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BIOACTIV
E
MATERIA
LS
DR. CLAUDINE LAGMAN
 BIOACTIVITY

“The ability of a material to elicit a response in a living tissue”

D Grotra, C V Subbarao: Bioactive materials in endodontics. recent research in science
and technology 2012:4(6); 25-27

“Bioactive material must be able to elicit a biological response
at the interface and induce the formation of a bond between
tissue and the material”

MG Gandolfi , P Taddei, A Tinti and C Prati : Apatite-forming ability (bioactivity) of
ProRoot MTA., Int Endod J 2010 43(10); 917–929
The ideal properties of bioactive material

bactericidal
bacteriostatic
sterile
stimulate reparative dentine formation
maintain pulp vitality.
Uses of BioActive Materials

pulp capping material

Used for permanent restorations

Used for dentinal tubule occlusion.

Prevents dentinal hypersensitivity

helps in regeneration of bone tissue.

promotes tooth remineralization
Various BIO Active Materials

 calcium hydroxide,
 mineral trioxide aggregate (MTA),
 calciumenriched mixture (CEM),
 Biodentine
 Inert material (isobutyl cyanoacrylate and tricalcium phosphate ceramic),
 ActiveTM BioACTIVE restorative material,
 Pulpdent (composite resin that are more bioactive and release more fluoride than glass ionomers),
 MTYA1-Ca filler,
 tetracalcium phosphate (TTCP),
 sol-gel-derived bioactive glass (BAG) ceramic containing silver ions (Ag-BG),
 calcium phosphate,
 novel endodontic cement (NEC),
 endo sequence root repair material.
 MTA
Mineral Trioxide Aggregate
Mineral trioxide aggregate (MTA) was developed
for use as a dental root repair material by Dr.
Mahmoud Torabinejad, (MTA)

It is the most commonly recommended material
for sealing communications between the
root canal system and the periodontium
 MTA COMPOSITION

MTA is comprised primarily of
75 % Portland cement
20 % bismuth oxide (Bi2O3)
5 % calcium sulfate dihydrate or gypsum
(CaSO4 ∙ 2H2O)

*Roberts HW, Toth JM, Berzins DW, Charlton DG. Mineral trioxide aggregate material use in endodontic
treatment: a review of the literature. Dent Mater 2008;24: 149–64.
 MTA COMPOSITION

Additional minor
trace elements may
also be present

*Roberts HW, Toth JM, Berzins DW, Charlton DG. Mineral trioxide aggregate material use in endodontic
treatment: a review of the literature. Dent Mater 2008;24: 149–64.
ASSIGNMENT:

Why Bismuth Oxide and
Gympsum are added?
There are two types of MTA
1. Gray
2. White
 Setting time: Antimicrobial
about 2 hours Biocompatible MTA PROPERTIES
and 45 min
Non-
Radio resorbable
opaque
Characteristics of
MTA Minimal
leakage
Set in the
presence
of
moisture Compressive strength
develops over a period of
Low or 28 days
10.2, after 3
pH: initially- no *more
hours- 12.5 solubilit
y than 133 MPa
(remains constant)
 Biocompatibil
ity
MTA is a biocompatible
material with good
sealing ability
Ca & P are
generate the main
encourage formation
little or no ions
the of
inflammator present in
formation of cementum
y response this
fibrous covering
in material,
connective the entire
periradicula which are
tissue root end
r tissues the
components
of dental
 Sealing
ability
In presence
MTA of
expands moisture
during
setting
reaction
excellen sealing ability
t of MTA is
sealing increased
ability
Moistened cotton pellet should be placed in contact
with MTA before placement of the permanent
 Setting
Time
MTA powder consists of fine hydrophilic
particles.
Hydration of MTA powder results in a colloidal
gel that solidifies to a hard structure in ~ 4 hrs
which has a long setting time.

MTA has long setting time with less
shrinkage.
Torabinejad M, Hong CU, McDonald F, et al. Physical and chemical properties of a new root-end
filling material. J Endod 1995;21:34–53
 Lack of solubility is an ideal
Solubili characteristic of MTA as a
root end filling material.
ty
Is an important factor to be
Compressi considered when a filling
material is placed in a cavity
ve that bears occlusal pressure.
Strength
Bismuth oxide added for
radiopacity and it is more
Radiopaci radio opaque than its
surrounding structures.
ty
 Usage in some
clinical cases
1. Root-end Filling after
Apicoectomy
2. Internal & external root
resorption & obturation
3. Lateral or furcation perforation
4. Root canal sealer
5. Apexification
6. Apexogenesis (Vital pulp)

Parirokh M, Torabinejad M. Mineral Trioxide Aggregate: A Comprehensive Literature Review
—Part III: Clinical Applications, Drawbacks, and Mechanism of Action. J Endod 2010; 36: 400-
Video MTA MANIPULATION
 Root –end Filling
after Apicoectomy

Endodontic surgery followed by root end filling may at time be
necessary for certain tooth where routine endodontic treatment is
not possible
Internal & external
root resorption &
obturation
 Lateral or furcation
perforation

Figure 1: (a) Pulpal floor view of
furcation with internal matrix in place,
(b) furcation filled with blood, (c)
excess blood soaked with damp
cotton pellet, (d) perforation sealed
with repair material

http://www.jcd.org.in/viewimage.asp?img=JConservDent_2013_16_5_462_117504_u2.jpg
 Apexification
(Necrotic pulp)
Figure 1: (a) Preoperative.
(b) and (c) Working
length determination. (d)
MTA apical plug of 4-5mm
thickness. (e) Final
obturation. (f) After 8-
month reassessment,
continuous lamina dura
and consistent width of
periodontal ligament
space suggest healing of
the periapical lesion.

Boon of MTA Apexification in Young Permanent Posterior Teeth
Vinod Kumar, Mohammed Zameer, Vijaya Prasad, and T. Mahantesh
Department of Pediatric and Preventive Dentistry, Navodaya Dental College and Hospital, Raichur, Karnataka 584103, India
Apexogenesis
(Vital Pulp)

The process of
maintaining pulp vitality
during pulpal treatment to
allow continued
development of the entire
root (apical closure
occurs approximately 3
years after eruption).
 Procedure of pulpotomy with
MTA
MTA placement Moist cotton
Control over exposure pellet
the pulp tissue by placement
bleedin using MTA on MTA
carries. material
g allow setting
 Next visit the
temporary filling
the rest of cavity removed along
cotton pellet tooth
filled with rest orated with
temporary filling permanent
restoration.
Why use MTA
for
pulpotomy
instead of
formocresol?
 **Formocresol has been criticized for its tissue irritant , cytotoxic
and mutagenic effect. While MTA found to be ideal material with
low toxic effect increased tissue regeneration properties and good
clinical result.

**An important clinical advantage of MTA over FC is less time is
required for the procedure. While FC requires 3–5 minutes
application before the cotton pellet is removed.

**During the removal of FC-soaked cotton pellet, there is a
possibility of the cotton fibers adhering to clot, resulting in
reoccurrence of bleeding. This does not occur with MTA as it
is applied directly without cotton pellet
https://www.sciencedirect.com/science/article/pii/B9780723436959000079
 MTA
LIMITATIONS
 Not used in area open to oral environment
 Because of solubility in acid environment
generated by bacteria, food and beverages

 Not recommended for obturation of primary teeth
- material is slowly resorbed

 Not used with anterior teeth (discoloration)
 Not uses as permanent filling – low compressive
strength
 MTA DRAWBACKS

 discoloration potential
 presence of toxic elements in the material
composition
 difficult handling characteristics
 long setting time

*Parirokh M, Torabinejad M. Mineral Trioxide Aggregate: A Comprehensive Literature Review—Part III:
Clinical Applications, Drawbacks, and Mechanism of Action. J Endod 2010; 36: 400-413
 high material cost
 absence of a known solvent for this material
 difficulty of removal after curing
 Low compressive strength incompatible with
restorative indications

*Parirokh M, Torabinejad M. Mineral Trioxide Aggregate: A Comprehensive Literature Review—Part III:
Clinical Applications, Drawbacks, and Mechanism of Action. J Endod 2010; 36: 400-413
BIODENTI
NE
 Biodentine: is
the first all-in-
one,
biocompatible
and bioactive
material to use
wherever
dentine is
 Biodentin - calcium silicate based
product which became commercially
available in 2009 by septodont and that
was specifically designed as a “ dentine
replacement “ material
 COMPOSITION OF
BIODENTINE

Tricalcium silicate( main
core material)
Powde Dicalcium silicate
r Calcium carbonate
Iron oxide (shade)
packaged Zirconium
in oxide(radiopacity)
capsule(0,7
g)
 Liquid Calcium
chloride(accelerator)
(packaged in Hydrosoluble polymer
pipette(0,18
ml) (water
reducing agent, faster
setting)
Water
MANIPULATI
ON
The powder is mixed with the liquid in a capsule

in the triturator for 30 seconds
1 capsule powder: 5 drops of liquid
Setting time: Approximately 12 min
Advantage
s
of
Biodentine
 Advantage
s
 For crown and root indications.
of
Biodentine
 Helps in remineralization of dentine.
 Preserves pulp vitality and promotes pulp healing.
 Replaces natural dentine with the same
mechanical properties.
 Better handling and manipulation.
 Reduced setting time.
 DENTIN
SUBSTITUTE
Biodentine has dentin like mechanical properties.

It can be used as permanent dentine substitute (base) under
composite or amalgam especially in deep carious teeth.
 PULP
CAPPING
Biodentine can be used safely and effectively as pulp
capping material.
Encourage pulp healing
Dentin bridge formation by
odontoblast stimulation

Initiate early mineralization
 PULPOTOMY

Pulpotomy is another widely used vital pulp therapy method in
which biodentine is advocated.
 Preferred when the coronal pulp tissue is inflamed and a direct
pulp capping is not a suitable option.
 The rate of success of vital pulpotomy with biodentine is higher
than MTA.

Recently at the 12th congress of european academy of pediatric dentistry (EAPD) in poland, rubanenko et al.
Presented their preliminary results of comparing biodentine versus formocresol as dressing agents in pulpotomized
primary molars. They demonstrated a success rate of 100% for biodentine while that of formocresol was 94%.
 REPAIR OF
PERFORATIONS
Biodentine has its own unique properties that make it
preferred for perforation repair either in root canal or pulp
chamber floor.

Due to their good adhesion to

dentin surface and fast setting time.
REPAIR OF RESORPTION
Biocompatibility and ability to induce calciumphosphate precipitation
at the interface to the periodontal tissue, calcium silicate cements
play a major role in bone tissue repair
 APEXIFICATION
biodentine can be used successfully in necrotic immature teeth.

Tight bacterial seal
Induction of formation of new cementum
Induction of formation of new pdl

Cauwels et al. Found that necrotic immature teeth can still achieve
continued root development after proper regenerative endodontic
treatment with biodentine.
 CONCLUSION

Due to its major advantages and unique features as well as
its ability to overcome the disadvantages of other materials,
biodentine has great potential to revolutionize the different
aspects of managing both primary and permanent in
endodontics as well as operative dentistry.
On the other hand, further studies are needed to extend the
future scope of this material regarding the clinical
applications.”
 REFERENCES
biodentine active biosilicate technology scientific file, septodont, paris, France.

L. Grech, B. Mallia, and J. Camilleri, “characterization of set intermediate restorative material, biodentine,
bioaggregate and a prototype calcium silicate cement for use as root- end filling materials,” inter national endodontic
journal,vol.46,no. 7,pp.632–641,2013

M.B.Kayahan,m.H.Nekoofar,a.Mccannetal.,“Effec to facid etching procedures on the compressive strength of
4 calcium silicate-based endodontic cements,” journal of endodontics,vol. 39,no.12,pp.1646–1648,2013.

L. Grech, B. Mallia, and J. Camilleri, “investigation of the physical properties of tricalciumsilicate cement-basedroot-end
filling materials,” dental materials, vol. 29, no. 2, pp. E20–e28, 2013.

J. Camilleri, “investigation of biodentine as dentine replacement material,” journal of dentistry,
vol.41,no.7,pp.600–610, 2013.

M.E.Odabas¸,m.Bani,andr.E.Tirali,“shear bond strengths of different adhesive systems to
biodentine,”the scientific world journal,vol.2013,article id 626103,5 pages, 2013