Term
|
Definition
| Synthetic mateirials for use in the body |
|
|
Term
Because biomaterials are not as durable as sound tooth tissue it is important to recognize the importance of: |
|
Definition
1. Prevention of caries 2. Conservative treatments 3. Durability of treatments |
|
|
Term
| List the applications of biomaterials in dentistry in order of importance |
|
Definition
1. Prevention of decay 2. Prevention of trauma 3. Realignment of teeth 4. Direct restorations 5. Indirect restorations 6. Prostheses 7. Implants **Lab materials |
|
|
Term
| List the general requirements of biomaterials |
|
Definition
Biocompatability Interfacial properties Chemical properties Mechanical properties Esthetics Practicability |
|
|
Term
Objectives in measuring mechanical properties of materials: |
|
Definition
1- Measure their fundamental properties 2- measure their properties under conditions attempting to simulate service conditions |
|
|
Term
| List bulk properties of a material: |
|
Definition
Viscoelasticity Fatigue Impact Stress-strain |
|
|
Term
| List surface properties of a material: |
|
Definition
Hardness (resistance to indentation Resistance to abrasion |
|
|
Term
|
Definition
| Force per unit area; has units of N/m2 |
|
|
Term
List the five types of stress: |
|
Definition
Tension Compression Torsion Flexur Shear |
|
|
Term
|
Definition
| Strain is the change in length per unit length; it is unitless |
|
|
Term
|
Definition
| Stress is proportional to strain |
|
|
Term
| Define modulus of elasticity (Young's modulus): |
|
Definition
Constant; defines the rigidity of a material; larger slope = more rigid material, smaller slope = less rigid material |
|
|
Term
| Define proportional limit: |
|
Definition
Maximum stress at which stress is proportional to strain |
|
|
Term
|
Definition
| The stress point where strains below are elastic and strains above are plastic |
|
|
Term
|
Definition
| Point where plastic strain becomes very pronounced; rapid inc. in strain without accompanying stress |
|
|
Term
|
Definition
Measure of ductility and maleability related to plastic strain; material with high percentage elongation = ductile; material with low percentage elongation = brittle |
|
|
Term
|
Definition
| Amount of energy a material can abosrob without permanently deforming; Area under the graph up to the proportional limit; has units of energy J/m3 |
|
|
Term
|
Definition
| Amount of energy a material can absorb withour fracture; has units of J/m3 |
|
|
Term
|
Definition
| A material won't break below this limit |
|
|
Term
| Three methods for measuring hardness: |
|
Definition
Brinell's (circle) Vickers (diamond) Knoop (diamond) |
|
|
Term
|
Definition
| Slow deformation of a material under stress |
|
|
Term
|
Definition
A property having plastic and elastic behavior |
|
|
Term
|
Definition
| Natural or synthetic compound of high molecular weight consisting of millions of repaeated linked units |
|
|
Term
| Examples of natural polymers: |
|
Definition
Proteins Polyisoprenes Polysaccharides |
|
|
Term
|
Definition
| Smallest repeating unit in polymer chain |
|
|
Term
| List examples of condesnation polymeraizations |
|
Definition
|
|
Term
|
Definition
| Any organic compound containing the vinyl group CH2=CH- (carbon carbon double bond) |
|
|
Term
|
Definition
1- Acrylic fabric (not relevant to dental biomaterials) 2 - Acrylic resin (aka PMMA) used for dentures 3 - Acrylic acid - water soluble polymer for adhesive dental cements |
|
|
Term
|
Definition
| contains a carbon-carbon doubl bond and a carbon-oxygen double bond, separated by a carbon-carbon single bond |
|
|
Term
| List the stages of polymerization |
|
Definition
1- Generation of free radicals (activation and initiation) 2 - Propagation of the reaction 3 - termination of the reaction |
|
|
Term
|
Definition
| Works on a polymerization initiator |
|
|
Term
| Three types of polymerization activators: |
|
Definition
1 - Heat 2 - Radiation 3 - Chemical |
|
|
Term
| List 4 steps in addition polymerization: |
|
Definition
1 - activator reacts with initiator to give free radicals 2 - Free radicals react with monomers to give larger free radical 3 - Propagation 4- termination |
|
|
Term
|
Definition
| Number of repeating units in a polymer |
|
|
Term
| Effect of molecular weight on polymer |
|
Definition
| Higher molecular weight = higher strength and rigidity |
|
|
Term
Four physical states of polymers |
|
Definition
Elastomers (or rubbers) Hard amorphous polymers (or glasses) Hard paritally crystalline polymers (not relevant) Polymeric fibers (not relevant) |
|
|
Term
| Glass transition temperature |
|
Definition
(Tg)Polymer characteristic determining at what temperature a glass becomes brittle on cooling, or soft on heating High Tg = rigid at mouth temperature Low Tg = flexible at mouth temperature |
|
|
Term
|
Definition
- More elastic, less plastic deformation - May have higher value of Tg - Harder and more brittle - More resistant to action of solvents |
|
|
Term
|
Definition
| Liquid capable of penetrating between the randomly oriented chains of a polymer |
|
|
Term
|
Definition
- Reduces forces between molecules - Result is softened polymer - Polymer may be more flexible (lower Tg) |
|
|
Term
|
Definition
Alternating Random Block Graft |
|
|
Term
| What happens in a viscoelastic material? |
|
Definition
| There is breaking of intermolecular bonds (plastic behavior) and uncoiling of polymer molecules (elastic behavior) |
|
|
Term
|
Definition
| Generally characterized by ductility, luster, conductivity of heat and electricity and ability to replace the hydrogenof an acid to form a salt |
|
|
Term
|
Definition
Material that exhibits both metallic and non-metallic behavior |
|
|
Term
|
Definition
|
|
Term
| List characteristic properties of metal: |
|
Definition
Usually hard Lustrous Dense Good conductor of heat Good conductor of electricity Opaque Ductile and malleable |
|
|
Term
| List methods of forming and shaping metals |
|
Definition
Casting Cold working (forming a smaller diameter of wire) Powder metallurgy Electroforming |
|
|
Term
|
Definition
| positive ions surrounded by a cloud of electrons |
|
|
Term
| List the consequences of metallic bonding |
|
Definition
- Conductivity (movement of electrons) - Opacity to light (electrons absorb electromagnetic energy) - Easily forms alloys - Solid metals can be considered sturcutrally as a regular arrangement of nucle at an equilibrium distance from each other |
|
|
Term
|
Definition
Material showing a long-range regular arrrangement of atoms (all metals are crystalline) |
|
|
Term
|
Definition
| Smallest reapeating unit in a crystal (14 types total) |
|
|
Term
| 3 types of unit cells we must memorize |
|
Definition
Body centered cube Face centered cube Hexagonal close packed |
|
|
Term
| List the types of crystal imperfections: |
|
Definition
Point defects (substitutional and interstitial impurities; vacancies) Line defects (the major reason for malleability and ductility of metals because dislocations propogate through structure; the more dislocations the more ductile a material) Planar defects |
|
|
Term
| Three types of grain structure |
|
Definition
Equiaxed coarse Equiaxed fine Fibrous grain |
|
|
Term
|
Definition
| Stretches inter-atomic bonds and is recoverable |
|
|
Term
|
Definition
| Permanent slip of layers of atoms over each other; the mechanism is the movement of the dislocations |
|
|
Term
| Effect of cold working on metal |
|
Definition
| Leads to a fibrous structure |
|
|
Term
| Effect of stress releif anneal on metal |
|
Definition
| Relieves stresses within the material; a low temperature heat treatment |
|
|
Term
Effect of recrystallization on metal |
|
Definition
| Further heating cuases reformation of equiaxed structure |
|
|
Term
| Effect of grain growth on metal |
|
Definition
| Even more heating causes large grains to form |
|
|
Term
| What happens when a molten alloy solidifies? |
|
Definition
1 - solid solution (one phase) - substitutional (random or ordered) or interstitial 2 - complete solid insolubility (two phases) 3 - partial solid insolubility (one or two phases) 4 - intermetallic compound formation |
|
|
Term
| List five fcc (face centered cubic) metals |
|
Definition
|
|
Term
| List an example of an interstitial solid solution |
|
Definition
| C atoms in Fe resulting in steel |
|
|
Term
| What happens in the solidification of an alloy where there is partial solid insolubility? |
|
Definition
1 - Solid solution formed during solidification and 2 - On cooling precipitation may occur |
|
|
Term
| Give an example of an intermetallic compound |
|
Definition
| Ag3Sn as in amalgam alloy powder |
|
|
Term
| The hardness of an alloy depends on: |
|
Definition
1 - chemical composition 2 - mechanical history 3 - thermal history |
|
|
Term
| Describe a subsitutional solid solution: |
|
Definition
| On mixing of a molten alloy one phase is present. Conditions for formation include: same crystal lattice, similar atomic size, similar chemical valency, and no reaction to form intermetallic compounds |
|
|
Term
| Temperature time curve for a metal |
|
Definition
| This includes the cooling of molten metal phase; solidifying of metal; cooling of solidified material |
|
|
Term
| Effect of chemical composition on an alloy: |
|
Definition
An alloy is harder than any of the individual metals from which it has been prepared Hardness depends on: number of different compounds relative amount of each component |
|
|
Term
| Effect of mecanical history on alloy: |
|
Definition
Cold working Deformation of structure Hinders movement of dislocations Material less easy to deform Harder |
|
|
Term
| Effect of thermal history on alloys: |
|
Definition
| At high temperature there is diffusion which can give harder materials |
|
|
Term
| Dental applications of alloys: |
|
Definition
Amalgam Inlays, crowns, bridges Bonding to porcelain Wires, brackets, bands Implants Instruments |
|
|
Term
|
Definition
| Physiochemical interaction between metal and its environment to form metallic compounds |
|
|
Term
| List factors in oral environment that enhance corrosion: |
|
Definition
pH levels food particles moisture temperature chemical effects |
|
|
Term
| Corrosion in the mouth is undesirable because: |
|
Definition
1 - can be harmful to the body 2 - galvanic pain 3 - weakening of structures 4 - adverse effet on esthetics |
|
|
Term
| Give examples of non-aqueous corrosion: |
|
Definition
Tarnishing of bras Surface discoloration by oxide formation |
|
|
Term
| Aquesous corrosion is an [blank] phenomenon |
|
Definition
|
|
Term
| General condition for occurrence of electrolytic corrosion: |
|
Definition
| Two disimilar metals in contact in the presence of an electrolyte |
|
|
Term
| Define electrode potential: |
|
Definition
| Measure of the tendency of a material to corrode |
|
|
Term
| Important dental examples of passivity: |
|
Definition
Ti forms a protective oxide coating Chromium (Cr) forms a protective oxide coating Gold and amalgam Plate and screw of same alloy (screw may be an anode because of irregular structure) Differences because of electrolyte composition (probably won't happen in the mouth) |
|
|
Term
| How does one prevent corrosion? |
|
Definition
1 - choose materials wisely - must be noble (Au, Pt, Pd) or passive (Cr) 2 - Use materials wisely by avoiding an electrolytic cell situation |
|
|
