Vol 50 No 4 Desember 2017.indd


171171

Effects of herbal medicine components on the physical properties of trial 
denture adhesives

Kenichiro Nakai,1 Takeshi Maeda,1 Guang Hong,2 Tadafumi Kurogi,3 and Joji Okazaki1
1Department of Removable Prosthodontics and Occlusion, Graduate School of Dentistry, Osaka Dental University, Hirakata-Japan
2Liaison Center for Innovative Dentistry, Tohoku University Graduate School of Dentistry, Sendai-Japan
3Department of Prosthetic Dentistry, Graduate School of Biomedical Sciences, Nagasaki University, Nagasaki-Japan

ABSTRACT

Background: Denture adhesive is widely used in elderly people who wear complete dentures. Chinese herbal medicine has long 
been used for the treatment of oral disease. The addition of herbal medicine to denture adhesive might be used to develop an adhesive 
which is effective for xerostomia patients. Purpose: The purpose of this study was to evaluate physical properties and cytototoxicity of 
herbal medicine components in denture adhesive. Methods: This study used a combination of 35wt% PVM-MA, 20wt% CMC, 40wt% 
white petrolatum and 5wt% liquid paraffin as base materials. Three kinds of herbal medicine components: Maimendong (Ophiopogon), 
Fuling (Hoelen) and Dongkuizi (Cluster mallow seed) were added to base materials of 1wt%, 5wt% and 10wt%. The initial viscosity was 
measured using a controlled-stress rheometer (AR-G2). The adhesive strength was quantified according to ISO-10873 recommended 
procedures. All data was analyzed independently by one-way Anova combined with a Turkey’s multiple comparison test at a 5% level 
of significance. Results: Significant differences were observed between materials in initial viscosity (p < 0.05). Specifically, samples 
containing 5wt% and 10wt% of Maimendong (Ophiopogon) showed higher values compared with the control samples. The larger the 
amounts of herbal medicine components, the greater the changes in the adhesive strength of denture adhesives over time. The denture 
adhesives containing herbal medicine components do not have a cytotoxic effect and are safe for use in actual clinical practice. 
Conclusion: The study showed that the addition of herbal medicine components does not affect physical properties (i.e. initial viscosity 
and adhesive strength) of denture adhesive and cytotoxicity in fibroblast cells.

Keywords: Ophiogon; Hoelen; Cluster mallow seed; herbal medicine; denture adhesives; initial viscosity; adhesion strength; 
cytotoxicity

Correspondence: Guang Hong, Liaison Center for Innovative Dentistry, Graduate School of Dentistry, Tohoku University, 4–1 
Seiryo-machi, Aoba-ku, Sendai, 980-8575, Japan. E-mail: hong@m.tohoku.ac.jp

Dental Journal
(Majalah Kedokteran Gigi)
2017 December; 50(4): 171–177

Research Report

INTRODUCTION

According to the 2017 Annual Report on the Aging 
Society in Japan,1 the over-65s account for 27.3% of the 
entire country’s population. This constitutes the highest 
number of elderly in its history. Japan has, undisputedly, 
become regarded as a super-aging society, with the number 
of Japanese above the age of 80 surpassing 10 million. 
Many elderly people wear partial or complete dentures, 
with the rate of complete denture use known to increase 
with age.2 Denture function begins from the moment 
dentures are placed in the oral cavity. Therefore, having 
comfortable dentures is crucial to improving the quality 
of life of the elderly. However, the latter face numerous 

problems, such as xerostomia, anatomical limitations 
and psychological anxiety. The number of patients using 
denture adhesives to stabilize and maintain dentures is 
increasing worldwide. According to a census of American 
academic prosthodontists regarding denture adhesives, 
the general attitude toward their use has changed greatly 
over the last 10 years.3 Despite the range of disagreements 
regarding the clinical significance of denture adhesives, 
the fact remains that improvements in denture function, 
stability and maintenance have been observed following 
their application.4–7 

Denture adhesives are broadly divided into two types, 
liner (home reliners) and glue, based on their mechanism of 
action.8 Liner type denture adhesives fill the gap between the 

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v50.i4.p171–177

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mailto:hong@m.tohoku.ac.jp


172 Nakai, et al./Dent. J. (Majalah Kedokteran Gigi) 2017 December; 50(4): 171–177

denture and the oral mucosa, thereby improving adhesion. 
However, the damage (i.e. deviation, bite raising) caused 
by these materials has long raised concerns regarding 
their use.9–12 In addition, liner type denture adhesive can 
change the occlusal vertical dimension and promote ridge 
resorption, with the result that dental professionals pay little 
attention to such materials.

On the other hand, glue type denture adhesives are 
mainly composed of water-soluble polymers that absorb 
the saliva between the denture base and the oral mucosa, 
thereby improving adhesion. These types of denture 
adhesives are broadly divided into powder-form, cream-
form and sheet-form. Of these, the cream-form and powder-
form varieties are advantageous in that they are thin and 
do not affect the occlusal vertical dimension. Cream-form 
denture adhesives are also advantageous in terms of their 
durability.13 

Xerostomia, which is particularly common among 
complete denture users, is treated with humectants. 
Currently, no other treatments are available and no radical 
solution has been identified. However, symptoms such as 
xerostomia have long been treated with Chinese herbal 
medicines. In particular, the herbal medicines Maimendong 
(Ophiopogon), Fuling (Hoelen) and Dongkuizi (Cluster 
mallow seed), as written in Shennong Bencao Jing 
(The Classic of Herbal Medicine) and Bencao Gangmu 
(The Compendium of Materia Medica), have long been 
considered effective in curing illnesses characterized by 
dry mouth or tongue, conditions wherein the tongue dries 
and takes on a burnt color, and in treating the dry mouth 
in patients with head and neck cancers.14 In addition, 
Maimendong (Ophiopogon) has been used to improve 
xerostomia in patients with Sjögren’s syndrome.15 

Many researchers reporting the use of denture adhesive 
in vitro and in vivo have confirm its effectiveness in 
improving denture retention and stability, increasing bite 
force, improving taste discrimination and taste perception 
among other benefits.16–20 A number investigated the initial 
viscosity and adhesive strength of denture adhesives and 
the effect of components on the mechanical properties of 
denture adhesives in vitro.21,22 However, the effect of herbal 
medicine on the initial viscosity and adhesive strength 
remains unclear. A combination of herbal medicine and 
denture adhesive might be used to develop denture adhesive 
which proves effective in cases of xerostomia.

The purpose of the present study was to examine 
the effects of herbal medicine components on the initial 
viscosity and strength of denture adhesive, to examine 

the cytotoxicity of herbal medicine components on the 
fibroblast cell and to develop cream-form denture adhesives 
containing herbal medicines. The null hypothesis adopted 
was that the addition of herbal medicine components neither 
affects initial viscosity and adhesive strength nor induces 
cytotoxicity in fibroblast cells.

MATERIALS AND METHODS

The primary denture adhesive components used in 
the study consisted of polyvinyl methyl ether-maleic 
acid (PVM-MA) copolymer alkali salt and sodium 
carboxymethyl cellulose (CMC). In addition, white 
petrolatum and liquid paraffin were used as ointment bases. 
The composition, formulation and code are shown in Table 
1 and Table 2, respectively. After stirring a proportion of 
40wt% white petrolatum and 5wt% liquid paraffin, 35 wt% 
PVM-MA and 20 wt% CMC were added. The ingredients 
were mixed for two minutes using a vacuum mixer (VM-II, 
GC Co., Tokyo, Japan) to produce a control sample for use 
as a base. A powdered herbal medicine was subsequently 
added to the prepared bases at different concentrations of 
1wt%, 5wt%, and 10wt% (Table 2). The vacuum-mixed 
products were transferred to hermetically sealed containers 
and placed in a dark room at 23°C for 24 hours to yield 

Table 1. Primary denture adhesive components used

Polymer Manufacturer Lot. No.

Methoxy ethylene maleic anhydride copolymer 
(PVM-MA)

ISP Japan LTD., Tokyo, Japan CC600150446

Sodium carboxymethyl cellulose (CMC) Daiichi Kogyo Seiyaku Co., LTD., Kyoto, Japan 353847

White petrolatum (WPL) Nikko Pharmaceutical Co., LTD., Hatori, Japan 669319

Liquid paraffin (LP) Sigma-Aldrich Japan Co. LLC., Tokyo, Japan A7568

Table 2. Formulations of components

Code Base materials
Herbal medicine 

components

BMT01 PVM-MA 
35wt%; CMC 

20wt%
WPL 40wt%; LP 

5wt%

Maimendong 
(Ophiopogon) 1wt%

BMT05
Maimendong 

(Ophiopogon) 5wt%

BMT10
Maimendong 

(Ophiopogon) 10wt%

FKR01 PVM-MA 
35wt%; CMC 

20wt%
WPL 40wt%; LP 

5wt%

Fuling (Hoelen) 1wt%

FKR05 Fuling (Hoelen) 5wt%

FKR10 Fuling (Hoelen) 10wt%

TKS01 PVM-MA 
35wt%; CMC 

20wt%
WPL 40wt%; LP 

5wt%

Dongkuizi (Cluster 
mallow seed) 1wt%

TKS05
Dongkuizi (Cluster 
mallow seed) 5wt%

TKS10
Dongkuizi (Cluster 

mallow seed) 10wt%

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017.
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173Nakai, et al./Dent. J. (Majalah Kedokteran Gigi) 2017 December; 50(4): 171–177

experimental samples containing each of the three herbal 
medicines Maimendong (Ophiopogon), Fuling (Hoelen), 
and Dongkuizi (Cluster mallow seed); (Uchida Wakanyaku 
Ltd., Tokyo, Japan) (Table 2).

In this study, the initial viscosity was measured using 
a stress-controlled rheometer (AR-G2, TA Instruments 
Ltd., Tokyo, Japan) and a parallel plate measuring 2 cm in 
diameter witha gap between the plates of 54 μm (Figure 1). 
The instrument was used in a constant strain mode with an 
angular velocity of 10 rad/s at 37 ± 2°C. Five specimens 
were measured for each material.

Measurements were obtained using the ISO 108738 
prescribed sample holder I and a pressure-sensitive axle 
(Figure 2). Sample holder I was fabricated from methacrylic 
resin (Acron Lot. No. powder 0308011; liquid 0308092, 
GC Co., Tokyo, Japan). The hole of sample holder I was 
filled with 500 ± 5 mg of sample which was subsequently 
immersed in 300 ml of distilled water at 37 ± 2°C for 0, 1, 
10, 30, 60, 180 or 360 minutes. A load of 9.8 ± 0.2 N was 
applied to the sample using a constant load compression 
testing machine (A-001, Japan Mecc Co. Ltd, Tokyo, Japan) 
at a pressurizing velocity of 5 mm/min using a pressure 
sensitive knob for 30 seconds. The sample was then pulled in 
the reverse direction with tensile velocity using a materials 
testing machine (Model 5565, Instron Co., Canton, MA, 
USA) at a crosshead speed of 5 mm/min. Measurements 
were taken five times for each combination.

A methacrylate board prescribed by ISO 108738 
and measuring 5.0 x 5.0 cm was fabricated using heat-
polymerized denture base resin (Acron Lot. No. powder 
0308011; liquid 0308092, GC Co., Tokyo, Japan). Samples 
were applied evenly on the methacrylate board, immersed 
in distilled water at 37 ± 2°C for one hour and, finally, 
scrubbed 20 times with a denture brush under running 
water. The methacrylate board was subsequently observed 
visually and the presence or absence of residue clumps 
assessed five times. The sample was considered to have 
passed the test if no clumps of residue were observed during 
at least four of the five assessments.

Following degradation of 1.00 ± 0.05 gram of sample 
by the addition of 5.00 ± 0.05 g of propylene glycol, 300 
ml of distilled water were stirred in, before the sample 
was agitated further. Then, the electrode of a pH meter 

(Series 2368, Beckman Coulter Inc., Tokyo, Japan) was 
inserted and the pH value displayed three minutes later was 
recorded. The same measurement was recorded five times 
and the values were averaged.

Following culture with a human gingival fibroblast cell 
line (p10-13) in a 24-well plate (1104/well) for 24 hours, 
the sample was placed in cell culture inserts so that it would 
account for 10% of the entire culture medium (1500 μl/well). 
Culture was performed again at 37°C under 5% CO2 for 24 
hours. Then, OD at 450 nm spectrophotometry (n = 5) was 
measured using a WST-8 cell counting kit (Sigma-Aldrich 
Japan, Tokyo, Japan). For the apoptosis measurement, the 
cells (1104 cells/well) were exposed to specimens for 24 
hours in a 24-well plate. Following exposure, the cells 
were trypsinized, centrifuged and resuspended in 50 μl 
FBS containing 10 μg/ml Hoechst 33342 and 10 μg/ml 
propidium iodide (Sigma, MO, USA). After incubation for 
30 minutes in the dark at room temperature, the cells were 
spread onto microscope slides. A minimum of 300 cells 
were counted using a fluorescence microscope (BZ-9000, 
Keyence, Japan) with an excitation filter 340–380 nm, and 
cells were classified as apoptotic, necrotic or viable.

All data was statistically analyzed using one-way 
analysis of variance (Anova) combined with a Tukey’s 
multiple comparison test at a 5% level of significance. All 
analyses were computed with PASW Statistics for Windows 
(PASW Statistics 18, SPSS Japan Inc., Tokyo, Japan).

RESULTS

The initial respective viscosity of each sample is shown 
in Figure 3. Significant differences (p < 0.05) were observed 
between materials. More specifically, samples containing 
5wt% and 10wt% of Maimendong (BKT05 and BKT10) 
showed higher values compared with the control samples, 
while samples containing Dongkuizi (TKS01, TKS05 and 
TKS10) showed lower viscosity values compared with the 
control samples. In general, the addition of herbal medicines 
tended to increase the initial viscosity.

The adhesive strength prior to immersion for all samples 
is shown in Figure 4. All samples indicated values higher 
than 5kPa, which is the value recommended by the ISO 

Figure 1. Block diagram of viscosity test jig.
Figure 2. Block diagram of sample holder for adhesive strength 

test.8

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017.
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174 Nakai, et al./Dent. J. (Majalah Kedokteran Gigi) 2017 December; 50(4): 171–177

standard for denture adhesives.8 Significant differences 
were observed between materials (p < 0.05). Specifically, 
FKR01 and TKS01 showed higher values compared 
with those of the control samples. The adhesive strength 
tended to decrease when the proportion of herbal medicine 
components in the sample exceeded 5wt%.

Changes in the adhesive strength for each sample are 
shown in Figure 5. Compared with the samples containing 
herbal medicine components, the control samples showed 
higher values over time. The adhesive strength was more 
stable in those samples with a lower proportion of herbal 
medicine components.

All samples indicated favorable cleanability. None of 
the methacrylate boards exhibited clumps of residue in any 
of the five assessments. All samples showed weakly acidic 
to neutral pH values (6–7) conforming to ISO standards8 
(Figure 6). No significant differences were observed 
between materials (p > 0.05).

Figure 7 shows the cell survival rates relative to those 
for the control sample which was established as 100%. All 
samples with herbal medicine components showed high cell 

Figure 4. Adhesive strength before immersion.

Figure 6. pH value of materials.

Figure 7. Results of cytotoxicity test

Figure 3. Mean initial viscosity with standard deviation.

survival rates, but there were no differences in cytotoxicity 
when compared with the control samples. The proportions 
of necrotic cells are shown in Figure 7. The values for all 
samples were lower than 5%, with no significant differences 
between the experimental and control samples (p > 0.05).

DISCUSSION

The null hypothesis that the addition of herbal medicine 
components affects neither initial viscosity nor adhesive 
strength and lacks cytotoxicity for fibroblast cells was 
accepted. In the study reported here, the effects of herbal 
medicine components possessing therapeutic effects against 
xerostomia on the physical properties of denture adhesive 
materials were examined. The development of cream-
form denture adhesives containing herbal medicines that 
possess therapeutic effects against xerostomia was found 
to be feasible.

Denture adhesives, widely used by the elderly for 
improving stability and retention of complete dentures23, 

Figure 5. Variations in adhesive strength.

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017.
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175Nakai, et al./Dent. J. (Majalah Kedokteran Gigi) 2017 December; 50(4): 171–177

polymers, which may explain why the samples containing 
herbal medicines demonstrated a high initial viscosity. 
Such initial viscosity is closely related to the application of 
denture adhesives. Highly viscous materials compromise 
the application because it becomes difficult to squeeze the 
denture adhesive from the tube and apply it evenly on the 
mucosal surface of the dentures. Thus, adding only a small 
amount of herbal medicine is desirable.

Samples containing herbal medicine components not 
only demonstrated a less pronounced water immersion-
associated increase in adhesive strength compared with 
the control sample, but also manifested a comparatively 
lower adhesive strength. When a denture adhesive is 
immersed in water, the water-soluble polymers are 
degraded, thereby increasing its viscosity and adhesive 
strength.7,21,22 However, the samples containing herbal 
medicine components consisted of base material (the 
control group) with herbal medicine. When the adhesive 
strength was measured using the same amounts of material, 
the total amount of water-soluble polymer was, apparently, 
smaller than that in the control samples, resulting in a small 
water solubility-associated increase in the viscosity. This 
may have accounted for the marginal increase in adhesive 
strength.

According to ISO 10873,8 only those denture adhesives 
that exhibit the recommended standard values for adhesive 
strength, washing performance (cleanability) and pH can 
be used. All the herbal medicine-containing cream-form 
denture adhesives assessed in the present study complied 
fully with all ISO standards, indicating that these trial 
denture adhesives can be used in actual clinical practice. 
Because denture adhesives are applied to the mucosal 
surface of dentures and are in direct contact with the oral 
mucosa, they must be biologically safe.8 None of the trial 
cream-form denture adhesives used in the present study 
demonstrated cytotoxicity, which confirms that they are 
safe for use in actual clinical practice. Chinese herbs are 
generally classified as superior, middle and inferior. In 
Shennong Bencao Jing (The Classic of Herbal Medicine), 
the oldest Chinese text of pharmacology, superior herbs 
are described as medicines that nourish life, cause no side 
effects or harm and can be consumed safely, even in large 
quantities over extended periods. However, middle and 
inferior herbs entail the risk of side effects and other damage 
and must be used with caution. The three herbal medicines 
used in the present study are all classified as superior herbs. 
This may be a reason why no materials used in this study 
indicated the presence of cytotoxicity.

Chinese medicine is not suited to acute illnesses or 
symptoms identified by modern medicine. However, in 
recent years, it has been frequently used to support the 
postoperative recovery of physical strength. In an increasing 
number of cases, Chinese medicine and modern medical 
science are being used in combination. Chinese herbs are 
used for patients who complain of xerostomia. In fact, 
in these patients, Chinese herbs are used in far greater 
amounts compared with those used in the present study. 

are broadly divided into two types: liner and glue.8 When 
patients use glue type denture adhesives (classified 
into cream-form, powder-form and sheet-form denture 
adhesives) under a dentist’s supervision, these prove 
effective in improving denture stability and retention.4–7 

The primary components of cream-form denture 
adhesives are water-soluble polymers and white petrolatum. 
In the oral cavity, the water-soluble polymers absorb saliva, 
thereby increasing viscosity and adhesion strength.22,24 
PVM-MA and CMC, the main polymers used in denture 
adhesives, are the most common water-soluble polymers. 
Made from natural pulp, they are extremely safe and have 
various applications in situations where environmental and 
personal safety is of importance.25 However, the water-
soluble polymers used in current commercially available 
cream-form denture adhesives are degraded during use 
in the oral cavity, resulting in an early decrease in their 
adhesion strength.25 Therefore, the adhesion strength of 
denture adhesives should be more durable. Han et al.21 

examined combinations of water-soluble polymers to 
improve the durability of the adhesion strength and found 
consistent effects. Therefore, for the base material in the 
present study, we used a combination of 35wt% PVM-MA, 
20wt% CMC, 40wt% white petrolatum, and 5wt% liquid 
paraffin. This formulation was shown to be the most durable 
combination in our previous study, with strong, stable, 
adhesive action and the promise of commercial viability 
as a long-acting cream-type denture adhesive.21 

Xerostomia greatly affects oral health and causes various 
oral diseases. In the West, it is particularly pronounced 
in the elderly, with more than 20% of such individuals 
being reported as exhibiting subjective symptoms of 
xerostomia.26,27 In contrast, in Japan, nearly 20-40% 
elderly individuals reportedly exhibit subjective symptoms 
of this condition.28 Currently, in the absence of a radical 
solution, the main treatment for xerostomia involves the 
use of humectants. Herbal medicines such as Maimendong 
(Ophiopogon), Fuling (Hoelen), and Dongkuizi (Cluster 
mallow seed) are considered effective in curing illnesses 
characterized by dry mouth or tongue. The initial viscosity, 
adhesion strength, cleanability and pH are the routinely 
assessed physical properties of denture adhesives.

In this study, the experimental samples containing 
herbal medicines tended to demonstrate significantly 
higher initial viscosity values compared with those of 
the control samples. The initial viscosity of a denture 
adhesive is the viscosity prior to the absorption of water 
by the material.22,24 It represents properties unique to the 
composition of the material. Here, viscosity increased with 
a proportional increase in the herbal medicine components. 
This condition was particularly pronounced in samples 
containing Maimendong (Ophiopogon) which were more 
viscous than samples containing other herbal medicines. 
Maimendong (Ophiopogon) is a herbal medicine more 
viscous than either Fuling (Hoelen) or Dongkuizi (Cluster 
mallow seed). In addition, powdered herbal medicines 
are more viscous than white petrolatumor water-soluble 

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
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176 Nakai, et al./Dent. J. (Majalah Kedokteran Gigi) 2017 December; 50(4): 171–177

Therefore, both physical examination and a prescription 
from a physician are required which makes it difficult to 
use Chinese herbs on a larger scale. In addition, because 
denture adhesives can be purchased at pharmacies without 
a prescription, it is impractical for them to incorporate large 
amounts of herbal medicines. From these perspectives, 
it is desirable to include only small amounts of herbal 
medicines. 

Chinese medicines typically consist of two or more 
herbal components used in combination. Thus, Chinese 
prescriptions include many components. The combination 
of multiple medicines also enhances potency, while 
reducing undesirable side-effects. Therefore, multiple 
herbal medicines should be used in combination, rather 
than a single medicine. In this study, the effects of herbal 
medicines on the physical properties of trial denture 
adhesives, each containing only one type of herbal 
medicine, has been examined. Even a 10% concentration 
of Chinese herbal medicines did not result in cell damage. 
However, since this study only tested the effect of the 
herbal medicines after a 24-hour period of exposure, 
testing of longer duration involving the use of animal 
subjects are needed to ensure their safe use. In addition to 
explaining the action mechanisms of herbal medicines in 
animal experiments, future studies should also examine 
how combinations of multiple herbal medicines affect 
the physical properties of materials and both the water 
channels in the luminal membrane of salivary ducts and 
saliva secretion in test animals.

From the standpoint of physical properties, smaller 
amounts of herbal medicine components are associated with 
a lower viscosity and, consequently, superior operability 
of denture adhesives. Denture adhesives containing 
Maimendong (Ophiopogon), Fuling (Hoelen), or Dongkuizi 
(Cluster mallow seed) are non-cytotoxic and are, therefore, 
safe for use in real clinical practice. The study showed 
that the addition of herbal medicine components does not 
affect initial viscosity or adhesive strength and does not 
cause cytotoxicity in fibroblast cells. It may be, therefore, 
be feasible to develop cream-form denture adhesives 
containing herbal medicines.

ACKNOWLEDGEMENTS

We would like to extend our deep gratitude to Professor 
Hiroshi Murata of the Department of Prosthetic Dentistry, 
Graduate School of Biomedical Sciences, Nagasaki 
University for his guidance on all aspects of the present 
study. This research was supported by the National Natural 
Science Foundation of China (Project No. 81400560).

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