion stability?

Answer 16

Particle size is important in many ways, among these are

• Influence on sedimentation rate
• Increase in surface free energy and aggregation tendency

Question 17

Explain how surface free energy is related to particle size and the stability of the system. Based on the equation ∆ F = γ ∆A

Answer 17

Essential characteristic common to all disperse systems; as particles become smaller, surface area to volume ratio becomes larger;

Question 18

what are the ways to lower surface free energy in a dispersion. Will decreasing surface free energy improve the physical stability of the dispersion?

Answer 18

decrease surface free energy are decreasing the interfacial tension and/or decreasing the surface are

. Note that to keep the particles small (with larger surface area) decreasing the interfacial tension is the main choice.

Question 19

Define the kinetic properties of colloidal particles.

Answer 19

Brownian motion, Diffusion and Sedimentation

Question 20

Explain the principle of Fick’s law of diffusion and how the different parameters influence the rate of diffusion.

Answer 20

Question 21

What is meant by concentration gradient and how this concept is used in formulation.

Answer 21

• concentration gradient: existence of high concentration region and a low concentration region
• directs the movement of molecules/particles
• By maintaining ‘sink conditions’ the highest concentration gradient will provide continuous movement of molecules/particles.

Question 22

Stokes law describes the sedimentation properties of particles. Explain the role of the different parameters in the context of formulation stability.

Answer 22

Question 23

. Describe the Tyndall effect and how it can be utilized for measuring particle size.

Answer 23

A beam of light directed at a colloidal sol will be scattered or absorbed.

The scattering of light makes the sol appear turbid *Tyndall effect

The degree of light scattering is proportional to particle size and can be used for measurements

Question 24

Can you observe colloidal particles by light microscope or by electron microscope? Explain.

Answer 24

Generally no,

colloidal particles are too small to be seen with an optical microscope (resolution is about 0.5 μm),

the high resolving power of electron microscopy must be employed where resolution is about 1 nm.

Question 25

Explain the concept of electrical double layer and its role in particle stability.

Answer 25

• charge onparticle surface will attract oppositely charged ions (counter ions) to achieve electrical neutrality: this causes the formation of an electrical double layer around the particle
• electrical double layer determines the distance between adjacent particles in the dispersion ⇒ directly affects the stability of the system.

Question 26

Name the parts of the electrical double layer (A-D), region E and potentials defined at different distances from the particle surface (1-3).

Answer 26

A – surface of particle
B – tightly bound layer
C – shear plane
D – diffuse part of double layer; layer with excess counter ions or also called Gouy- Chapman layer

E- electro-neutral region; bulk solution

1- surface potential
2- Stern potential
3- zeta potential

Question 27

Define shear plane and zeta potential.

Answer 27

Shear plane= boundary after the tightly bound layer marking the the mobile portion of the double layer

potential measure at the shear plane = zeta potential

Question 28

How does the electrical potential change as we move away from the particle surface?

Answer 28

• Zeta potential decreases linearly from the surface potential to the Stern potential
• decays exponentially thereafter and becomes zero at the end of the double layer

Question 29

How the Debye length influences the interaction between lyophobic particles?

Answer 29

Debye length is the length of the double layer and 2X the Debye length (two particles)

indicates the distance between particles

Question 30

Define deflocculated and flocculated particles and the zeta potential in each of these systems.

Answer 30

Deflocculated: particles remain dispersed; characterized by a high ζ potential

Flocculated: particles form loose aggregates (flocs); characterized by low ζ potential

Question 31

If zeta potential is high the colloidal soltion is thermodynamically stable or unstable

Answer 31

stable

Question 32

Is it important to lower the zeta potential to achieve a pharmaceutically stable colloidal sol? Why?

Answer 32

Yes, lowering zeta potential provides a flocculated dispersion that is considered redispersible, hence pharmaceutically stable

Question 33

What is the difference between ‘colloidally stable’ and ‘pharmaceutically stable’ dispersions.

What are the practical implications for formulation stability?

Answer 33

deflocculated systems = colloidally stable due to electrostatic repulsion between particles -> NOT pharmaceutically stable due to caking (not redispersible) after sedimentation had occurred

• harmaceutically stable system is the one that can be easily redispersed, therefore a flocculated system (not colloidally stable) should be used.

Question 34

Explain the effect of added counterions on the zeta potential of colloidal particles.

Answer 34

Added counterions lower the zeta potential.

Question 35

Define DLVO theory and the presence and balance of attractive and repulsive forces around colloidal particles.

a) name the axes (D,E,F) of the graph
b) explain curves VA, VR and VT

Answer 35

D – repulsive potential
E – attractive potential
F – distance between particles
VA – van der Waals attraction
VR – electrostatic repulsion
VT – total energy of interaction

Question 36

explain the forces responsible for the potential minimum and maximum

A, B and C

what is the relationship between the balance of these forces and the physical stability of the particles?

Answer 36

A – primary minimum: attraction predominates - coagulation
B - secondary minimum – slight attraction predominates – flocculation
C – primary maximum – repulsive forces predominate due to the electrical double layer

The balance of these forces determine whether the particles will be individually dispersed or aggregate (either loosely or irreversibly).

Question 37

Explain the difference between flocculation, aggregation and coagulation.

Answer 37

terms represent the degree of binding of the particles from loose to irreversible.

• Flocculated and aggregated particles can still be redispersed but coagulated particles cannot.

Question 38

Define ‘caking’. Which colloidal system is prone to caking? Why?

Answer 38

An irreversible form of sedimented particles; deflocculated systems are prone to caking because as particles eventually sediment coagulation occurs due to compaction.

Question 39

Provide examples for flocculating agents and their mechanism of action.

Answer 39

Electrolytes – decrease zeta potential
Lyophilic macromolecules – protective colloid effect; eg Polymers – provide steric hindrance

Question 40

Define sedimentation volume ratio (F) and how it changes in relation to zeta potential.

Answer 40

F=Vu/Vo
V_u final volume of sediment

V_o total volume of the suspension

*Lowering zeta potential results in increased F

Question 41

What are protective colloids and what types are used in pharmaceutical formulation?

Answer 41

Lyophilic macromolecules can be added to lyophobic colloids to act as ‘protective colloids’

• adsorb onto other particle surfaces preventing close contact of particles and therefore preventing coagulation

Question 43

What is coacervation and microencapsulation and how is it used in drug delivery?

Answer 43

Coacervation = precipitation of colloid particles from solution/dispersion with the addition of electrolytes or non-solvents

• when done in the presence of drug particles the colloid particles coat the drug particles – microencapsulation.

used to prepare slow and controlled release dosage forms.

Question 44

Give several examples for pharmaceutical applications of colloids

Answer 44

• Delivery systems: Micelles, microemulsions, liposomes, microspheres, nanoparticles, and drug – polymer conjugates, nanocrystals

– Radioactive Colloids: Diagnostic and therapeutic agents in nuclear medicine

• Excipients: emulsifier, stabilizer, viscosity modifier, suspending agent