Obturation First Lecture 2024 PDF

Summary

This lecture covers different aspects of root canal obturation, including factors influencing treatment outcomes, properties of various materials, and detailed analysis of different types of dental sealers and core materials. The document also examines the advantages and disadvantages of different materials, like the use of gutta-percha and the relevance of factors like sealing efficiency and material compatibility.

Full Transcript

Obturation of The Root
Canal System
By
Mahmoud Ramadan Abo ElSeoud
Lecturer of Endodontics
Faculty of Dentistry
Alexandria University

Remember: The main cause of pulpal and
periapical disease is BACTERIA.

Factors affecting outcome of
primary root canal treatment (2
factors related to obturation)
1. Absence of preoperative radiolucent
lesion.
2. Dense filling with no voids.
3. Filling within 0-2 mm of the
radiographic apex.
4. Satisfactory coronal restoration.

Why to obturate the root canal
after biomechanical
preparation ?

1. Studies indicate that root canal systems cannot be completely
cleaned and disinfected (bacteria free canals).
2. Since the primary etiology of pulpal and periradicular pathosis is
bacterial.
 Therefore , obturation of the radicular space is necessary to
(Objectives of obturation):
1. Entomb the remaining irritants in the canal.
2. Seal the apex from the periapical tissue fluids (prevents apical

leakage).
3. Obturation also reduces coronal leakage (prevents coronal
leakage) ( Achieved with adequate coronal restoration) .

 Simply, obturation serves to prevent the traffic of fluids from the
periradicular tissues or saliva into the canal as well as of bacteria
and their products from the canal to the periradicular tissues.

 Obturation main aim is to prevent leakage and reinfection of the
cleaned and disinfected root canal system.

Obturation should seal the root canal
apically, laterally and coronally

It should be noted that
effective

coronal

seal

maintaining an
(permanent

restoration) is considered essential for long
term successful root canal treatment.

Root canal obturation materials

1.Sealer.
2.Core material.

Root Canal Sealers
 Functions of root canal sealers:
1. Root canal sealers are necessary to seal the space
between the dentinal wall and the obturating core
interface.

2. Sealers also fill voids and irregularities in the root canal,
lateral and accessory canals.

3. Fill the spaces between gutta-percha points used in
lateral condensation.
4. Serve as lubricants during the obturation process.

• Grossman outlined the properties of an ideal sealer.
• At present no sealer satisfies all the criteria.

Common features for all types of sealers:
 Sealers are biocompatible and well tolerated by the
periradicular tissues.
 All sealers exhibit toxicity when freshly mixed; however,
their toxicity is greatly reduced on setting.

 Sealers are resorbable when exposed to tissues and tissue
fluids.
 Tissue healing and repair generally appear unaffected by
most sealers, provided there are no adverse breakdown
products of the sealer over time.

Types of Root Canal Sealers
The most popular sealers are:

1. Zinc oxide–eugenol formulations.
2. Calcium hydroxide sealers.
3. Glass ionomer sealers.
4. Resin based (epoxy resin or methacrylate resin)
sealers.
5. Calcium silicate–based sealers.

Zinc Oxide and Eugenol
 Zinc oxide–eugenol sealers have a history of successful use over an
extended period of time.
 Zinc oxide–eugenol sealers will resorb if extruded into the periradicular
tissues.
 Features of ZOE sealers:
 Slow setting time.
 Shrinkage on setting.
 Solubility.

 Can stain tooth structure.

 An advantage to this sealer group is antimicrobial activity.
Example: Pulp Canal Sealer

Calcium Hydroxide Sealers
 Calcium hydroxide sealers were developed for therapeutic activity

(antimicrobial, mineralization potential) .
 It was thought that these sealers would exhibit antimicrobial activity
and have osteogenic–cementogenic potential.

 Unfortunately, these actions have not been demonstrated.
 Solubility is required for release of calcium hydroxide and sustained
activity which is inconsistent with the purpose of a sealer.
Examples:
 Calciobiotic root canal sealer .
 Apexit and Apexit Plus .

Glass Ionomer Sealers
Glass ionomers have been advocated for use in

obturation

because

of

their

dentin-bonding

properties.

A disadvantage of glass ionomers is their removal if
retreatment is required.

 This sealer has minimal antimicrobial activity.
Example: Ketac-Endo.

Resin Sealers
Resin sealers have a long history of use , they
provide adhesion, and do not contain eugenol.
There are two major categories:
Epoxy resin–based.
Methacrylate resin–based sealers.

Epoxy Resin Sealers
AH-26 (DENTSPLY) is a slow setting epoxy resin

that was found to release formaldehyde when
setting.

AH Plus (DENTSPLY ) (Gold Standard) is a
modified

formulation

of

AH-26

in

which

formaldehyde is not released.
The sealing abilities of AH-26 and AH Plus appear

comparable.

 AH Plus is an epoxy resin–amine based system that comes in two
tubes.
 It exhibits a working time of approximately 4 hours.

AH Plus sealer is a resin formulation. (Courtesy DENTSPLY
DeTrey, Konstanz, Germany.)

AH Plus sealer achieves high bond strength to both
dentin (2.06 MPa) and gutta-percha (2.93 MPa).
The adhesiveness of AH Plus to root dentine is related

to covalent bonds between epoxide rings and the
exposed amino groups in the collagen network of
dentin.

Methacrylate Resin Sealers
 Four generations of methacrylate resin–based root canal sealers have
been marketed for commercial use.
 The bondable root canal sealers has been aggressively promoted with

the highly desirable property of creating monoblocks within the root
canal space ( similar to bonding composite to dentin).
 It was suggested that monoblock obturation improves the seal and
fracture resistance of the filled canals.
 The formed bond was not durable and long term failure was noted.

Silicone Sealers
 Example: RoekoSeal is a polydimethylsiloxane that has been

reported to expand slightly on setting.
 Example: GuttaFlow and GuttaFlow2 are cold flowable
matrices that are triturated.
 They consist of gutta-percha in particulate form (less than 30
μm) added to RoekoSeal.

 The material is provided in capsules for trituration.
 The technique involves injection of the material into the canal,

followed by placement of a single master cone.

 The material provides a working time of 15 minutes and it cures in 25 to
30 minutes.
 The

material

fills

canal

irregularities

with

consistency

and

is

biocompatible, but the setting time is inconsistent and may be delayed
by final irrigation with sodium hypochlorite.

GuttaFlow trituration
capsule and injection
syringe (Coltène/
Whaledent).

Calcium Silicate Sealers
 A new category of root canal sealers based on mineral

trioxide aggregate (MTA) has recently been commercially
available.
 These sealers are based on tricalcium silicate, a hydraulic
(water setting) powder used for various surgical and
vital pulp therapy treatments.

These sealers exhibit Bioactivity (induce
hydroxyapatite formation) (therefore called
Bioceramics)

Ther are

also

hydrophilic (sets in the

presence of moisture) .

 Tricalcium silicate cements/sealers set by reaction with water
and form a highly alkaline (pH of about 12) mixture consisting
of a rigid matrix of calcium silicate hydrates and calcium
hydroxide.
 When tricalcium silicate cement sets, the dimensional change
is less than 0.1% expansion, which helps with creating a
barrier, and is especially important for obturation.

Examples of tricalcium silicate sealers
1. Endosequence BC sealer.

2. Ceraseal.

Premixed ready to use calcium silicate sealers

Medicated Sealers
 Sealers containing paraformaldehyde (e.g: Sargenti paste,
N2, RC2B) are strongly contraindicated in endodontic
treatment.
 These sealers are not approved by the U.S. Food and Drug
Administration

and

are

unacceptable

under

any

circumstances in clinical treatment because of the severe
and permanent toxic effects on periradicular tissues.

The toxic in vivo effects of these materials on
the pulp and periapical tissues have been
demonstrated over time.
Overextension has resulted in osteomyelitis
and paresthesia.

Core Materials
The most common method of obturation
involves gutta-percha as a core material.
 Regardless of the obturating technique,
emphasis should be placed on the process of

shaping and cleaning the canal.

The properties of an ideal obturation material have
been outlined by Grossman.

Core obturating materials may be classified into:
1. Solids ( Silver cones used in the past).
2. Semisolid materials ( GP ) ( The most common
material nowadays).
3. Pastes ( not used any more).

Silver Cones ( not used nowadays)
Jasper introduced cones made of silver,
which he claimed produced the same
success rate as gutta-percha and were

easier to use.

Disadvantages of silver cones:
1. When silver points contact tissue fluids or saliva, they
corrode. The corrosion products have been found to be
cytotoxic and produce pathosis or impede periapical
healing.

2. Silver cones are rigid so can be easily placed to length.
 This resulted in clinician often failing to properly clean and
shape the canal before obturation (canals may be
instrumented to file # 15 or # 20 without any coronal
flaring).

Silver cones are advocated for ease of placement and length control. A,
Radiograph of a facial maxillary right central incisor obturated with a silver cone. B,
Tissue discoloration indicating corrosion and leakage. C, Lingual view indicates coronal
leakage. D, Corroded silver cone removed from the tooth. E, Post-treatment radiograph
of the tooth

Gutta-Percha

Gutta-Percha
 Gutta-percha is the most popular core material used for
obturation.
 Major advantages of gutta-percha are its:
1. Plasticity, ease of manipulation.
2. Minimal toxicity.
3. Radiopacity.
4. Ease of removal with heat or solvents.
 Disadvantages include:
1. Lack of adhesion to dentin.
2. When heated, shrinkage upon cooling.

 Gutta-percha cones consist of approximately:

1. 20% guttapercha.

2. 65% zinc oxide (antibacterial activity).
3. 10% radiopacifiers.
4. 5% plasticizers ( wax or resin).
Rubber like material obtained from trees growing in
Asia (Indonesia and Malaysia).

 Since gutta-percha comes from trees, so its original color
is white.
 By the addition of dyes, its color usually changes to pink

to simulate the color of the pulp ( the tissue that it replace).
 Can be stained to any color by the addition of different
dyes.

Properties of gutta-percha:
 Gutta-percha is the trans-isomer of polyisoprene (rubber)
and exists in two crystalline forms (α and β).
 In the unheated β phase, the material is a solid mass that is
compactable.

 When heated, the material changes to the α phase and
becomes pliable and tacky and can be made to flow when
pressure is applied.
 A disadvantage to the α phase is that the material shrinks on
setting.

Gutta-percha can be made to flow if it is
modified by either heat or solvents such as
chloroform.
This permits adaptation to the irregularities of

the canal walls.

 Gutta-percha cones are available in standardized (numbers)
and nonstandardized (letters) sizes .
 The nonstandard nomenclature refers to the dimensions of the

tip and body.
For example: A fine-medium cone has a fine tip with a medium
body.
Nonstandard guttapercha cones: extra
fine, fine fine, fine,
medium fine, fine
medium, medium, large,
and extra large.

Standardized cones are designed to match the
taper of stainless steel ( 2%) and nickel-titanium
instruments ( 4%,6%).

Standard gutta-percha cone sizes #15 to #40.

 For example: A size 40, 0.02 taper cone has a tip of 0.4 mm
and a taper of 0.02 mm per millimeter (2% Taper similar to
size 40 file).

Size #30 2 % taper file and standard gutta-percha point.

Although gutta-percha points cannot be

heat sterilized, gutta-percha points can
be sterilized by placing in 5.25%

NaOCl for one minute followed by
96% ethyl alcohol.

WHEN TO OBTURATE THE CANAL
1. The root canal is ready to be filled when the canal is
cleaned and shaped to an optimum size.
2. The tooth should be comfortable.

3. Dry canals may be obtained with absorbent points except
in cases of apical periodontitis or apical cyst, in which

“weeping” into the canal persists.
4. The smear layer (organic and inorganic components)
lining the canal walls should also be removed.

EXTENSION OF THE ROOT CANAL
FILLING
The anatomic limits of the pulp space are the
cementodentinal junction apically, and the pulp

chamber coronally.
 Debate persists, however, as to the ideal apical limit

of the root canal filling.

 Canals filled to the apical CDJ are filled to the anatomic limit
of the canal.
 Beyond this point, the periodontal structures begin.

Ideal termination of canal preparation and obturation. A, Apical constriction at
cementodentinal junction marks end of root canal. From this point to anatomic apex (0.5 to 0.7
mm), tissue is periodontal. B, Photomicrograph of periapex. Small arrows at cementodentinal
junction. Large arrow (bottom) at denticle inclusion

 The CDJ junction is an average of about 0.5 to 0.7 mm from the
external surface of the apical foramen, as clearly demonstrated by
Kuttler, and is the major factor in limiting filling material to the

canal.

Therefore, filling to the radiographic end of the root
is actually overfilling since the apical flare of the
foramen is filled with periodontal tissue.

Histologic section of a root apex, demonstrating
anatomy of the classic foramen and constriction.

Histologic section demonstrating the
foramen exiting short of the root apex.