Cariology 1 - Lectures 1-5 PDF

Summary

This document contains lecture notes on cariology, covering introductory topics such as Personal Protective Equipment (PPE) protocol, bur anatomy, handpieces, and materials. The document also discusses tooth nomenclature and resin composites.

Full Transcript

Cariology 1 - Lectures 1-5

Lecture 1 - Intro to Cario, PPE
I. PPE Protocol
A. Donning - Gown, Mask, Goggles/Loupes, Face Shield, Gloves
B. Doffing - Gloves, Face Shield, Goggles/Loupes, Mask, Gown

Lecture 2 - Burs and Handpieces
I. Bur Anatomy
A. Head, Neck, Shank

B. Materials - Carbide, Diamond, Steel, Ceramic
C. Grit -
1. Diamond - ^ Grit, v microns
2. Carbide - ^ Grit, ^ # of Blades
II. Handpiece Primer
Handpiece Bur Width Gear Ratio Speed Range Torque

Friction Grip (FG) 1.6 mm 1:5 500 - 200,000 0.7 Ncm

Right-Angle Latch (RA) 2.35 mm 1:1 60 - 40,000 3.5 Ncm

Lecture 3 - Rubber Dam shit that we’ve done like 50 billion times just figure it out

Lecture 4 - Tooth Nomenclature
I. Jaw
A. Maxilla on top, mandible on bottom
II. Dentition
Arch Total # Incisors Canines Premolars Molars Universal
Numbering

Primary/Deciduous 20 8 4 0 8 Letters from UR

Permanent 32 8 4 8 12 #’s from UR
III. Succedaneous Teeth - Permanent teeth that replace deciduous teeth
 A. Permanent Incisors, Canines, and Premolars (#4-13, #20-29)
IV. Non-succedaneous Teeth
A. Permanent Molars (#1-3, #14-19, #30-32)
V. Diphyodont - having two sets of teeth throughout a lifetime
VI. Natural Tooth Curvatures
A. Curve of Spee/Anteroposterior Curve - natural mandibular rounding of occlusal
surfaces

B. Curve of Wilson/Mesiolateral Curve - natural mandibular rounding of teeth
lingually

VII. Tooth Numbering Systems
A. Universal

B. FDI
 C. Sextants - organizes anterior/posterior teeth

D. Palmer Notation

VIII. Tooth Structures/Anatomy
A. Diastema - the gap between occlusal surfaces of teeth
 B. Embrasure - triangular gaps of spacing between teeth faciolingually
1. Incisal/Occlusal Embrasure and Cervical Embrasure

2.
3. Buccalabial Embrasure and Lingual-palatal Embrasure

4.

6) Resin Composites
Composition of Resin Composites
○ Matrix (Organic) - glue, all ends with dimethyl acrylate
BIS-GMA* thickest, circled is acryloyl group
long molecule with rings -> makes it polar -> makes material
thicker, not fluid, thick fillings

UDMA: flowy material, add to BIS-GMA to make flowy
TEGDMA: flowy material
○ Filler Particles (Inorganic) - reinforcement
Inorganic particles - ie quartz, lithium aluminum silicate, zirconia, glasses
(barium, strontium, zinc, ytterbium)
 Reduces polymerization shrinkage, water absorption, and coefficient of
thermal expansion
Size decrease + percentage of FP in composite increase over the years
CURRENT nano-hybrid (0.002-0.075 um @ 72-78% comp. weight)
Filtek Supreme XT (what we use)
78.5% vol. filler particle, good polishability, high strength, light-
cured
○ Coupling Agents (Silanes) - connects matrix and filler particles
Silanes - has both silane group bonds to glasses (FP) and acryloyl group
(Matrix)
○ Optical Modifiers (Inorganic) - pigments (inorganic oxides) to match shade
Fluorescence - LONGER WAVELENGTH ABSORPTION/REFLECTION
Opalescence - SHORTER WAVELENGTH SCATTERING
Opacity - measure of impenetrability to visible light, Enamel > Dentin
Halo - translucency at incisal edge
Elderly patients have less enamel so teeth appear darker
Color Matching Tools - Shade Guide/Spectrophotometer
○ Initiators/Accelerators - speeds up curing process
Chemical - Init. Benzoyl Peroxide, Accel. Organic Amine
Light - Init. Diketone, Accel. Organic Amine
Camphorquinone (CQ) - 468 nm, bluelight
Lucirin TPO - 370 nm, UV
Phenylpropanedione - 370 nm, UV
Dual Cured - uses both initiators
Valolight Light Cure - 395-415 nm and 440-480 nm
Polymerization - Acryloyl groups’ (DB’s in matrix monomers are reduced and fused with
the help of light/heat/chemicals
○ Three types
Linear
Branched
Crosslinked
○ 3 Steps
Initiation - benzoyl peroxide (BPO) initiator breaks its’ O-O bond to
produce O free radicals which goes onto reduces acryloyl group
Propagation - reduced DB on acryloyl group continues to reduce further
acryloyl groups
 Chain Transfer - sometimes reduced acryloyl chain 1 can regain its
double bond by reducing another acryloyl chain 2, but acryloyl
chain is now reduced and goes onto propagate reaction
Termination
Scenario 1) 2 reduced acryloyl chains reduce each other and form
a single bond
Scenario 2) 2 reduced acryloyl chains reduce each other and form
one chain with DB and one separate chain with SB
○ Polymerization Inhibitors -
Conversion Rate - 50-70%, rigidity increase with propagation
Eugenol - temp fillings/cements
Peroxide - bleaching
Oxygen Inhibiting Layer (OIL) -
Oxygen in air oxidizes superficial acryloyl groups and inhibits chain
propagation
Facilitates polymerization of iterative composite layers
4-84 mm thick
Reduces mechanical/physical properties, prone to staining
Remove OIL by polishing at end of composite layering
○ Polymerization Shrinkage - ~2-10% as monomers get closer together
C-Factor - bonded surfaces/unbonded surfaces
^ C-Factor = ^ shrinkage stress
Class I + V have greatest stress
^ monomer size = v shrinkage
Effects - debonding, gaps, microleakage, secondary caries, enamel
microcracks
Can Fix By - smaller fillers, larger monomers, soft-start curing lights, layer
composites in 2mm increments to lower C-Factor
7) Cavity Classifications and Principles of Cavity Preparation
Caries Classifications
○ Class I – O
All pit and fissure preps
○ Class II - M and/or D + O optional on post.
Proximal surfaces of posterior teeth
○ Class III - M/D/L/F no I on ant.
Proximal surfaces of anterior teeth not including incisal edge
○ Class IV - M/D/L/F + I on ant.
Proximal surfaces of anterior teeth including incisal edge
○ Class V - gingival third of facial/lingual surfaces
Abfraction - cervical/wedge-shaped defects due to grinding
Abrasion - friction w/ external objects
Erosion - chemico-mechanical action
○ Class VI - incisal (ant.) and or occlusal (post.) cusp tips
Point Angles - points of junction of 3 or more prep. Walls
Objectives of Tooth prep
○ Preserve healthy tooth structure
○ Remove diseased structure
○ Provide restorative form
○ Esthetic reimplementation
Steps for Preparation:
1) Initial Depth + Outline Form
○ 0.2 mm beyond DEJ/0.5-0.8 mm into root suraces
○ Visualize shape of prep, 90 deg of prep
2) Primary Resistance Form
○ Maintain 90 deg. To axis of preparation
○ Enhance stability of a restoration along an axis other than path of placement
○ ie round internal angles to resist cracking, remove unsupported tooth structure
(unsupported enamel rods), pulpal/gingival floors perpendicular to occlusal
forces
3) Primary Retention Form
○ Prevents dislodgement of a crown in vertical direction/ path of placement
○ ie undercuts, grooves, slots or pins
○ Secondary retention forms - grooves to prev comp from falling out or parapulpal
pins, not common anymore
4) Convenience Form
○ Features to facilitate procedure/make the area more accessible
 5) Removal of defective restorative materials/soft dentin
6) Pulp protection
7) External Wall Finishing
8) Final Procedures - debridement/inspection

8) Magnification
Resolution - smallest distance between two points to perceive them separately
○ Unaided eye resolution = 200 um
Ergonomics - position 1-4, 1 = 0 deg declination, each position increases angle by 15 deg
Declination Angle - angle that eyes are inclined downwards toward work
Head Angle - head tilt angle
Viewing Angle - declination angle + head angle
Loupes -
○ 1) Simple Lens - 1 convex lens
prone to distortion, makes objects bigger
Binocular simple can cause spheric operation and chromatic operation
distortion
○ 2) Compound/ Galilean Lens - 1 convex (converging) + 1 concave (diverging) lens
No distortion with dual lenses
limited magnification due to length
^ length = ^ magnification = v image lighting
○ 3) Prismatic/ Kepler Lens - multiple convex lenses
Schmidt-Pechan Prism - flips image back to correct orientation
^ magnification = v field of view = v field of depth
CAN BE ANGLED - so fixes declination angle
○ 1) Through-the-lens (TTL) Loupes -
Custom-made, closest to eyes, prescription possible
○ 2) Flip up Loupes
Off-the-shelf, further, prescription possible, adjustable, can be shared
○ Frames -
Metal Frame
Sports Frame
Head Gear - ADJUSTABLE, uncomfy
○ Add ons - light or light+battery, orange filter for composite preps
Microscopes
○ Advantages - less eye convergence strain, no declination angle
○ Tube head reorients light
 ○ End Magnification = Tube focal distance/lens focal distance * mag. Changer
factor * eyepiece factor
9) Posterior Composite Restorations
Prim. Caries Indications - (when we can restore posterior teeth using direct composite
resin)
○ Primary carious lesions
Secon. Caries Indications - (when we can restore posterior teeth using direct composite
resin)
○ Replacement of composites and amalgam restorations
Contraindications – when we cannot restore
○ Large restorations - use indirect
○ Inadequate Isolation
○ Heavy Occlusal Stress
○ High Caries Risk
○ (LIHH) – Live In His House
Composite Advantages
○ Esthetics, conservative, less complex, decreased microleakage, increase strength
of remaining tooth structure
Composite Disadvantages
○ Polymerization shrinkage
○ Lower fracture toughness vs. indirect
○ More technique sensitive
○ Possible greater occlusal wear
○ BPA could be used (similar to estrogen)
Protocol
○ 1) Anesthesia
○ 2) Pre-op. Occlusion - articulation paper
○ 3) Prophylaxis - clean w/ pumice
○ 4) Color Matching - shade match, do before RD placement
○ 5) Operative Field Isolation - RD
○ 6) Cavity Preparation - drilling
○ 7) Adhesive System - 35% phosphoric acid etchant, bond
1) Etch + Rinse (total etch)- etch > dessicate > primer > dessicate > bond >
LC
2) Etch + Dry (self etch) - primer/etch hybrid > dessicate > bond > LC
3) Selective Etch - differentiates in dentin/enamel
NOTE* single step bond/etch SUCKS
○ 8) Composite Placement - refer to chapter 7
 ○ 9) Final Light Cure
○ 10) Check Occlusion - articulation paper
○ Finish and Polish

10) Temporary Direct Restorations
1) Zinc-Oxide Eugenol (reinforced w/ PMMA)
○ Curing - Self-cured (liquid + powder)
○ Base protective restoration
○ Inhibits polyermization!!!
○ Can soothe teeth but increased internal tooth inflammation (NOT USED)
2) Calcium Sulfate (gypsum) - (ie CAVIT)
○ Curing - Hygroscopic setting - hardens with water
○ Class I or C II
○ High expansion
○ LONG 2-hour setting time
○ Procedure - scoop to mixing pad > shape w/ instrument or bite > moisten w/ wet
cotton > can use slow carbide bur/cavitron to remove
3) Light-cured Resin (ie Telio Onlay 20s LC)
○ Curing - Light-cured
○ Contains trace fluoride
○ For temping inlays/ onlays/ implant screw healing
4) Glass Ionomer Cements (Class Vs)
○ a) Cavity Liner - inner coating to cover prep. walls, seals tubules and pulp
Helpful for amalgam which is thermoconductive
○ b) Base/restorative Foundation - blocks undercuts, thermal/chemical barrier,
saves on cost of expensive indirect rest.
○ c) Build Up - provides coronal anatomy to endo-treated tooth
○ Acid-Base Reaction - Calcium-Aluminosilicate w/ Polyacrylic Acid, chemically
bonds to tooth as opposed to composites which adhere
Tartaric Acid as accelerator, Silver to mimic amalgam
Liquid Acid attacks Glass Base > glass releases Ca/Al cations and F >
cations cross-link to form salt matrix w/ polyacrylic acid
note - fluoride released can form fluoroapatite/fluorohydroxyapatite but
diminishes in effectiveness in 2 weeks, can replenish with F-varnish
^ F release v Mechanical Properties
GIC > RMGIC > Compomers > Composites
○ Sensitive to moisture, can apply protective varnish
○ Fuji IX -
 Mixing Time - 10s
Working Time - 2 min/ 120 s
Setting Time - 6 min/ 360 s
Powder to Liquid Ratio - 0.4/0.11
5) Resin Modified Glass Ionomer Cements (ie Fuji 2LC and Fuji Triage)
○ Adds Methacrylate Polyacid matrix + amphipathic HEMA
○ A/B rxn AND Polymerization for increased stability
○ HEMA has alcohol group for salt matrix and DB for composite matrix reduction
○ 1) Fuji 2LC - dual-cured, resin-modified, protective for C III and C V
Mixing Time - 10 s
Working TIme - 3 min 15 s/ 195 s
Light Curing Time - 20 s
Depth of Cure - 1.8 mm
Powder to Liquid Ratio - 0.33/0.1
○ 2) Fuji Triage - pink
Mixing Time - 10 s
Working Time - 1 min 40 s/100s
Setting Time - 2 min 30 s/150 s
Powder to Liquid Ratio - 0.3/0.15
○ Protocol
1) Apply Cleaners - cavity conditioner + 20% polyacrylic acid and rinse
2) Activate
3) Mix - 7 s, not full 10 s to have more time
4) Dispense w/ gun
FILTEK SUPREME ULTRA NANOFILLERS
TELIO ONLAY - LC

Lecture 11 - Enamel and Dentin
3 Stages of Tooth Development
○ Bud - (6th week prenatal)
Formation of buds onto the dental lamina
Ectomesenchyme Cells - Ectodermal cells from epithelium proliferate into
underlying mesenchyme
○ Cap - (9th or 10th week prenatal)
Bud enlarges into a cap shape, forming enamel organ, dental papilla, and
dental follicle
○ Bell - (11th or 12th week prenatal)
The tooth’s crown develops (ergo bell shape) and develops hard tissue
 Separates from the dental lamina
Enamel
Composition - 88% inorganic, 2% organic, 10% water
Inorganic - Amelogenesis
○ Ameloblast - cell elongates, nuclei moves to top of cell, distal parts differentiate
into wedge-shapes
Secretory Stage - ameloblasts secrete hydroxyapatite crystals from the
Tomes Processes which are positioned at distal end of the ameloblast to
form enamel rods
Maturation Stage - more minerals secreted (Calcium and Phosphate) to
harden the enamel rods
○ Enamel Rods -
HA Crystals - 25 nm thick, 100 nm wide, 500-100 nm long, arranged into 5
um rods, wrapped in 1 um protein sheath
Arranged perpendicular to DEJ, parallel to each other
Crystals near edge of the rod can tilt (15-45 deg) to have more force
dispersion
3 main enamel structures - sheath, rod, and inter-rods (connecting
structures)
Organic -
○ Proteins - amelogenin, ameloblastin, enamelin, tuftlelin
Regulates enamel growth, promotion, termination, and organization
○ Enzymes - metalloproteinases (MMP), proteinase, phosphatase
Regulates enamel/dentin and affects bonding

Enamel Thickness Across Tooth - gets thiccer as you go up tooth from CEJ
○ Gingival 1/3 - 0.3 - 0.4 mm
○ Middle 1/3 - 0.5 - 0.6 mm
○ Incisal 1/3 - 0.8 - 1.0 mm
Enamel Structures (SCHOITL)
○ Striae of Retzius/ Retzius Line
Incremental growth lines, suggests successive deposition of enamel
layers
Perikymata - retzius lines on superficial teeth surface, gives teeth texture
○ Enamel Cross Striations
Demarcate enamel deposition by ameloblasts DAILY (4 um/ day, ranges
from 2.5-6.5 um)

○ Hunter-Schreger Bands (HSBs)
Set of 10> rods, related to synchronous decussation of enamel rods
Reflects light differently
Structural adaptation that increases enamel strength (found prominently
in occlusal surfaces like posterior teeth cusps)
○ Outer Enamel
Rigid, parallel rods arranged perpendicularly to DEJ
Higher rigidity
The outermost layer contains aprismatic enamel
Aprismatic enamel: no pronounced or no rods at all. Hardest layer
of enamel
○ Inner Enamel
Closer to DEJ, more rod decussation (crossing over)
Higher elasticity (aka lower modulus of elasticity) (Dissipates force)
Increased organic content
Contains enamel tufts
○ Enamel Tufts
Brush-like structures extending directly from DEJ
Hypomineralized and protein-rich to provide cushioning
○ Enamel Lamellae
 Fissure-like projections further from DEJ
Includes proteins, proteoglycans, and lipids
Enamel Disorders -
○ Dental Fluorosis
Increased enamel porosity along Retzius Lines
Hypomineralized lesions through enamel caused by Fluoride ions
reducing HA producing excess fluorapatite
○ Amelogenesis Imperfecta
Genetic
Hypocalcification - defect in the secretion stage
Hypomaturation - defection in the maturation stage
Hypoplastic - defect in amount of enamel
DEJ
Scallop-apperance: 30 um incisors and 43 um molars, convexity directed toward dentin
○ Prevents enamel cracks from permeating into dentin
○ More durable along enamel side
Dentin
Composition - 50% inorganic, 30% organic, 20% water
Organic
○ 90% Type I Collagen - trace Type 3 and 4
○ 10% Non-collagenous components:
Proteins: Amelogenin, Osteonectin, Osteocalcin
Enzymes: MMPs, tissue inhibitors of MMPS (TIMPS), acid/alkaline
phosphates
Lipids
Growth Factors
Inorganic
○ Crystallites: 2-5 nm thickness, 60 nm length, needle-like
Dentin Structures
○ Dentinal Tubules - holes from DEJ to pulp
Water, fluids, odontoplastic processes
More tubules closer to pulp in deep dentin vs superficial dentin
(45,000/mm2 vs 20,000/mm2)
○ Peritubular Dentin - highly-calcified and surrounds/protects tubules
96% HA crystallites (25-30 nm)
4% organic content
Hardness: 2.23-2.5 GPa resistance force
○ Intertubular Dentin - space between tubules
 88% HA crystallites (2-5 um and 60 nm long)
12% organic content: collagen-rich and proteins
Hardness: ~0.5 GPa near DEJ to ~0.16 GPa near pulp
Types of Dentin
○ Primary - initial dentin formed near DEJ after eruption
○ Secondary - dentin formed between initial tooth formation and remaining life of
tooth
○ Tertiary - reactive/reparative dentin formation
Reactionary Dentin - odontoblast/Hoehl’s cell calcification response to
anything (caries, prep, abrasion, erosion, attrition, toxicity etc...)
Reparative Dentin - formed in response to pulp exposure
Dentin Bridge - barrier formed to protect exposed pulp
○ Sclerotic Dentin - formed due to occlusion and hypermineralization of superficial
tubules
Example: non-carious cervical lesions (NCCLs) near CEJ
Air pushes odontoblasts down exposed tubules, increases calcification
Brannstrom’s Hydrodynamic Theory - air/temp/pressure moves
odontoblasts in tubules, triggering main response in pulp
Dentin Disorders -
○ Dentinogenesis Imperfecta - genetic mutation of DSPP gene, producing soft
dentin (discolored), lack of dentin tubules and lack of cushioning collagen
Type I - COL1A1/COL1A2 causing osteogenesis imperfecta (all bones),
brittleness to all bones
Type II - most common, associated with hearing loss
Type III - common in South Maryland and Ashkenazi Jews

Lecture 12 - Caries
Scale: perm. 2.3 billion, deci. 0.5 billion
Prevalence: proportion of the population
Incidence: new cases
Caries - transmissible, infectious oral disease caused by interaction between cariogenic
oral flora (biofilm) with fermentable carb sources on tooth over time
○ Vertical Transmission - bacteria from higher generation, eg. mom -> baby
○ Horizontal Transmission - same generation, eg. sibling -> sibling
○ Protective Factors - salivary flow, proteins, antibacterials, fluoride, ions
(calcium/phosphate), protective diet (non-cariogenic sweeteners like xylitol)
○ Pathological Factors - acidogenic bacteria, fermentable carb. ingestion,
xerostomia
 Cariogenic Challenge - oral flora converts mono/di saccharides into pyruvic acid
(glycolysis) and then lactic acid (lactic acid fermentation)... or propionic/acetic acid
○ Stephan Curve - acid drops pH (< 5.5 pH), demineralizes enamel, saliva/enzymes
neutralize pH

○
note higher threshold pH for dentin because it’s more sensitive
Microbiology
○ A) White Spot Lesions/ Initial Caries - like an initial scar, strep. mutans
○ B) Dentinal Caries/Tubule Infection - more lactobacillus
○ C) Root Caries - actinomyces attracted to roots specifically
Caries Factors: Time and Teeth (external) and Bacteria and Diet (internal)
○ Teeth - most prevalent: pits/fissures > root/cervical > interproximal

Higher prevalence in restorations/ortho appliances as they introduce
man-made overhangs for bacterial growth
○ Bacteria/Time -
1) Pellicle (0-24 hrs) - thin glycoprotein layer, electrostatically sticks to
enamel, acts as a primer for bacterial growth recruiting more bacteria

2) Biofilm Formation (4-24 hrs) - co-adhesion of bacteria, microcolonies
3) Microbial Succession (1-7 days) - bacterial diversification
 4) Climax (>1 week) - mature biofilm, plaque build-up
Resident Oral Flora - Gram+/Gram- bacteria, yeasts, other microbes
Symbiotic Relationship - takes space from bad bacteria, produces
peroxide, kills bad bacteria, secretes inhibitory factors
Ecological Plaque Hypothesis - current theory, many carious
bacteria but also depends on environment

○ Diet
Mono/di saccharides are hardest to break down with saliva
Amylase and other salivary enzymes can break down complex sugars
Sugar Alcohols - alt. Sweeteners with anti-cariogenic properties, eg.
xylitol, lactitol, isomalt
Lesion Progression -
○ Sub-surface lesion under surface layer
○ H+ in and Calcium/Phosphate out
○ Pore volume increases up to 30%, and microorganisms and substrate permeate
○ Light scattering causes white spot

○
○ 1) White Spot - acid travels to dentin tubules, forming sclerotic dentin
○ 2) White/Brown Spot - demineralized dentin and tubules near DEJ and formation
of tertiary (reactionary) dentin near deep dentin
○ 3) Micro-Cavitation - enamel breaks down, lesion accelerates
○ 4) Cavitation - inorganic tissues disintegrate forming zone of destruction
○ Removed dentin will be wet/leathery
Lecture 13 - Dental Adhesion
Enamel and Dentin require modifications to bond adhesive monomers
(Enamel) Biofilm - oral flora, plaque, debris
(Dentin) Smear Layer - created by handpiece on dentin
○ Composition - amorphous (1-5 um), residual debris/oil from bur
○ Obstructs tubules by 86%
○ Carbide Bur: heat (2um layer) < Diamond: abrasive force (5 um layer)
○ Can be removed with 1.5-3 pH smear layer acid remover
Etch - (35% Phosphoric Acid) creates more surface area, decalcifies enamel
○ Helps with micromechanical retention, clears smear layer, helps adhesive bond
to enamel/dentin (hydrophilic) and resin composite (hydrophobic)
Primer - diffuses etchant across the tooth
○ Contact Angle - lower viscosity, hydrophilic, more surface spread upon
○ Bifunctional Monomers (BFM) - h.philic for enamel/dentin, h.phobic for resin
eg. HEMA, Bis-GMA, 10-MDP, TEGDMA, GDMA, UDMA
○ Solvent - removes water and makes space for BFM, lowers viscosity of bond to
allow for greater permeation
eg. water, ethanol, acetone
Bond - adhesive
○ Smaller BFMs -
eg. Bis-GMA, HEMA, TEGDMA
○ Photoinitiators -
eg. CQ
○ Fillers - inorganic, increases strength
eg. silicon, aluminum, silicon dioxide (2-5 nm)
Mechanisms of Adhesion
○ Micromechanical - STRONGER
Penetration, permeation, and polymerization of resin monomers
○ Chemical -
Chem. bond to HA via ionic bond/salt formation
Chem. bond to collagen via cross-linking covalent bonds
Classification of Adhesive Systems
○ 1) Etch and Rinse
1a) Three-Step: etch, primer, bond
Etch - 35-37.5% phosphoric acid
Primer - highly hydrophilic
Bonding Resin
 1b) Two-Step: etch, primer+bond
Higher concentration of solvents (