1. Introduction to Polymers
Physical Pharmacy 2
4/17/2017
Introduction to Polymers
Kausar Ahmad
Kulliyyah of Pharmacy, IIUM
Physical Pharmacy 2
KBA

2. Polymers in drug delivery
Physical Pharmacy 2
4/17/2017
Contents
Polymers in drug delivery
Copolymer
Polysaccharides
Properties of polymers
Crosslink density
Molecular weight
Physical Pharmacy 2
KBA

3. Polymers in drug delivery
Physical Pharmacy 2
4/17/2017
Polymers in drug delivery
use in drug delivery due to
Surface activity
efficient stabilisers for colloidal drug delivery system
Gel forming capacity
rheological control
Formation of self-assembly structure
analogous to simple surfactants: solubilisation of sparingly-soluble drugs
Physical Pharmacy 2
KBA

4. Polymers in delivery systems: Examples
Physical Pharmacy 2
4/17/2017
Polymers in delivery systems: Examples
Polyurethane
elasticity
catheter
Polysiloxane/silicone
inert
implants
Polymethyl methacrylate
physical strength & transparency
Polyvinylalcohol
hydrophilicity & strength
Polyethylene
toughness & lack of swelling
Polyvinyl pyrrolidone
suspension capabilities
Physical Pharmacy 2
KBA

5. BLOCK COPOLYMERS Consisting of block of two or more polymers
Physical Pharmacy 2
4/17/2017
BLOCK COPOLYMERS
Consisting of block of two or more polymers
Example is poly(ethylene oxide)-poly(propylene oxide) block copolymers:
H-OCH2CH2)a(OCH2CHCH3)b(OCH2CH2)cOH
Physical Pharmacy 2
KBA

6. ADVANTAGE OF BLOCK COPOLYMERS
Physical Pharmacy 2
4/17/2017
ADVANTAGE OF BLOCK COPOLYMERS
degradation rate of polymers can be controlled.
can obtain controlled drug release
protect compound from harsh environment
e.g. in stomach – in particular polymers containing poly(lactic) acid or poly(glycolic) acid
Physical Pharmacy 2
KBA

7. EXAMPLE OF BLOCK COPOLYMERS
Physical Pharmacy 2
4/17/2017
EXAMPLE OF BLOCK COPOLYMERS
Poly(lactic) acid
Poly(glycolic) acid
Physical Pharmacy 2
KBA

8. POLYSACCHARIDES Mainly due to formation of gels in aqueous solutions
Physical Pharmacy 2
4/17/2017
POLYSACCHARIDES
Mainly due to formation of gels in aqueous solutions
Examples:
carrageenans
alginates
starch
Exercise: List other types.
Physical Pharmacy 2
KBA

9. Chemical Structure of Some Polysaccharides Used in Drug Delivery
Physical Pharmacy 2
4/17/2017
Chemical Structure of Some Polysaccharides Used in Drug Delivery
Physical Pharmacy 2
KBA

10. Properties of Polymers
Physical Pharmacy 2
4/17/2017
Properties of Polymers
High molecular weight
Repeating units
Exist as linear or branched
Can be crosslinked
Properties depend on the polymerisation of the monomers
Can be divided into homopolymers or copolymers
Physical Pharmacy 2
KBA

11. TYPES OF Copolymers These can be further divided into: Alternating
Physical Pharmacy 2
4/17/2017
TYPES OF Copolymers
These can be further divided into:
Alternating
Block
Graft or branched
Please find out.
Physical Pharmacy 2
KBA

12. Physical Pharmacy 2
4/17/2017
Natural Polymers
Chemical modification can be carried out to change the properties
Example: Crosslinking
Physical Pharmacy 2
KBA

13. Rigidity In decreasing order: Plastics Rubbers Elastomers
Physical Pharmacy 2
4/17/2017
Rigidity
In decreasing order:
Plastics
Rubbers
Elastomers
Can be related to the glass transition temperature
Physical Pharmacy 2
KBA

14. Structure of polymer Linear Branched Crosslinked Thermoset polymer
Physical Pharmacy 2
4/17/2017
Structure of polymer
Linear
Branched
Crosslinked
Thermoset polymer
Linear polymers are equivalent to long strings which are not tied together.
Branched polymers are equivalent to tying the same pieces of string together but without closed loops
If you tie closed loops, then you are creating a crosslinked system e.g. pink dashed lines.
According to IUPAC recommendation: A thermosetting polymer is a prepolymer in a soft solid or viscous state that changes irreversibly into an infusible, insoluble polymer network by curing. Curing can be induced by the action of heat or suitable radiation, or both. A cured thermosetting polymer is called a thermoset.
Physical Pharmacy 2
KBA

15. Physical Pharmacy 2
4/17/2017
Crosslink Density
The extent of crosslinking in a polymer is expressed as the crosslink density
As number of crosslinks increases, the glass transition temperature increases.
As a coating crosslinks, the glass transition increases. Ueberreiter and Kanig reported that the change in glass transition temperature was directly proportional to crosslink density [K. Ueberreiter, G. Kanig, J. Chem. Phys., 18, 399 (1950)]
Vulcanized rubber, developed by Harvey Firestone, and used for automobile tires, is a well known example of a crosslinked polymer. Phenol formaldehyde resins, epoxy resins, amino resins, polyurethanes, unsaturated polyesters are all examples of polymers that can be used for crosslinked systems.
Physical Pharmacy 2
KBA

16. MOLECULAR WEIGHT/TEMPERATURE & POLYMER PROPERTIES
Physical Pharmacy 2
4/17/2017
MOLECULAR WEIGHT/TEMPERATURE &
POLYMER PROPERTIES
From: Florence & Attwood
Physical Pharmacy 2
KBA

17. Physical Pharmacy 2
4/17/2017
Molecular Weight
Both natural and synthetic polymers do not have specific molecular weight
Molecular weight is normally expressed as an average
The range of molecular weight is described by the POLYDISPERSITY
Physical Pharmacy 2
KBA

18. Molecular Weight Determination
Physical Pharmacy 2
4/17/2017
Molecular Weight Determination
Methods that can be used are:-
Chemical analysis
Osmotic pressure
Light scattering measurement
Gel permeation chromatography
In size exclusion chromatography, such as gel permeation chromatography, the intrinsic viscosity of a polymer is directly related to the elution time of the polymer. Therefore, by running several monodisperse samples of polymer in a gel permeation chromatograph (GPC), the values of K and a can be determined graphically using a line of best fit. Then the molecular weight and intrinsic viscosity relationship is defined.
Also, the molecular weights of two different polymers in a particular solvent can be related using the Mark–Houwink equation when the polymer-solvent systems have the same intrinsic viscosity:
Knowing the Mark–Houwink parameters and the molecular weight of one of the polymers allows one to find the molecular weight of the other polymer using a GPC. The GPC sorts the polymer chains by volume and as intrinsic viscosity is related to the volume of the polymer chain, the GPC data is the same for the two different polymers. For example, if the GPC calibration curve is known for polystyrene in toluene, polyethylene in toluene can be run in a GPC and the molecular weight of polyethylene can be found according to the polystyrene calibration curve.
Physical Pharmacy 2
KBA

19. Average MW The averages can be in terms of:- Number Weight Viscosity
Physical Pharmacy 2
4/17/2017
Average MW
The averages can be in terms of:-
Number
Weight
Viscosity
Z (sedimentation)
The above depends on the type of analytical method employed
Physical Pharmacy 2
KBA

20. Number Average MW Determined by: Osmometry End-group titration
Physical Pharmacy 2
4/17/2017
Number Average MW
Determined by:
Osmometry
End-group titration
Colligative properties
Physical Pharmacy 2
KBA

21. Weight Average MW Determined from Light scattering
Physical Pharmacy 2
4/17/2017
Weight Average MW
Determined from
Light scattering
Small Angle Neutron Scattering (SANS)
Sedimentation velocity [Hiementz]
Bias towards larger molecules
Light scattering
Small Angle Neutron Scattering (SANS)
Physical Pharmacy 2
KBA

22. Viscosity Average MW Determined by intrinsic viscosity
Physical Pharmacy 2
4/17/2017
Viscosity Average MW
Determined by intrinsic viscosity
intrinsic viscosity
Physical Pharmacy 2
KBA

23. Mark-Houwink Equation
Physical Pharmacy 2
4/17/2017
Mark-Houwink Equation
h = KMva
‘K’ and ‘a’ are the Mark-Houwink parameters and depend on polymer-solvent characteristics.
rigid rods, a=2.
hard sphere, a=0.
good solvent, a=0.8
Mark–Houwink equation
The equation describing the dependence of the intrinsic viscosity of a polymer on its relative molecular mass (molecular weight) and having the form:
[η] = K × Ma
where [η] is the intrinsic viscosity,
K and a are constants the values of which depend on the nature of the polymer and solvent as well as on temperature
Note:
The use of this equation with the relative molecular mass (molecular weight) is recommended, rather than with molar mass (which has the dimension of mass divided by amount of substance), since in the latter case the constant K assumes awkward and variable dimensions owing to the fractional and variable nature of the exponent a.
Source: IUPAC Compendium of Chemical Terminology 2nd Edition (1997)
Physical Pharmacy 2
KBA

24. Z-Average MW Determined by sedimentation equilibrium
Physical Pharmacy 2
4/17/2017
Z-Average MW
Determined by sedimentation equilibrium
Physical Pharmacy 2
KBA

25. Polydispersity Mw/Mn > 1
Physical Pharmacy 2
4/17/2017
Polydispersity
The ratio of Mw/Mn is the degree of polydispersity
Mw/Mn > 1
The smaller the ratio, the narrower is the distribution in molecular weight of the polymer
Physical Pharmacy 2
KBA

26. MOLECULAR WEIGHT DISTRIBUTION
Physical Pharmacy 2
4/17/2017
MOLECULAR WEIGHT DISTRIBUTION
Physical Pharmacy 2
KBA

27. Physical Pharmacy 2
4/17/2017
References
Aulton, M. E. (1988). Pharmaceutics: The Science of dosage form design. London: Churchill Livingstone. Wise, D. L. (2000). Handbook of Pharmaceutical Controlled Release Technology. New York: Marcel Dekker. Chasin, M & Langer, R (1990). Biodegradable polymers as drug delivery systems. New York: Marcel Dekker. Vyas, S. P & Khar, R. K. (2002). Targeted and controlled drug delivery. New Delhi: CBS.
Physical Pharmacy 2
KBA