101

introduction

Root canal obturation consists of placing an inert 
filling material in the space previously occupied by pulp 
tissue. To achieve successful endodontic therapy, it is 
important to obturate the root canal system completely.  
Gutta-percha is used with various techniques for obturation 
of the root canal system. Throughout the years, a variety of 
techniques using gutta-percha have been developed for root 
canal fillings. These techniques include lateral condensation, 
warm vertical condensation, and injectable thermoplasticized. 
Investigators have evaluated the apical seals obtained 
by these various gutta-percha filling techniques. 1 
Lateral condensation remains the most widely accepted and 
used obturation technique.2 Almost all other techniques 
are compared to it to evaluate success. It seems that lateral 
condensation is a gold standard for obturation. Based on 
that reasons, this study will use lateral condensation for 
root canal obturation.

In root canal obturation various materials have been 
used. The most frequent material used is gutta percha 
in combined with a root canal sealer. It must have 

ideal properties to be used for root canal obturation, as 
biocompatibility and sealing ability fundamental to promote 
apical and periapical tissue repair.3 Many materials are 
used for root canal sealer, but none of the available sealer 
consistency prevents leakage.4. The hermetic sealing of 
the root canal space is one of the objectives in root canal 
therapy.5

The most common cause of failure involving endodontic 
therapy can be attributed to the lack of an apical seal leading 
to leakage at the apex. effective endodontic obturation 
thus, must provide a dimensionally stable, inert fluid tight 
apical seal that will eliminate any portal of communication 
between the canal space and the surrounding periapical 
tissues through the apical foramen.6

Hydroxyapatite is the most thermodynamically stable 
synthetic calcium phosphate cement.7 A calcium phosphate 
cement has indicated that is useful as a sealer because can 
seal a furcation perforation, is shown to be biocompatible 
and also has potential to promote the healing of bone 
in endodontic treatment.8 Recently, most of the sealers 
commonly used contains zinc oxide or calcium hydroxide 
as a base ingredient of the powder.9

Sealing ability of hydroxyapatite as a root canal sealer: in vitro 
study

Widowati Witjaksono,1,6 lin naing,2 Ema Mulyawati,3 ar. Samsudin,4 and Mon Mon tin oo5
1 Department of Restorative Dentistry School of Dental Sciences Universiti Sains Malaysia
2 Institute of Medicine National University of Brunei Darussalam
3 Department of Conservative Dentistry, Gadjah Mada University, Indoensia
4 Department of Oral Surgery and 5 Department of Community Dentistry School of Dental Sciences Universiti Sains Malaysia
6 Department of Periodontic, Faculty of Dentistry Airlangga University, Indonesia

abstract 
Hydroxyapatite	(HA)	is	the	most	thermodynamically	synthetic	calcium	phosphate	cement,	and	has	indicated	useful	as	a	sealer	because	

can	seal	a	furcation	perforation,	is	shown	to	be	biocompatible	and	also	has	potential	to	promote	the	healing	of	bone	in	endodontic	
therapy.	 The	 objective	 of	 this	 study	 is	 to	 determine	 the	 sealing	 ability	 of	 HA	 produced	 by	 School	 of	 Engineering,	 Universiti	 Sains	
Malaysia	(USM)	when	used	as	a	sealer	in	root	canal	obturation,	compare	with	Tubli-seal	(Zinc-Oxide	base)	and	Sealapax	(Calcium	
Hydroxyde	base)	sealers.	Forty	five	single	rooted	human	anterior	teeth	were	instrumented	and	randomly	divided	into	three	experimental	
groups	of	15	teeth	each.	All	teeth	in	the	experimental	groups	were	obturated	with	laterally	condensed	gutta	percha	technique.	Teeth	
in	 the	 first	 group	 were	 sealed	 using	 Zinc-Oxide	 (ZnO)	 based	 sealer	 and	 those	 of	 second	 group	 using	 Calcium	 Hydroxide	 (CaOH)	
based	root	canal	sealer.	Third	experimental	group	was	sealed	using	HA	from	School	of	Engineering	USM.	Teeth	were	then	suspended	
in	 2%	 methylene	 blue.	 After	 this,	 teeth	 were	 demineralized	 dehydrated	 and	 cleared.	 Linear	 dye	 penetration	 was	 determined	 under	
magnifying	lense	with	calibrated	eye	piece.	Statistical	analyses	of	the	linear	dye	penetration	were	performed	with	Kruskal	Wallis	test.	
The	intergroup	comparison	between	HA	and	ZnO	groups	and	CaOH	groups	were	analyzed	by	Mann-Whitney	test.	The	dye	penetration	
for	group	which	were	sealed	with	HA	exhibited	the	lowest	penetration	and	it	showed	that	there	was	a	statistically	significant	difference	
both	between	HA	and	ZnO	groups	and	also	between	HA	and	CaOH	groups	(p	<	0.001).In	conclusion,	it	was	found	that	value	added	HA	
based	endodontic	material	which	were	produced	by	USM	can	be	used	as	a	root	canal	sealing	materials	when	it	used	in	combination	
with	epoxy	resin	since	it	leaked	comparatively	less	as	compared	to	ZnO	and	CaOH	sealers.	Before	reaching	a	definitive	conclusion,	
this	material	requires	further	extensive	exploration	both	clinically	and	in	vitro.	

Key words:	apical	seal,	endodontic	sealers,	micro	leakage	

Correspondence: Widowati, Department of Restorative Dentistry, School of Dental Sciences Universiti Sains Malaysia, Health Campus 
16150 K.Kerian, Malaysia. e-mail: widowati@kb.usm.my



102 Dent. J. (Maj. Ked. Gigi), Vol. 40. No. 3 July-September 2007: 101-105

The present study was thereby designed to determine 
the sealing ability of hydroxyapatite when used as a sealer 
in root canal obturation, compare with zinc-oxide base and 
calcium hydroxide base. Therefore, it would be interesting 
to examine whether or not hydroxyapatite is able to act as 
a root canal sealer. The rationale is that if adequate sealing 
is obtained, this material has the potential to be clinically 
useful.

materials and method

This study was designed to evaluate the in vitro	sealing 
abilities of endodontic materials. The following materials 
were selected and grouping for the study. 

Materials: Tubli_Seal TM sealer (Sybronendo, Kerr/
USA). A zinc-oxide based root canal sealer (ZnO) Sealapex 
TM sealer (Sybronendo, Kerr/USA). A calcium hydroxide 
based root canal sealer (Ca(OH)2) Hydroxyapatite (HA) 
(from School of engineering, Universiti Sains Malaysia/ 
USM) and were mixed with epoxy resin (Dentsply, 
DeTrey). This type of HA were used as part of a larger study 
(not yet published) in many fields and clinical trials.

Instruments: Ultrasonic scaler, bone’s cutting, contra 
angle hand piece, burs, endodontic box, glass lab, cement 
spatula, plastic filling instruments, tweezer, explorer, paper 
point, magnifying lense 10×, le crown mesh knife.

The study was carried out in vitro on forty-five extracted 
human single rooted, noncarious anterior teeth which 
were collected from the outpatient department of oral and 
maxillofacial surgery, School of Dental Sciences, Universiti 
Sains Malaysia. All external debris were removed with an 
ultrasonic scaler.

All teeth randomly divided into 3 groups each is  
15 teeth. The crown were separated from the root until 
the length of the roots were 14 mm and store in saline. 
The pulps were broch and the root canals were prepared 
by Step-back technique with working length 13 mm until 
no:80 file with Master Apical File (MAF) no 50. After 
the use of each instrument (file), the root canals were 
irrigated with 1ml H2O2 3% and 1 ml NaOCl 2.5% and 
dry with paper point and ready for root canal filling. The 
sealer were mixed according the manufacture’s directions. 
Hydroxyapatite granules were mixed up with epoxy resin 
liquid for hardener. The sealer was put along the lentulo 
plugger and coated to the inner walls of the canal by 
moving lentulo plugger clockwise according the groups, 
group A (ZnO based root canal sealer), group B (Ca (OH)2) 
based root canal sealer and group C (HA from School 
of engineering USM). One third apical of gutta percha 
master cone (no. 50) was coated with sealer and seat in the 
canal to the full working length. The canal were obturated 
with lateral condensation technique. A finger spreader 
was inserted into the root canal to a level that was –1 mm 

short of the working length. The root canal was filled with 
accessory cones until the entire canal was obturated. The 
access cavities of teeth in all groups were then filled with 
zinc polycarboxylate cement and hydraulic temporary 
restorative, then the root were immersed in saline solution 
for 4 weeks at 37 °C. After storage, the roots were double 
coated with nail polish, with the exception of the apical  
2 mm. Specimens used for the dye leakage test were placed 
in 2% methylene blue solution (37 C, pH &) for 48 hours. 
The roots were then taken from the dye solution, remove 
the nail polish with le crown mesh knife, washed and dried 
with compressed air. The depth of dye penetration were 
evaluated with clearing method.10

All the teeth were immersed in HNO3 5% for 72 hours 
for teeth demineralized. HNO3 was changed with the fresh 
one every 24 hours. The teeth were then placed in alcohol 
96% for 48 hours for teeth dehydration, and every 24 hours 
alcohol was changed with the fresh one. The final stage was 
clearing.10 All the teeth were placed in methyl salicylate, 
until dye penetration were able measured visually. Apical 
leakage was measured from the apex to the most coronal 
extent of dye penetration (Figure 1, 2, and 3). Linear dye 
penetration was measured under magnifying lense with 
calibrated eye piece and analyse by Kruskal Wallis test. The 
intergroup comparison between hydroxyapatite and zinc 
oxide groups and calcium hydroxide groups data analyzed 
by Mann-Whitney test. 

results

In the present study, measurements of maximum 
linear dye penetration were made to quantify the relative 
leakage (Figure 1, 2, 3). Dye penetration data for all the 
three groups are summarized in table 1. In group C teeth 
which were filled with laterally-condensed gutta-percha 
and hydroxyapatite (HA) sealer exhibited the lowest 
minimum-maximum (min-max) value of dye penetration. 
The min-max of dye penetration for group C(HA) was 
between 0-1mm. The min-max of dye penetration for group 
A teeth which were filled with laterally-condensed gutta-
percha and zinc oxide (ZnO) base sealer was between 1–3 
mm. The corresponding values for group B teeth which 
were filled with laterally condensed gutta-percha and 
calcium hydroxide (Ca(OH)2) base sealer was also between 
1–3 mm. Ten samples in group C (HA) showed no dye 
penetration whereas all samples in group A and B showed 
dye penetration. The comparison of the three study groups 
using Kruskal Wallis test (Table 2) revealed that there were 
at least one significant difference among the study groups 
(p < 0.001). Further Mann-Whitney test (post-hoe multiple 
comparisons between two groups) (Table 3) revealed that 
HA group has significance lesser penetration compared to 
ZnO or Ca(OH)2 groups (p < 0.001).



103Witjaksono et al.: Sealing ability of hydroxyapatite

discussion

HA is one of the ceramic materials commercially 
used for orthopaedic and dental implants, and it forms the 
principal mineral component of bone and comprises 60% to 
70% of the calcified skeleton. It’s chemical composition is 
Ca 10(PO4)6 (OH)2 and it has been produced synthetically 
since the early 1970’s and used clinically for the last 20 
years.11,12 It has received considerable attention over 
the past two decades primarily because of it’s excellent 
biocompatibility with hard tissues.13,14 and when placed 
in contact with viable bone, result in osteoconduction 

figure 1. Measurement of apical leakage in ZnO base 
(group A).

figure 2. Measurement of apical leakage in Ca(OH)2 base 
(group B).

figure 3. Measurement of apical leakage in Hydroxyapatite.

table 1. Amount of dye penetration in group A, B and C (mm)

Specimen no of each group

Amount of dye penetration (in mm)

Group A zinc oxide base 
(ZnO)

Group B calcium hydroxide 
(Ca(OH)2)

Group C Hydroxyapatite 
(HA)

1
2
3
4
5
6
7
8
9

10
11
12
13
14
15

Min–Max
Median (IQR)

2
1.5
2.5

2
2
1
2
3

1.5
2
3
2
1
2
2

1–3
2.0 (0.5)

2
1

1.5
2.5

3
1.5

3
2
3
2
2
3
3
2
3

1–3
2.0 (1.0)

0
0
0

1.0
0
0
0
0
0

0.5
0.5

0
0.5

0
0.3
0–1

0.0 (0.5)



104 Dent. J. (Maj. Ked. Gigi), Vol. 40. No. 3 July-September 2007: 101-105

table 3. Comparison of dye penetration between 
Hydroxyapatite (HA) and others

Comparison Z Stat. P valuea

ZnO vs HA
Ca(OH)2 vs HA

–4.76
–4.77

< 0.001
< 0.001

a Mann-Whitney test; P value is adjusted using Bonferroni 
procedure for multiple comparison

and osteointegration.15,16 HA does not cause a chronic 
inflammatory respons, toxic reactions or a foreign body 
giant cell reaction.12 Although HA is a promising implant 
material, the greatest stumbling block to it’s wider application 
and utilization is the brittleness of the material and it’s low 
strength for load-bearing applications.17 Thus the material 
used in this study is the value added HA based material 
which were produced by a group of scientist at the School 
of engineering Universiti Sains Malaysia (USM). The 
pure HA has been added with zirconia and other additional 
components, hot pressed and then sintered at a temperature 
of 1300 °C, to increase the toughness and strength of HA 
ceramic. Composites formed by HA ceramic in combination 
with zirconia have been proven not to produce any local 
or systemic adverse reactions or any cytotoxix effects in 
various in	vivo studies.18 This material showed no decrease 
in strength after ageing up to 1 year, which is in agreement 
with the study done by some investigators in 1993.19

It has been recognized for decades that the ideal end 
result of root canal therapy would be a closure of the apical 
foramen with reparative cementum. The goals for stability 
of successful endodontic therapy are total obliteration of 
the canal and perfect sealing of the apical foramen at the 
dentino-cemental junction and accessory canals at locations 
other than the root apex with an inert, dimensionally stable 
and biologically compatible material.20 According to other 
researchers,21 endodontic sealers are used to eliminate the 
interface between the gutta-percha and the dentinal walls. 
Thus, the quality of the filling depends largely on the sealing 
capacity offered by sealers.22,23

From this study an average leakage values of Zn O base 
sealer and CaOH base sealer both were minimum of 1 mm 
to maximum of 3 mm. The lesser value of dye penetration 
shown by value added HA sealer in the present study may be 
because of the better sealing abilities of HA. One possible 

explanation for this observed difference may be that HA 
has ability to bind strongly with natural bone tissue,24 
and synthetic HA has the same chemical composition as 
biological HA and thus mimics many properties of natural 
bone.25As for epoxy-resin based endodontic sealers to the 
human dentin showed a higher capacity to attach to the 
dentinal walls than other endodontic sealers and provide 
bonding between it and gutta-percha points.26 However the 
exact mechanism by which HA is incorporation with epoxy 
resin, then can be function as a good root canal sealer in the 
present study remain far from clear. It would be necessary to 
carry out further studies in order to make a larger evaluation 
of these value added HA based endodontic materials as well 
as their potential benefits. The in	 vivo	 evaluation should 
be done to assess the reaction to this value added HA as 
compared to the pure HA.

It can be concluded from this study that the value added 
HA based endodontic material can be used as a root canal 
sealing materials when it used in combination with epoxy 
resin since it leaked comparatively less as compared to ZnO 
and CaOH sealers. Before reaching a definitive conclusion 
this material requires further extensive exploration both 
clinically and in	vitro.

acknowledgements

The authors acknowledge the Universiti Sains Malaysia 
for funding this research as a short term grant in the year 
2006–2007. Special thanks to Ir. endro for help with the 
special work.

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table 2. Comparison of dye penetration between study groups (mm)

Group n
Dye Penetration

X2 Stat. (df) P valuea
Median (IQR) Min.-Max.

Zn O
Ca (OH)2
HA

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31.00
(2)

<0.001

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IQR = Interquartile range; Min. = Minimum; Max. = Maximum 



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