�

A comparison of three dimensional change in maxillary complete 
dentures between conventional heat polymerizing and microwave 
polymerizing techniques

Shinsuke	Sadamori,*	Toshiya	Ishii,*	Taizo	Hamada*	and	Arifzan	Razak**
* Department of Prosthetic Dentistry, Graduate School of Biomedical Sciences, Hiroshima University, Hiroshima, Japan
** Department of Prosthodontics, Faculty of Dentistry, Airlangga University, Surabaya, Indonesia

abstract

The purpose of this study was to measure and compare two different polymerizing processes, heat polymerizing (HP) and microwave 
polymerizing (MP), on the three dimensional changes in the fitting surface and artificial teeth of maxillary complete dentures. A three-
dimensional coordinate measurement system was used to record distortion of the specimens. The distortion of the fitting surface was 
measured from the reference plane on the fitting side from which a coordinate system was set, and the movement of the artificial teeth 
and the distortion of the polished surface was measured from the reference plane of the artificial tooth side, from which a coordinate 
system was set. It was clearly showed that various distortions of denture specimens after polymerization process can be measured 
with this three-coordinate measuring machine. The study showed that the overall distortion of the fitting surface in HP specimens was 
shown to be larger than in MP ones.

Key	words: Maxillary complete denture, Three dimensional change, Microwave polymerizing

Correspondence: Dr Shinsuke Sadamori, Department of Prosthetic Dentistry, Graduate School of Biomedical Sciences, Hiroshima 
University, 1-2-3 Kasumi, Minami-ku, Hiroshima City, 734-8553, Japan, Tel: +81-82-257-5681, Fax: +81-82-257-5684,  
E-mail:tsada@hiroshima-u.ac.jp

introduction 

It is now widely recognized that natural teeth can be 
retained for life. The number of people retaining their 
natural teeth is growing, and the absolute number of 
persons over the age of 65 is increasing rapidly. However, 
the actual number of patients requiring complete dentures 
remains almost constant.1 With the increasing percentage 
of population over the age of 65, the number of individuals 
with dementia will also grow. It constitutes a serious 
problem. However, a two-year follow-up study in a 
dementia ward in a mental hospital suggested that denture 
wearing has an effect on some activities of daily life.2 

The dimensional accuracy of heat-cured denture resin 
was evaluated by comparing the distance between reference 
points in the deflasked specimen and the master model 
after the deflasked specimen was adapted to the master 
model,3–5 or by comparing the distance between marked 
points in the deflasked specimen and the master model.6–8 
Other studies examined changes in the position of teeth in 
complete dentures.9,10 Several papers have investigated the 
accuracy of three-dimensional coordinate measurement on 
the mucosal surface of dentures.11–14

In this study, the three dimensional change in the fitting 
surface and artificial teeth of maxillary complete dentures 
was measured and compared for two different polymerizing 
processes.

materials and methods

Specimen	preparation
To fabricate the working cast, a die of an edentulous 

maxillary arch (402U, Nisshin, Kyoto, Japan) was 
duplicated using silicone elastomer (GC, Tokyo, Japan). 
A master cast was made of dental stone (New Fujirock, 
GC, Tokyo, Japan) according to the manufacturer’s 
recommendation. The measuring points on the master cast 
consisted of 12 points on the alveolar ridge related to each 
second molar and first premolar tooth and the midway 
point of the incisor teeth, and on the denture flange in the 
molar, premolar and anterior regions. In addition, we set 
three datum-points (reference points) to set the coordinate 
system in the palate. The measuring points were set with 
steel balls with a diameter of 2 mm, and the datum-points 
were steel balls with a diameter of 4 mm set on the model 
using self-curing resin. The master cast was duplicated and 
six master casts were made. A wax denture was made on 
one of the six working casts. One thickness (approximately 
1.5 mm) of base plate wax (paraffin wax, GC, Tokyo, 
Japan) was adapted to the working cast and the artificial 
teeth (GC Duradent: anterior teeth C3, posterior teeth 30M, 
GC, Tokyo, Japan) were positioned in the usual manner. 
The core of the wax denture was made with dental stone 
and silicon impression material. After the working casts 
were measured, three steel balls 4 mm in diameter were 



7Sadamori: A comparison of three dimensional change

set in the appointed positions as datum-points, and the wax 
dentures were made from the core. The measurement points 
were prepared on mesiolingual cusps of the right and left 
second molar tooth, the lingual cusps of the right and left 
first premolar tooth, and the mesial edge of the right incisor 
with a diamond point 1.8 mm in diameter (Diamond Point 
FG regular 340, Shofu, Kyoto, Japan). 

Polymerizing	process
Two acrylic resins were used: Bio resin (Shofu, Kyoto, 

Japan) and Acron MC (GC, Tokyo, Japan) (Table 1). The 
Bio resin was mixed using 4.5 ml liquid to 10 g powder. The 
polymerizing process followed Japan Industrial Standard’s 
(JIS) recommendation: an initial 90 minutes at 70 °C 
followed by 30 minutes at 100 °C (HP). The Acron MC 
was mixed using 4.3 ml liquid to 10 g powder. Specimens 
(MP) were processed for 3 minutes in a 500 W microwave 
oven (EM-M 535 T, Sanyo Electric, Osaka, Japan). Ten 
standardized denture specimens were fabricated: five using 
the conventional technique and five using the microwave 
technique. After polymerization, flasks were allowed to cool 
at room temperature for over 12 hours and deflasked. 

Measuring	method
Dimensional change was measured using a three-

coordinate measuring machine (Tristation, TST 600-FC, 
Nikon Corp., Tokyo, Japan) graduated to an accuracy 
of 0.5 m or less at 20 °C with a ball stylus measuring  
0.5 mm in diameter (Figure 1). 

A device made of plaster was put on the surveyor to 
provide fixation for the denture specimen when measuring 
by probe. Two types of fixation devices were prepared 
to allow measurements to be taken on the fitting surface 
and the occlusal side. The measurements were performed 
on working casts, wax dentures, and dentures after 
deflasking.

The probe interfaces with the computer to measure 
and record point locations in the x-, y-, and z-axes. Such  

Figure	1. The measuring machine used in this study (Tristation).

Processing 
method

Brand Polymerizing 
cycle

Processing technique Powder-to-liquid ratio 
(g/ml)

Manufacturer

Heat polymerizing (HP) Bio resin 90 min at 70 °C
30 min at 100 °C

Hot water bath 10/4.5 Shofu
Kyoto, Japan

Microwave 
polymerizing (MP)

Acron MC 3 min Microwave 500W 10/4.3 GC
Tokyo, Japan

Tabel	1. Materials used in this study

Figure	3. Probing to detect measuring point.Figure	2. Probing to detect reference point.



� Dent. J. (Maj. Ked. Gigi), Vol. 40. No. 1 January-March 2007: 6–10

Figure	6. Dimensional change after polymerization (artificial 
teeth). The cross point of the axes indicates the center 
of the three reference points.

a digitizing system requires a reference plane to standardize 
the three-dimensional measurements. In this study, the 
reference plane (x-y plane) was established as the plane 
linking the centers of the hemispherical elevations 4 mm in 
diameter placed at three points on the palate of the denture, 
on both the polishing side and the fitting side. The center 
was measured by probing the surface of each reference 
hemisphere ten times (Figure 2). 

The measurement points consisted of 12 points on 
the cast and five points on the artificial teeth in the 
form of hemispherical hollows 2 mm in diameter. Each 
measurement point was measured three times, and the 
average value was used (Figure 3).

results

Measurement	accuracy
The measurement accuracy of each method was 

determined by calculating the square root of the standard 
deviation of each measured value.15 The measurement 
accuracy on the stone casts was X-axis (5.6 m), 
Y-axis (2.9 m) and Z-axis (4.7 m). On artificial 
teeth, the measurement accuracy was X-axis (5.6 m),  
Y-axis (7 m) and Z-axis (7.5 m). The official measurement 
accuracy of the three-dimensional coordinate measuring 
machine was 5 m, so the above accuracies were considered 
to be adequate. 

Dimesional	changes
Figure 4, 5, and 6 show the dimensional changes after 

each polymerizing process for both the fitting surface and 
the polishing surface. The cross point of the x and y axes 
of the reference plane is the center of the three reference 
points, and this point is the reference point for measurement 
in this study. The distortion of the fitting surface of the 
alveolar ridge in both HP and MP occurred in a horizontal 
direction towards the center of the palate. The fitting 
surface of the alveolar ridge of the posterior section of MP 
moved slightly towards the alveolar mucosa compared to 
HP. The amount of distortion at the fitting surface of the 
alveolar ridge was similar in both polymerizing methods 
(Figure 7). The distortion of flanges in both polymerizing 

HP

HP

MP

MP

Lateral view

Posterior view

Figure	5. Dimensional change after polymerization. The cross 
point of the axes indicates the center of the three 
reference points.

Figure	4. Dimensional change after polymerization. The cross 
point of the axes indicates the center of the three 
reference points. Arrows indicate the direction of the 
change.

HP

Occlusal view

Fitting surface view

Reference point

Lateral view

Posterial view

HP
MP

MP

HP

10 mm



�Sadamori: A comparison of three dimensional change

methods involved horizontal movement towards the center 
of the palate. The center and posterior border of the palate 
in both polymerizing methods were displaced in the original 
direction, and the palate center in HP was distorted to  
a greater degree than in MP (Figure 7). The artificial teeth 
moved slightly backwards from the origin in a horizontal 
direction in specimens polymerized by both methods; 
however, the artificial teeth polymerized by MP tended to 
move more than those polymerized by HP (Figure7). 

The dimensional changes in the lateral and posterior 
views are shown in Figure 5 and 6. In the vertical direction, 
the anterior flange of the HP denture moved slightly, but the 
distortion of the flange was larger in the premolar region, 
and larger again in the molar region. In the MP denture, 
the vertical distortion was similar over the entire surface 
of the denture, and there was less distortion than in the HP 
denture (Figure 7). 

discussion

We revealed the influence of thickness on the linear 
dimensional change of a denture base resin.16 Developments 
in coordinated measuring systems, such as the Nikon 6000 
(Figure 1), which was originally developed for applications 
in engineering, would appear to have considerable potential 
in studies on the dimensional accuracy and stability of 
prosthetic appliances. This system offers the advantages 
of three dimensional measuring linked with sophisticated 
computer technology.

In this study, denture specimens were not polished 
because the generation of excessive heat during finishing 
and polishing with burs and arbor bands may have 
contributed to stress release.17–20

A three-dimensional coordinate measurement system 
that situates a coordinate system on the denture specimens 
was used to record distortion of the specimens in this study. 
The coordinate system used a hemisphere form of datum-
point. The distortion of the fitting surface was measured 
from the reference plane on the fitting side from which 
a coordinate system was set, and the movement of the 
artificial teeth and the distortion of the polishing surface 
were measured from the reference plane of the artificial 
tooth side, from which a coordinate system was set. The 
coordinate system of the fitting surface and the artificial 
teeth and polishing surface is not the same because of 
the measuring error created by the 4 mm standard balls. 
However, it is considered acceptable for comparison of 
the measured values between both surfaces. The vertical 
movement of the artificial teeth was measured using the 
standard plane set by the polishing surface.

Takahashi11 recorded the distortion in the vector of the 
fitting surface of specimens made by the similar model 
used in this study. This study used a different measurement 
method, but there was little difference between them in the 
measurements on the fitting surface. Some studies found 
that the distortion of the fitting surface and the movement 
of the artificial teeth were indicated by the vector. Our 
study found that the overall distortion of the denture 
occurred as a displacement into the center of the denture 
after polymerization. The fitting surface in the HP denture 
showed more vertical displacement after polymerization 
than the MP denture and this tendency was most sifnificant 
in the flange. In the HP denture, the heat is conducted 
from the surface to the center of the flask, so this process 
might be the cause of the vertical distortion of the flange in 
denture specimens. The amount of movement of the fitting 
surface in the MP denture was smaller than that in the HP 

Figure	7. Amount of distortion.



�0 Dent. J. (Maj. Ked. Gigi), Vol. 40. No. 1 January-March 2007: 6–10

denture, especially in the flange. These results are consistent 
with several reports.21,22 Nelson et al.23 also found that the 
amount of movement of artificial teeth in MP specimens 
tended to be greater than in HP specimens. Our results 
might be similar to their results. This may be due to the 
difference of thermal conductivity of both polymerizing 
process because microwave energy is independent of 
thermal conductivity.

This study clearly showed that various distortions of 
denture specimens after polymerization can be measured 
with a three-coordinate measuring machine. The overall 
distortion of the fitting surface in HP specimens was shown 
to be larger than in MP specimens. A more complete 
understanding of the distortion caused by different curing 
methods might improve the outcome for patients requiring 
complete dentures by shortening the adjustment period.

acknowledgement

This study was supported in part by a Grant-in-Aid for 
Scientific Research (16390617) from Japan Society for the 
Promotion of Science (JSPS).

references

 1.  Budtz-Jorgensen E. Treatment of edentulous patients. In: 
Prosthodontics for the elderly: Diagnosis and treatment. Chicago, 
IL: Quintessence; 1999, p. 203–28.

 2. Sadamori S, Hamada T, Nakai N, Nishimura M. Influence of denture 
wearing on the stage of dementia and ADL of the elderly with severe 
dementia - a two-year follow-up study in a dementia ward in a mental 
hospital. Dentistry in Japan 2004; 40:163–7.

 3. Kraut RA. A comparison of denture base accuracy. J Am Dent Assoc 
1971; 83:352–7.

 4.  Laughlin GA, Eric JD, Glaros AG, Young L, Moore DJ. A comparison 
of palatal adaptation in acrylic resin denture bases using conventional 
and anchored polymerization techniques. J Prosthodont 2001; 
10:204–11.

 5. Consani RL, Domitti SS, Rizzatti Barbosa CM, Consani S. Effect of 
commercial acrylic resins on dimensional accuracy of the maxillary 
denture base. Brazilian Dent J 2002; 13:57–60. 

 6. Huggett R, Brooks SC, Bates JF. The effect of different curing cycles 
on the dimensional accuracy of acrylic resin denture base materials. 
Quint Dent Tech 1984; 8:81–5.

 7. Jagger RG. Dimensional accuracy of thermoformed poly-methyl 
methacrylate. J Prosthet Dent 1996; 76:573–5.

 8. Wong DM, Cheng LY, Chow TW, Clark RK. Effect of processing 
method on the dimensional accuracy and water sorption of acrylic 
resin dentures. J Prosthet Dent 1999; 81:300–4.

 9.  Mainieri ET, Boone ME, Potter RH. Tooth movement and dimensional 
change of denture base materials using two investment methods. J 
Prosthet Dent 1980; 44:368–73.

 10. Garfunkel E. Evaluation of dimensional changes in complete dentures 
processed by injection-pressing and the pack and press technique.  
J Prosthet Dent 1983; 50:757–61. 

 11. Takahashi Y. Three dimensional changes of the denture base of the 
complete denture following polymerization. J Jpn Prosthodont 1990; 
34:136–48.

 12. Turck MD, Lang BR, Wilcox DE, Meiers JC. Direct measurement 
of dimensional accuracy with three denture-processing techniques. 
Int J Prosthodont 1992; 5:367–72.

 13. Jackson AD, Lang BR, Wang RF. The influence of teeth on denture 
base processing accuracy. Int J Prosthodont 1993; 6:333–40.

 14. Nogueira S, Ogle R, Davis EL. Comparison of accuracy between 
compression- and injection-molded complete dentures. J Prosthet 
Dent 1999; 82:291–300.

 15 Takahashi Y, Takeuchi T, Sawamura N, Inanaga A, Habu T. Improved 
denture measuring method using the three dimensional measurement 
system. J Jpn Prosthodont 1988; 32: 1358–1362.

16. Sadamori S, Ishii T, Hamada T. Influence of thickness on the linear 
dimensional change, warpage, and water uptake of a denture base 
resin. Int J Prosthodont 1997; 10:35–43.

 17. Woelfel JB, Paffenbarger GC. Dimensional changes occurring in 
artificial dentures. Int Dent J 1959; 9:451–60.

 18. Woelfel JB, Paffenbarger GC, Sweeney WT. Dimensional changes 
occurring in dentures during processing. J Am Dent Assoc 1960; 
61:413–30.

 19. Woelfel JB, Paffenbarger GC, Sweeney WT. Clinical evaluation of 
complete dentures made of eleven different types of denture base 
materials. J Am Dent Assoc 1965; 70:1170–88.

 20. Lorton L, Phillips RW. Heat-released stress in acrylic dentures. 
J Prosthet Dent 1979; 42:23–6.

 21. Takamata T, Setcos JC, Phillips RW, Boone ME. Adaptation of acrylic 
resin dentures as influenced by the activation mode of polymerization. 
J Am Dent Assoc 1989; 119:271–6.

 22. Wallance PW, Graser GN, Myers ML, Proskin HM. Dimensional 
accuracy of denture resin cured by microwave energy. J Prosthet 
Dent 1991; 66:403–9.

 23. Nelson MW, Kotwal KR, Sevedge SR. Changes in vertical dimension 
of occlusion in conventional and microwave processing of complete 
dentures. J Prosthet Dent 1991; 65:306–8.