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Polymer Biomaterials

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to introduce some fundamental polymer properties and the factors that influence them ... size of pendent groups. interaction between chains ... – PowerPoint PPT presentation

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Title: Polymer Biomaterials


1
Polymer Biomaterials
  • There are a large number of uses for polymers in
    the biomaterials field. These arise due to the
    wide variety of properties possible.
  • OBJECTIVES
  • to introduce some fundamental polymer properties
    and the factors that influence them
  • to provide an overview of the uses of polymers as
    biomaterials

2
POLYMERS
  • Polymers - long chain molecules of high molecular
    weight
  • -(CH2)n-

3
Common Polymer Biomaterials
4
Polymers In Specific Applications
5
Properties Molecular weight
  • synthetic polymers possess a molecular weight
    distribution

polydispersity index Mw/Mn
6
The Bulk State Solid
  • Polymers can be either amorphous or
    semi-crystalline, or can exist in a glassy state.
  • amorphous glassy state
  • hard, brittle
  • no melting point
  • semi-crystalline glassy state
  • hard, brittle
  • crystal formation when cooled
  • exhibit a melting point

7
Glass transition temperature, Tg
  • related to chain mobility
  • increased flexibility, lower Tg
  • factors
  • flexible links in backbone
  • size of pendent groups
  • interaction between chains
  • plasticizers interfere with bonding, increase
    chain movement, decrease Tg

8
Tg
  • effect of Molecular weight
  • Fox-Flory eqn.
  • K constant for given polymer
  • Tg8 Tg for infinite M
  • for copolymers (Fox-Flory)
  • w weight fraction of monomer in copolymer

9
Effect of Temperature on Polymer Properties
  • amorphous

viscous liquid
rubbery
Tg
T
glassy
Mw
10
Effect of Temperature
  • semi-crystalline

Rubber
Liquid
Viscous Liquid
Tm
tough plastic
T
Tg
semi-crystalline plastic
crystalline solid
10
1000
100000
1000000
molecular weight (g/mol)
11
Crosslinked Networks
  • crosslinks
  • covalent H-bonding entanglements
  • crosslinking
  • increased molecular weight
  • swell in solvents
  • organogel
  • hydrogel

12
Thermal Properties
13
Temperature Effects
Tg
Tm
semicrystalline
log(Modulus)
crosslinked
T
linear amorphous
Temperature
14
Viscoelasticity
  • The response of polymeric materials to an imposed
    stress may under certain conditions resemble the
    behavior of a solid or a liquid.

Stress
Strain
15
Mechanical Properties
16
Diffusion in Polymers
  • Polymers can also act as solvents for low
    molecular weight compounds. The diffusion of
    small molecular weight components in polymers is
    important in a number of fields
  • purification of gases by membrane separation
  • dialysis
  • prevention of moisture loss in food and drugs
    (packaging)
  • controlled drug delivery (transdermal patches,
    Ocusert)
  • polymer degradation

17
Diffusion in Polymers
  • Flux is dependent on
  • solubility of component in polymer
  • diffusivity of component in polymer
  • These in turn depend on
  • nature of polymer
  • temperature
  • nature of component
  • interaction of component with polymer

18
Solubility Estimation
  • From Hildebrand, the interaction parameter, c, is
    defined as
  • The solubility parameter, d, reflects the
    cohesive energy density of a material, or the
    energy of vapourization per unit volume.
  • While a precise prediction of solubility requires
    an exact knowledge of the Gibbs energy of mixing,
    solubility parameters are frequently used as a
    rough estimator.
  • In general, a polymer will dissolve a given
    solute if the absolute value of the difference in
    d between the materials is less than 1
    (cal/cm3)1/2.

19
Diffusivity
  • experimental observations
  • effect of T vs Tg

20
Diffusivity
  • effect of permeant size

21
Diffusivity Effect of Crystallinity
  • solutes
  • do not penetrate crystals readily
  • take path of least resistance
  • through amorphous regions
  • increased path length

D1,c diffusivity in semi-crystalline
polymer D1,a diffusivity in amorphous
polymer fc volume fraction of crystals x
shape factor (2 for spheres) (Mathematics of
Diffusion)
22
Example of Undesirable Absorption
  • poppet-style heart valve
  • poppet is composed of PDMS
  • in small of patients the poppet jammed or
    escaped
  • recovered poppets were yellow, smelled, and had
    strut grooves

23
Leaching - Undesirable
  • polymers often contain contaminants as a result
    of their synthesis/manufacturing
    procedure/equipment
  • may also contain plasticizers, antioxidants and
    so on
  • these contaminants are a frequent cause of a
    polymers observed incompatibility

24
Drug Delivery
Ocusert
TD - Scopolamine
25
In Vivo Degradation of Polymers
  • no polymer is impervious to chemical and physical
    actions of the body

Mechanisms causing degradation
26
Hydrolytic Degradation
  • hydrolysis
  • the scission of chemical functional groups by
    reaction with water
  • there are a variety of hydrolyzable polymeric
    materials
  • esters
  • amides
  • anhydrides
  • carbonates
  • urethanes

27
Hydrolytic Degradation
  • degradation rate dependent on
  • hydrophobicity
  • crystallinity
  • Tg
  • impurities
  • initial molecular weight, polydispersity
  • degree of crosslinking
  • manufacturing procedure
  • geometry
  • site of implantation

28
Hydrolytic Degradation
  • bulk erosion (homogeneous)
  • uniform degradation throughout polymer
  • process
  • random hydrolytic cleavage (auto-catalytic)
  • diffusion of oligomers and fragmentation of
    device
  • surface erosion (heterogeneous)
  • polymer degrades only at polymer-water interface

29
Polyesters
30
Polyesters
fractional change in molecular weight
31
Oxidative Degradation
  • usually involves the abstraction of an H to yield
    an ion or a radical
  • direct oxidation by host and/or device
  • release of superoxide anion and hydrogen peroxide
    by neutrophils and macrophages
  • catalyzed by presence of metal ions from corrosion

32
Poly(Carbonates)
PEC in vivo
M. Acemoglu, In. J. Pharm. 277 (2004) 133-139
33
Enzymatic Degradation
  • Natural polymers degrade primarily via enzyme
    action
  • collagen by collagenases, lysozyme
  • glycosaminoglycans by hyaluronidase, lysozyme
  • There is also evidence that degradation of
    synthetic polymers is due to or enhanced by
    enzymes.

Z Gan et al., Polymer 40 (1999) 2859
C.G. Pitt et al., J. Control. Rel. 1(1984) 3-14
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