Chapter-5-amalgam.pptx

Transcript

Chapter
DENTAL AMALGAM
5
ntroduction
Amalgam has been an accepted part of dental therapeutics
for more than 150 years and is still used for the majority of
direct posterior restorations.

The reasons for its popularity lie in its ease of manipulation

relatively low cost.

a long life.

Some concern has been raised about mercury toxicity from
both biologic and an environmental point of view; however, it
is believed that amalgam presents an acceptable risk-to-
benefit ratio when properly used.
 Overview
Alloy: Alloy is a union of two or more metals

Amalgam: Amalgam is an alloy in which
mercury occurs as a main constituent.

Dental amalgam: The dental amalgam is an
alloy of mercury with silver, tin, and varying
amounts of copper, zinc and other minor
constituents.

*** insert a video, about what is dental amalgam***
AMALGAM
Amalgam is the most widely used
permanent filling in dentistry. It is
prepared by mixing the alloy with
mercury.

The reaction between mercury and
alloy is termed an amalgamation
reaction.

It results in the formation of a hard
restorative material of silvery – gray
appearance
Amalgam Use and
Benefits
Dental amalgam, in widespread use for over 150
years,

One of the oldest materials used in oral health care.

Its use extends beyond that of most drugs, and is
predated in dentistry only by the use of gold.

Dental amalgam is the end result of mixing
approximately equal parts of elements
 liquid mercury (43 to 54%)
 an alloy powder (57 to 46%) composed of silver,
tin, copper, and sometimes smaller amounts of
zinc, palladium, or indium.
 Amalgam
MERCURY (Hg) – is a liquid at room
temperature and it is able to form a
workable mass when mixed with the alloy.

The reaction between mercury and alloy is
termed an amalgamation reaction.

Dental amalgam has been used for many
years with a large measure of success.

It is the most widely used of all available
filling materials.
 Composition
The composition of the alloy powder
particles varies from one product to another.

Composition of CONVENTIONAL
AMALGAM ALLOY:

Metal: Weight:
Silver (Ag)............................ 40-60
Tin (Sn).................................27-30
Copper (Cu)..........................13-30
Zinc (Zn)................................2
Mercury (Hg).........................3
CLASSIFICATION OF
AMALGAM
According to the number of alloyed metals

According to the shape of the particles

According to the copper content of the alloy
- Low copper alloys: contain less than 6% copper
- High copper alloys: contain more than 6% copper

According to zinc content
- Zinc -containing alloys: contain more than 0.01% zinc
- Zinc-free alloy: contain less than 0.01% zinc

According to whether the alloy is unimixed or admixed
Role of each metal
in dental amalgam
Role of each metal
in dental amalgam
 Composition
1. Silver:
Increases strength, expansion and reactivity.
Decreases creep.
Corrosion products are AgCl and AgS.

2. Tin:
Increases reactivity and corrosion.
Decreases strength and hardness.
Corrosion products are SnO, SnCl, and SnS.

3. Copper:
Increases strength, expansion and hardness.
Decreases creep.
Corrosion products are CuO and CuS.
 Composition
4. Zinc:
Increases plasticity, strength and the Hg:alloy
ratio.
Decreases creep.
Causes secondary expansion.
Corrosion products are ZnCl and ZnO.

5. Mercury:
Wets the alloy particles.
Decreases strength if in excess amounts.
Implicated in toxic and allergic reactions.
 In Brief
Silver......................................gives strength

Tin……...…….……………….……workability

Copper….....strength & corrosion resistance

Zinc…………….………….prevents oxidation
Effects on properties of an
amalgam restoration
imparted
PROPERTY by ingredients.
INGREDIENT
Silver Tin Cooper Zinc

Strength Increases

Durability Increases

Hardness Increases

Expansion Increases Decreases Increases

Flow Decreases Increases Decreases

Color Imparts

Setting time Decreases Increases Decreases

Workability Increases Increases

Cleanliness Increases
 Advantages
1. High compressive strength and hardness
2. Ease of use
3. Excellent wear resistance
4. Easy to distinguish between amalgam
and tooth structure
5. Convenience of manipulation
6. Fairly low cost.
 Disadvantage
s
1. Objectionable
2. Mercury hazard
aesthetics (silver color)

3. Amalgam tattoo
4. Non -insulating filling material
 Amalgam:
properties
1. DIMENSIONAL CHANGES
2. STRENGTH
3. PLASTIC DEFORMATION (CREEP)
4. CORROSION
5. THERMAL PROPERTIES
6. BIOLOGICAL PROPERTIES
1. DIMENSIONAL
CHANGES
A large contraction would result in a marginal gap down
which fluids could penetrate.
A large expansion would result in the protrusion of the
filling from the cavity.
A freshly mixed amalgam is condensed into the cavity
preparation, the ideal result is that the amalgam neither
expands or contracts as it sets.
Expansion could result in post-placement sensitivity or
protrusion from the cavity,
Contraction would leave gaps prone to leakage between
the restoration and the tooth
The net contraction or expansion of an amalgam is called
its "dimensional change."
2. STRENGTH
The strength of dental amalgam must be high enough to
resist forces placed on the amalgam restoration in the
mouth.

The strength of dental amalgam is developed slowly.
- 24 hours: 90% to reach a reasonably high value and
continues to increase slightly for some time after that.
- 1 hour: 40 to 60% maximum

15 – 20 minutes after placing the filling , the AMALGAM is
relatively weak.

It is necessary to instruct patients not to apply undue
stress to their freshly placed AMALGAM fillings.
 3. PLASTIC
DEFORMATION
Creep is(CREEP)
a viscoelastic property

Creep is a gradual dimensional change
under load.

Amalgam undergoes a certain amount of
plastic deformation or creep when
subjected to dynamic intra-oral stresses.
 4. TARNISH AND
Tarnish is a surface phenomenon that can result in a
CORROSION
discolored restoration.
Tarnish, the chemical reaction between the amalgam and
the oral cavity are restricted to the amalgam surface.

Corrosion results from chemical reactions that penetrate
into the body of amalgam.
Corrosion is a matter which may significantly affect the
structure and mechanical properties.
The rate of corrosion is accelerated if the AMALGAM filling
contacts a gold restoration.

Smooth surfaces are less prone to concentration cell
corrosion.
 5. THERMAL
PROPERTIES
AMALGAM has a relatively high value of thermal diffusivity.
Dentine is replaced by a good thermal conductor.

The coefficient of thermal expansion value for AMALGAM is
about three times greater than that for dentine.

This results in considerably more expansion and
contraction in the restoration than in the surrounding tooth
when a patient takes hot or cold food or drink.

Thermal expansion may cause microleakage around the
fillings since there is no adhesion between AMALGAM and
tooth substance.

Microleakage plays an important part in initiating such lesions.
 BIOLOGICAL
PROPERTIES
Certain mercury compounds are known to have a harmful effect on the
central nervous system.

Some studies have shown a higher concentration of mercury in the blood
and urine of patients with AMALGAM fillings than those without.

Another potential problem concerns allergic reactions, usually
manifested as contact dermatitis.

Mercury or freshly mixed AMALGAM should never be touched by hand.

Mercury is readily absorbed by the skin.
 Usage and
preparation of
The dental specialist has the direct responsibility for the
amalgam
correct preparation and use of amalgam.

Incorrect use may produce a faulty restoration that can
cause or contribute to the loss of a tooth.

Therefore, the dental specialist must use extreme care in
preparing a good mix of amalgam that will provide the best
qualities obtainable from the alloy.

***insert a video about changing an amalgam restoration for composite resin
restoration***
 MANIPULATIVE
VARIABLES
The manipulating of AMALGAM involves
the following sequence of events:

1. Proportioning and dispensing
2. Trituration
3 Condensation
4.Carving
5. Polishing

***insert a video about class 1 amalgam restoration***
1. PROPORTIONING AND
DISPENSING
Alloy/mercury ratios vary between 5:8 and 10:8.

Those mixes containing greater quantities of mercury are
“wetter” and are generally used with hand mixing.

Those mixes containing smaller quantities of mercury are
“drier” and are generally used with mechanical mixing.
- For example Spherical particle alloys, require
less mercury to produce a workable mix.
1. PROPORTIONING AND
DISPENSING
For optimum properties, the final set
amalgam should contain less than
50% mercury.

The optimal final mercury content
ranges from an average of 45% for
lathe-cut materials to an average of
40% for spherical materials.
TRITURATION
The mixing or trituration of AMALGAM may be
carried out by hand or in an electrically
powered machine which vibrates a capsule
containing the mercury and alloy.

Trituration by hand is not extensively practiced in
developed countries nowadays. Mechanical
mixing is far more widely used - amalgamator.

Trituration times 5 - 20 seconds are normal.
 2. TRITURATION
The advantages of mechanical trituration
are as follows:

1. A uniform and reproducible mix is
produced.

2. A shorter trituration time can be used.

3. A greater alloy/mercury ratio can be used.
Amalgamator
 3.
ONDENSATION
Material is condensed into the prepared cavity using a flat-
ended steel hand instrument called an amalgam condenser.

The technique chosen for condensation must ensure the
following.
1. Adequate adaptation of the material to all parts of the cavity
base and walls.
2. Good bonding between the incremental layers of amalgam
3. Optimal mechanical properties in the set amalgam by
minimizing porosity and achieving a final mercury content of
44-48%.
 3.
CONDENSATION
There should be a minimal time delay between trituration and
condensation.

If condensation is commended too late, the amalgam will have achieved a
certain degree of set and adaptation, and final mechanical properties
are all affected.

There is a good correlation between the quality of an AMALGAM
restoration and the energy expended by the operator who condenses it.

It needs to use a high condensating force.

Lower forces are required to condense spherical particle amalgams than
lathe-cut materials.
 Condensing

Instruments
Amalgam carriers and condensers are used for this purpose.
4. CARVING
Soon after condensing the AMALGAM, the surface layer,
which is rich in mercury, is carved away with a sharp
instrument.

If carving is delayed too long the material may become
too hard to carve and there is a danger of chipping at
the margins.
4. CARVING
Example of Amalgam Carvers
 5. POLISHING
Polishing is carried out in order to achieve a
lustrous surface having a more acceptable
appearance and better corrosion resistance.

The fillings should not be polished until the
material has achieved a certain level of
mechanical strength, otherwise there is a
danger of fracture, particularly at the margins.

Many products require a delay of 24 hours
between placing and polishing.
 5. POLISHING
Example of AMALGAM polishing materials
THANK YOU