2. OBJECTIVE
To remove the attachment and all the
adhesive resin from the tooth and restore
the surface as closely as possible to its
pretreatment condition without inducing
iatrogenic damage
5. REMOVAL OF STEEL
BRACKETS
Place the tip of bracket remover against mesial and
distal (or occluso-cervically) edges of the bonding base
and cut the brackets off
A gentler technique is to squeeze the bracket wings
mesiodistally and lift the bracket with the peel force
6.
7. REMOVAL OF CERAMIC
BRACKETS
With the introduction of ceramic brackets, a new
concern over enamel fracture and loss from
debonding has arisen.
Because of differences in bracket chemistry and
bonding mechanism, various ceramic brackets
behave differently on debonding
More recent ceramic brackets have
mechanical lock base and vertical slot
that will split the bracket by squeezing
13. Takla and Shivapuja (1995) study in which 30 teeth were
schduled for orthodontic extractions
15 extracted 24 days after ETD
7 extracted 28-32 days after ETD
8 were control teeth and debonded by conventional
method, with pliers
In control group pulp was normal
Significant hyperemia in teeth extracted after 24 day
In case of teeth extracted after 28-32 day variation was seen
from complete recovery to persistent inflammation
Jost-Brinkmann et al (1997) did an in vivo study in which 12
human premolars scheduled for extraction were bonded with
ceramic brackets which were subsequently debonded using
ETD. After 4 weeks, teeth were extracted and histologically
examined . No signs of pulpal inflammation were seen
14. LASERS
The use of laser eliminates problems like enamel tear
outs, bracket failures and pain.
Lasers decreases debonding force and less time
consuming.
Strobl et al (1993) Removal of ceramic brackets from
enamel surface by means of laser heating was investigated
with the use of C02 and YAG laser
Polycrystalline alumina
Monocrystalline alumina
15. Laser-aided debonding significantly reduced debonding
force by thermal softening of adhesive resin.
In 69-75% incident light reached enamel surface when
Nd:YAG laser was used which has the potential to cause
pain or damage to tooth surface
17. DEBONDIN
G
METHODS
Mechanical
ADVANTAGES
Low cost
Electrothermal o Reduced incidence of
bracket failure
o Short debonding time
DISADVANTAGES
Risk of enamel fracture
Potential for pulpal damage
and mucosal burn
Laser
Experimental, but
increased precision
regarding time and
amount of heat
application
High cost of equipment
Ultrasonic
o Potentially reduced
enamel damage
o Reduced likelihood of
bracket failure
o Adhesive removal after
debonding may be
o Increased debonding time.
o Extensive wear of
expensive ultrasonic tip
o Some force required
o Potential for soft tissue
injury
18. ADHESIVE REMNANT INDEX
(ARI)
Used to evaluate the amount of adhesive left on the tooth
after debonding
SCORE 0: No adhesive left on tooth
SCORE 1: Less than half of adhesive left
SCORE 2: More than half left
SCORE 3: All adhesive left on tooth with distinct with
distinct impression of bracket mesh
20. REMOVAL OF RESIDUAL RESIN
Ultrasonic scaler
Scraping with a sharp bond removing removing plier
21. Burs
Tungsten carbide bur
Ultrafine diamond bur
White stone finishing bur
22. ENAMEL SURFACE INDEX
SCORE 0: Instrument tested left the tooth surface with its
perikymata intact
SCORE 1: Plain cut and spiral fluted tungsten carbide burs
operated at about 25,000 rpm were the only instruments that
provided the satisfactory surface appearance
23. SCORE 2: Fine sandpaper disks produced several
considerable and some even deeper scratches
SCORE 3: Medium sandpaper disks and a green rubber
wheel produced similar scratches, that could not be
polished away
24. SCORE 4: Diamond instruments were unacceptable
and even fine diamond burs produced coarse
scratches and gave a deeply marred appearance