Introduction To Amalgam Restorations PDF

Summary

This document provides an introduction to amalgam restorations, covering topics such as classification, particle geometry, zinc content, and mercury/alloy ratios. It also details setting reactions, properties, and biological effects, along with hygiene recommendations and the potential controversy surrounding mercury use.

Full Transcript

INTRODUCTION TO
AMALGAM RESTORATIONS
(Sturdevant, ch. 19, pg. 339-358).

DENTAL AMALGAM
• Alloy made by mixing mercury (Hg)with silver tin dental amalgam alloy (Ag-Sn)
• Amalgam alloy is a silver-tin alloy to which varying amounts of copper (Cu) and Zinc
(Zn) are added.

• alloy particles mixed with mercury that produce a
matrix of mercury reaction products surrounding
residual dental amalgam alloy particles

BEFORE REACTION

Alloy
Mercury

AFTER REACTION
Alloy
Reaction
Products

Classification
I) According to the cupper content:
• A) Low-Copper Amalgam
• B) High-Copper Amalgam:
Silver
(Ag)

Tin
(Sn)

Copper
(Cu)

Zinc
(Zn)

Low Cu

70%

25%

4%

1%

High Cu

60%

27%

13%

0%

II) ACCORDING TO
PARTICLE GEOMETRY:
• Alloy is produced predominantly as
irregular-shaped particles, spherical
particles, or mixture of the two types
A) Spherical Amalgam

B) Lathe-cut particles Amalgam
C) Admixed Amalgam

• Irregular particles are generally “lathe-cut,” meaning
that the ingot of alloy material is pulverized by filing
it to pieces on a lathe
• Spherical particles are created by atomizing or
spraying liquid dental amalgam alloy through a nozzle
into a vertical column of cooled nitrogen gas. This
solidifies the spheres and protects them from
oxidation during the cooling steps
• Melting

/ Casting / Comminution  IRREGULAR Particles

• Melting

/ Spray Atomization  SPHERICAL PARTICLES

III) ACCORDING TO ZINC CONTENT

• Zn was usually added to conventional amalgam s
as a processing aid to suppress oxidation during
manufacturing.
• A side effect of the residual zinc was that
moisture contamination before setting convert
the zinc to zinc oxide and produce hydrogen gas
that could expand the amalgam
Zn + H2O
ZnO + H2
A. Zinc Free Amalgam
B. Zinc Containing Amalgam: usually less than 1%

MERCURY/ ALLOY RATIO

• The principal considerations for any amalgam are the
amount of mercury in the final restoration and the type of
reactions products formed
• Originally, dental amalgams had relatively high Hg/alloy
ratios

• During the 1900s, the excess was removed by squeezing the mass with a squeeze
cloth before placement and by compressing the placed mass within the cavity
preparation. This reduced the final Hg/alloy ratio well below 50:50 by weight.
Compressing (condensing) extrudes excess matrix from the setting mass and
improves both strength and corrosion resistance.

• Most contemporary mixtures (pre-capsulated) are now
made with 45-55% initial mercury and end up with about
42% after the reaction and condensation steps are
complete.

• Proportioned alloy and
mercury in prepackaged
capsulres (Precapsulated)
for
mixing
amalgam
constituents
using
an
amalgamtor
• Mercury
and
powder
separad by septum that
must be perforated before
mixing

SETTING REACTION
Ag: Silver
Sn: Tin
Cu: Copper

Primary reactant
Creates solubility, fluidity
Reacts with Sn
( Increase strength and hardness)

Zn: Zinc

Alloy processing aid
(oxygen scavenger ,Oxidation)

Hg: Mercury

Reactant with Ag (and Sn)

Copper:
• Improves the strength
• Increases hardness of mix
• Improves resistance to corrosion
Silver:
• Gives amalgam strength
• Increases set expansion
Tin:
• Makes the mixture more workable and decreases
the expansion

Low-Copper Dental Amalgam:
Ag3Sn

gamma g

+ Hg 
+

Hg 

Ag3Sn

gamma g +

+ Ag2Hg3 +

gamma-1 g 1 +

Sn7-8Hg

gamma-2 g-2

High-Copper Dental Amalgam
Ag3Sn+ Hg  Ag3Sn
g

g

+ Ag2Hg3 +
g -1

Sn7-8Hg

SnHg (gamma-2) + Cu  CuSn + Ag2Hg3
Cupper-Tin replace Tin-Mercury Phase

g -2

GAMMA – TWO PHASE
(TIN-MERCURY)
• Although (Sn-Hg) is less than 10% of the final
composition, it is highly prone to corrosion (surface
and subsurface deterioration).
• In high copper amalgam, the (gamma – 2) phase is
minimized or eliminated when excess copper
preferentially reacts with the Sn forming Cu-Sn.
• The resulting copper reaction (cupper-tin) Cu-Sn is
much less corrosion prone than tin-mercury phase
they replace.

• Sn-Hg (g-2) crystals are elongated and look like
blades. While the Sn-Hg crystals represent relatively
little total volume of the mixtures, they tend to be
touching (connected) throughout the entire dental
amalgam (allowing “penetrating corrosion” to take
place
• Penetrating corrosion generates a porous and spongy
amalgam with minimal mechanical resistance.

LOW-CUPPER AMALGAM

+ Hg 

+
g

+
g1

g2
Penetrating
Corrosion

High Cu Amalgam
+ Hg 
g
60 Ag
27 Sn
13 Cu
0 Zn
DISPERSALLOY

+

g

+

CuSn

g1
no Sn-Hg (gamma2) remains in the
set amalgam as
shown.

DIMENSIONAL CHANGES
• Contraction results as the particles dissolve and the g1 grows.
• If there is sufficient liquid mercury present to provide a plastic
matrix, expansion will occur when g1 crystals impinge against
one another
EXP (+)

± 20 mm

CONT (--)

TIME

Dimensional changes on depend on reaction variables:
Particle size, Hg/alloy ratio, trituration time, condensation, ...

• Dissolving the amalgam alloy into Hg and formation of Ag-Hg
crystals leads to a slight decrease in volume (contraction).
Most of this occurs during the mixing process.
• Growing crystals push on each other and create expansion.
Most of this occurs during placement and condensation.
• Depending on the time of condensation and extent of reaction,
the volume change may vary anywhere from -20 to +20
microns per cm over the setting reaction. Over long periods
of time (weeks to a month) the reaction will slowly continue
and can produce small amounts of solid state creep as well.

Physical Properties
1. Thermal conductivity = [High]
2. Electrical conductivity = [High]
3. Coefficient of thermal expansion =
(tooth :10 ppm)

25 ppm/ºC

MECHANIC AL PROPERTIES

• High Compressive Strength : range from

•
•
•
•

(380 to 550 MPa
Dental enamel has a compressive strength of
400 MPa.
Low tensile Strength : 45 MPa (brittle)
Amalgams that have inadequate bulk to
distribute stress may fracture. At margins,
where amalgam margins are less than 90
degree, marginal fracture could occur.
High wear Resistance

STRENGTH:

• Resistance to compression forces is the most favorable
strength characteristic of amalgam.
• Amalgam cannot withstand high tensile or bending stresses.

• Mercury content ( Hg

Strength)

Excess Hg left  reduction in strength

• Trituration
• Either undertrituration or overtrituration effects the
strength
• Overtrituration  increases strengths in lathe-cut alloys
• Both over- and undertrituration  decrease strengths in
spherical alloys and admixed high-Cu alloy

Trituration
• Process of mixing the silver alloy with the mercury
―
―

Mechanical device (Amalgamator)
Proper trituration is essential for clinical success

• Undertrituration
―
―
―

Dull, crumbly appearance
Insufficient mass formation
Poor compressive and tensile strength

• Overtrituration
―
―
―

Shiny and soupy, adhere to the inside of the capsule
Overformation of the matrix
Poor strength and creep, poor corrosion properties
Under

Proper

Over

• Amalgam strength decreased when:

1. There is excess mercury in the mix
2. corrosion has occurred

3. inadequate bulk
4. improper manipulation

PROPERTIES OF AMALGAM
II) CHEMICAL PROPERTIES:
CORROSION
• Dental
amalgam
restorations
undergo both chemical and
electrochemical corrosion
• Chemical corrosion (Tarnish):
occurs most notably on the occlusal
surface and produces a black Ag-S
tarnish film. This reaction is limited
to the surface and does not
compromise any properties, except
for esthetics (Discoloration).

CHEMICAL
CORROSION:

• Electrochemical corrosion:
Occurs whenever chemically different sites act as an
anode and cathode. This required that the sites be
connected by an electrical circuit in the presence of
an electrolytes (saliva). The anode corrodes, producing
soluble and insoluble reaction products. If an amalgam
is in direct contact with an adjacent metallic
restoration such as a gold crown, the amalgam is the
anode in the circuit. This type of electrochemical
corrosion is called galvanic corrosion

• During
electrochemical
corrosion of low-copper
amalgams, the Sn-Hg phase
is oxidized into Sn-O. Sn-O
helps seal the space against
the micro-leakage
• Electrochemical corrosion
of Sn-Hg does not appear
to release free mercury
into the oral cavity

CREEP

• Amalgam creep is plastic deformation principally due to
very slow metallurgic phase transformations and produce
volume increases. The associated expansion makes the
amalgam protrude from the tooth preparation. Such
secondary expansion can occur throughout the clinical life
of a restoration.

• On non-occlusal surfaces,
the
entire
amalgam
restoration may appear
extruded, and this can
produce unwanted esthetic
problems or over hangs in
some areas. On occlusal
surfaces,
abrasion
and
attrition tend to limit the
overall extrusion

CREEP OR MERCUROSCOPIC
EXPANSION
• Over long terms there is a slow
continuation of the amalgam
reaction that produces expansion
and causes creep. Since corrosion
may be occurring at the same time,
as Sn is consumed, local Hg
becomes available that reacts with
residual Ag-Sn particles and
produce more Ag-Hg.

• This leads to further expansion
(and creep) – and extrudes the
amalgam margins above the
normal
anatomic
contours
allowing local stresses to fracture
the margins
• Marginal fracture of amalgam is
known as “Ditching”

Biological Properties
Mercury Toxicity:
The mercury content in amalgam restorations is much
lower than the toxic levels of mercury

Mercury Hypersensitivity:
A very small number of people (< 1 in 100,000,000
patients) may be allergic to Hg. The reactions
are low level (not life threatening).

• Biological effect on the pulp:

• Biocompatible but pulp irritation comes from:
- Electrical conductivity
- Thermal conductivity
- Micro-leakage
- Masticatory and condensation forces in deep cavities.
So, pulp should be protected under amalgam and the
dentinal tubules should be sealed

OTHER PROPERTIES

• Optical: Non-esthetic
• Adhesion: Non-adhesive but
amalgam bonding systems are
available.
• Micro-leakage: it requires initial
sealing by either varnish or
bonding agents till corrosion
products Sn-O seals the
restoration/cavity interface.

MERCURY CONTROVERSY

• Mercury has the potential to be hazardous if not managed
properly
• In amalgam restoration, Once the reaction is complete,
only extremely minute levels of mercury can be released,
and those are far below the current health standard.

• All published research demonstrates
clearly that there is no cause-and-effect
relationship
between
amalgam
restorations and other health problems.
• Fears of amalgam are not a basis for
amalgam removal
• The health risk from amalgam use is
clearly greater for members of the
dental office team that for a patient.

SOURCES OF
MERCURY IN THE
CLINIC:
1. Amalgam raw materials being stored for use
2. Mixed but unhardened amalgam during
trituration, insertion, and intra-oral
hardening
3. Amalgam scrap
4. Amalgam undergoing finishing and polishing
5. Amalgam restorations being removed
• Storage locations should be near a vent that
exhausts air out of the building.

• In set dental amalgam, the Hg which was mixed with
alloy resides only in the matrix phase (predominantly
Ag-Hg).. The matrix melts at 127 C and so just above
the boiling point of water, you can melting dental
amalgam and release Hg from the matrix phase (e.g.
polishing, amalgam removal)
• Rubber dam, high volume evacuation and water
cooling is essential during amalgam polishing or
removal
• Masks are not able to filter mercury vapor from the
air.
Amalgam Melting Piont = 127 C

• Once Hg is released as vapor it can be breathed and absorbed into your system...

•

TLV: Threshold limit value for exposure to mercury
The level is extremely small (5 ppb) but still it is relatively easy to stay
3 below the
vapor
for
a
40-h
work
week
=
50
mg/m
level

•
A.
B.
C.

Hg exists in three basic forms:
Elemental (pure Hg)
Inorganic: found in nature e.g. HgS in mines
Organic mercury (primarily as dimethyl
mercury for its use in farming as a fungicide
and pesticide). It absorbed by many
organisms and concentrated in food .

SOURCES OF MERCURY IN
NATURE:
• Volcanic eruptions
• This vapor gradually is deposited in the world’s
oceans.
• Concentrated in large fish e.g. swordfish and tuna
(top of the ocean food chain). Within them, the
concentration of mercury is 1000 mg/kg of mass.
• Fungicides and herbicides to coat seeds used to plant
farm fields
• Industrial Pollution: e.g coal burning, Minamata Bay
incident in Japan 1952
• Mercury Mine

Mercury mine workers
300mg/m3



SYMPTOMS of chronic Hg poisoning:

1.

Ataxic gait.

2.

Convulsions.

3.

Numbness in mouth and limbs.

4.

Constriction of visual field.

5.

Difficulty in speaking.

• Absorption into the human body occurs via:
A. The skin,
B. Lungs, and/or
C. Gastrointestinal tract.
• As a vapor, metallic mercury can be inhaled and
absorbed through the alveoli in the lungs at 80%
efficiency. This is clearly the major route of entry
into the human body. Metallic mercury is poorly
absorbed through the skin or via the GIT.
• Organic mercury is not practically absorbed in the
lungs but is readily absorbed in the GI tract.

• Mercury does not collect irreversibly in human tissues.

• On average, the half-life Hg circulating in the body is 55 days.
• Thus, mercury that came into the body years ago, is not longer present in the body.

DENTAL MERCURY
HYGIENE
1.Be awareRECOMMENDATIONS
of the potential sources of mercury vapor
2.Because mercury vaporizes at room temperature, work in wellventilated spaces with fresh air exchanges and outside exhaust
3.Periodically check the dental operatory atmosphere for
mercury vapor
4.Floor covering should be non absorbent
5.Use only pre-capsulated alloys
6.Avoid skin contact

7. Use high-volume evacuation when finishing or
removing amalgam
8. Store all scrap amalgam (i.e. amalgam remaining
after a procedure) in tightly closed container
containing radiographic fixer solution. Recycle
amalgam scrap
9. Do not place mercury-contaminated materials in
medical waste bags because these will be burned
and mercury will be vaporized.