J Bagh College Dentistry                   Vol. 30(2),  June 2018                   Effect of phosphate 
   

Restorative Dentistry   5 
 

Effect of phosphate ester addition on transverse strength 

and hardness of heat cured acrylic denture base material 

 

ABSTRACT 
Background: acrylic resin denture base consider a common denture base material for its acceptable cost, aesthetic 

and  easy processing but still has disadvantages including easy of fracture and low impact strength. 

Material and method: The experimental group was prepared by addition of 15% phosphoric acid 2-hydroxyethyl 

methacrylate ester  (PA2HEME) with polymethyl methacrylate monomer; the experimental groups was compared 

with the control one. The specimens were prepared according to ADA specification No. 12 with dimension 65 mm x 

10 mm x2.5 mm (length x width x thickness respectively). The prepared specimens were tested by three-point flexural 

strength utilizing Instron Universal Testing Machine (WDW, Layree Technology Co.), Shore D hardness tester used to 

measure hardness test. Statistical analysis used student T- test, mean and standard deviation.   

Results: The result of PA2HEME group showed high significant reduction comparing to the control group for both 

transverse strength and hardness test. 

Conclusion: Mixing 15% of PA2HEME with 85% methyl methacrylate (MMA) can reduce the mechanical properties of 

new modified polymethyl methacrylate (PMMA) acrylic resin. 

Keyword: phosphoric acid 2-hydroxyethyl methacrylate ester, transverse strength and hardness. (J Bagh Coll 

Dentistry 2018; 30(2):5-9) 

 

INTRODUCTION 
The PMMA consider the most widely used 

material as denture base due to its favorable 

mechanical properties and its ability for 

modification (1) and the perfect resin material 

should have adequate biological response and 

mechanical properties. However, the mechanical 

properties of PMMA are important for function 

of removable denture such as compressive 

strength, tensile strength, dimensional stability, 

hardness, transverse strength and solubility (2). 

Addition of 15% PA2HEME to the heat cure 

acrylic denture base significantly reduced 

candida albicans adhesion and porosity (3), 

however according to Park et al., 2003, They 

found that modifying the PMMA with 

methacrylic acid to produce negative charge 

polymer could reduce denture stomatitis but with 

reduction in the physical properties of material(1). 

The aim of this study was to evaluate the effect 

of phosphoric acid 2-hydroxyethyl methacrylate 

ester containing PMMA group on following 

properties: Transverse strength and Hardness 

test. 

 
 

 

 

(1) M.Sc Student, Department of prosthodontics, 
college of dentistry, university of Baghdad. 

(2) Assistant professor, Department of 
prosthodontics, college of dentistry, university of 

Baghdad. 

 

MATERIALS AND METHODS 
Modified PMMA (mPMMA) polymer was 

prepared by addition phosphoric acid 2-

hydroxyethyl methacrylate ester (Sigma Aldrich) 

to methyl methacrylate monomer in 15% ratio 

then mixed with powder (vertex) according to 

manufacturer's    instruction. The P/L ratio was 

every 50g of PMMA was added to 22.7 ml of 

MMA monomer. Two groups were prepared in 

the present study, they were divided into group 

A control (vertex dental BV), group B 

phosphoric acid 2- hydroxyethyl methacrylate 

ester containing group. Ten  rectangular shape 

samples were prepared for transverse and 

hardness test according to ANSI/ADA No.12, 

1999 with dimension 65 mm length x 10 mm 

width x 2.5 mm thickness. The samples kept in 

distal water at 37ₒcfor 48 hours before testing to 

remove residual monomer.  

The flexural strength was measured by Instron 

testing machine. The acrylic strip was positioned 

at each end of metal rollers at 50 mm distance 

between two ends with centrally located rod that 

applied the load till fracture with  cross head 

speed 5mm/min speed. The Surface hardness 

was obtained by using a durometer hardness 

tester (shore D hardness) which consider 

acceptable for acrylic (plastic) material. The 

instrument consist of a blunt indenter (0.8 mm in 

diameter) that locate in cylinder (1.6 mm in 

diameter), which connect to a digital scale 

graduated from zero to 100 unit. The specimens 

were prepared for each group A and B. five 

readings were measured for every specimen, 

 

Zahraa saad abed karkosh B.D.S. )
1) 

Basima M.A. Hussien B.D.S., M.Sc, Ph.D.
(2) 



J Bagh College Dentistry                   Vol. 30(2),  June 2018                   Effect of phosphate 
   

Restorative Dentistry   6 
 

mean of these five reading was recorded as 

hardness value. In Statistical analysis, the mean, 

standard deviation and student T- test were used 

for each group.  

RESULTS 
The PMMA and modified PMMA polymers 

were examined by FTIR to determine about the 

presence of OH group. The result of test showed 

a changes occurred in area between 2800- 3100 

cm-1 of FTIR spectra of hydroxlated polymer 

which gave a broad band in 2950- 3050 cm-1 as 

compare to the control group. In addition, the 

result of FTIR showed for mPMMA that there is 

no humidity in the region of 2800- 3100 cm-1 

while the humidity present in the control PMMA 

as in figure (1) and (2). 

 
Figure (1) FTIR analysis for mPMM

 

Figure (2) FTIR analysis for control PMMA 

 

A- Transverse strength results  
Means of transverse strength test 

for control and PA2HEME 

containg groups are shown in 

figure(3).

 

 

 

 

 

 

Figure (3) the mean of transverse strength by groups 

The results in table (1) showed that the 

control group had higher transverse 



J Bagh College Dentistry                   Vol. 30(2),  June 2018                   Effect of phosphate 
   

Restorative Dentistry   7 
 

strength (97.014) than experimental group 

(77.520) with high significant differences 

between them when P < 0.05. 

 
 

Table (1) descriptive and statistical test of transverse strength between groups 

group number mean SD T df P- value 

Control 10 97.014 1.596 34.769 18 0.000 
PA2HEME 10 77.520 .773 

 

 
 

B-Hardness test results 

The results of hardness test for control and 

PA2HEME groups are shown in table (2) 

and figure (4). The control group had 

higher hardness values than experimental 

group with high significant difference with 

P-value ≤0.001. 

 

Figure (4) the mean of hardness test by groups. 

Table (2) descriptive and statistical test of hardness test between groups. 

group number mean SD T df P-value 

control 10 101.150 1.773 8.804 18 0.000 

PA2HEME 10 91.560 2.953 

DISCUSSION 
In the present study, 15% of PA2HEME added 

to monomer then mixed with acrylic resin 

powder to produce a new modified PMMA in 

order to improve both biological and mechanical 

properties, however this addition reduced the 

transverse strength and hardness. In addition, 

changing the material in order to improve one 

property may lead to deteriorates effect on other 

properties.  The effect of this addition on 

mechanical properties was evaluated by 

measuring, transverse strength and hardness test. 

Mixing two different types of liquid (MMA and 

PA2HEME) produced new polymer with free 

hydroxyl group that give a negative charge to the 

new structure of polymer which in turn effect on 

mechanical properties (4). 

Hardness test 
The results of hardness test showed highly 

significant reduction with P- value ≤ 0.05 of 

hardness test for phosphoric acid containing 

group with mean comparing to control group 

with mean, this could be due to PA2HEME 

prevent enlargement of polymer chains, thus 

alter the physical characteristics of new PMMA 
(5). 

Furthermore, the reduction in hardness test may 

result from the reduction of other components of 

monomer like ethylene glycol dimethacrylate 

(EGDMA) which is cross-linking agent (5). 



J Bagh College Dentistry                   Vol. 30(2),  June 2018                   Effect of phosphate 
   

Restorative Dentistry   8 
 

 The reduction in hardness of PA2HEME group 

may resulted from lengthen ester chain of 

mPMMA that increased the flexibility of 

material, this agree with Pavle et al., 2015 who 

used Itaconic acid instead of methacrylic acid for 

its advantageous point as a natural product (7-8) 

and less toxic (9), however; he found as the 

concentration of itaconic acid increase, both 

stiffness and deformation of the material 

increase, probably this occur due to 

plasticization action of aliphatic chain of itaconic 

acid, in addition, adding a methylene unite to 

increase the length of ester chain could increase 

the flexibility of material that cause internal 

plasticization of material.  Although, water 

sorption and solubility were not measured in the 

present study, the negatively charged polymer 

increased water sorption and increase the 

hydrophilicity of material (1).  There is 

hydrophilic radicals that could enhance water 

sorption and water considers complex solvent 

that interact with polymer because its polarity 

and forming hydrogen bonds that enable it to 

cluster and lead to plasticization of material 

matrix (10). 

Transverse strength 
The results showed  highly significant reduction 

in transverse strength of phosphoric acid 

containing group compare to control group and 

this probably result from the dilution of the 

cross-linking agent (EGDMA), since denture 

acrylic resin consist of powder (prepolymerized 

PMMA), monomer (MMA) and cross-linking 

agent (EGDMA), once polymerization reaction 

begin, the monomer partially dissolve in  the 

polymer to produce a new larger molecular 

weight  

Polymer with the help of cross-linking agent. 

The cross-linking agent add to concentration 

range between 5%-6% by weight, which may 

assist in growing the chain of polymerized 

polymer. However, in 1995, Arima et al., found 

that increasing the concentration of cross-linking 

agent could increase the flexural strength and 

modulus. 

The results go in agreement with those obtained 

by Gunjan et al., 2007 who found that increase 

the concentration of experimental phosphate 

compound, the flexural strength and modulus 

decreased. Furthermore, the reduction of 

transverse strength of mPMMA could attributed 

to  the repulsion forces created inside the 

polymer which is became obvious when the 

polymer is subjected  to mechanical tests like 

transverse strength or tensile test, because these 

repulsion internal forces could, effect on 

modulus of elasticity which consider the basic 

response of material to subjected forces, this 

agree with Sang et al., 2009. . The addition of 

15% of PA2HEME could reduce the transverse 

strength and hardness of new PMMA. However, 

many methods introduced to improve the 

mechanical properties of new PMMA in 

cooperation of fiber like polyethylene, carbon 

and glass (13-16). Also incooperation of fiber 

found to be effectively increased the transverse 

strength of PMMA (17). Although a pervious 

study suggest, addition of fiber may increase 

roughness of PMMA (18).  

CONCLUSION 

Modification of PMMA with PA2HEME 

cause high significant reduction in the 

transverse strength and hardness of 

mPMMA. 

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 الخالصة

و سهولة الكسر قاعدة األسنان تعتبرواسعة االستخدام بسبب تكلفتها مقبولة، الجمالية ,قابلة للمعالجة ولكن ال يزال لديه عيوب بما في ذلك لاالكريليك الراتنج  الخلفية:

 .قوة التأثير

هيدروكسي إيثيل ميثاكريالت استر مع مونومر ميثاكريالت متعدد -2حمض الفوسفوريك  ٪11تم تحضير المجموعة التجريبية بإضافة  المواد وطرق البحث:

ر السماكة على التوالي(. تم إعداد العينات الختبا× العرض × مم )الطول  2.1× مم  11× مم  51مع البعد  ADAالميثيل. تم تحضير العينات طبقا للمواصفة رقم 

 اختبار صالبة تستخدم لقياس اختبار صالبة. Dثالث نقاط اختبار قوة الثني باستخدام إنسترون العالمي اختبار آلة ، شور 

 قوة عرضية واختبار صالبة مقارنة مع مجموعة السيطرة.ل نسبة قليلة  قد سجلت  PA2HEMEأن مجموعة النتائج: 

لكن مع تقليل الصفات الميكانيكيمن المونيمر قد قللت جدا نسبة التصاق الفطريات لمادة الرانتج و %51مع  PA2HEMEمن  %11ان خلط االستنتاج: