MKGS Vol 44 No 2 April-Juni 2011.indd


88

Vol. 44. No. 2 June 2011

Research Report

Effectivity of 0.15% benzydamine on radiation-induced oral 
mucositis in nasopharynx carcinoma 

 

Remita Adya Prasetyo
Division of Oral Medicine 
Installation/Department of Dental & Oral Health, Dr. Soetomo Hospital 
Surabaya - Indonesia

ABSTRACT

Background: Nasopharynx carcinoma is the most common malignant tumour in head and neck region. Radiotherapy is the first 
choice of treatment for nasopharynx carcinoma that had not been metastases. The most common oral complications in radiotherapy 
is mucositis (± 80%). 0.15% benzydamine hydrochloride (HCl) oral rinse can be used to prevent radiation-induced oral mucositis. 
Purpose: The aim of this research was to study the effectivity of 0.15% benzydamine HCl oral rinse for prevention of radiation-induced 
oral mucositis in nasopharynx carcinoma. Methods: Samples were divided into 2 groups. Group A was using 0.15% benzydamine HCl 
oral rinse for 10 days. Group B was using placebo oral rinse for 10 days. Evaluation was conducted 3 times: first day, fifth day and 
tenth day of radiotherapy. The scoring used Spijkervet’s mucositis α score. Results: Independent t test analysis for initial occurrence 
of oral mucositis showed no significant difference between 2 groups. Paired t test analysis showed significant difference between initial 
mucositis α score and mucositis α score in tenth day in each group. Independent t test analysis showed no significant difference in 
mucositis α score in tenth day between 2 groups. Conclusion: In conclusion 0.15% benzydamine HCl oral rinse was not effective to 
prevent radiation-induced oral mucositis in nasopharynx carcinoma. 

Key words: 0.15% benzydamine hydrochloride, prevention, radiation-induced oral mucositis, nasopharynx carcinoma

ABSTRAK

Latar belakang: Karsinoma nasofaring (KNF) merupakan tumor ganas terbanyak di daerah kepala-leher. Radioterapi merupakan 
terapi pilihan utama KNF yang belum mempunyai metastasis jauh. Komplikasi akibat radioterapi dalam rongga mulut yang terbanyak 
adalah mukositis (± 80%). Salah satu obat untuk pencegahan mukositis akibat radioterapi adalah benzydamine hydrochloride 
(HCl) 0,15%. Tujuan: Tujuan penelitian ini adalah untuk mempelajari efektivitas penggunaan obat kumur benzydamine HCl 0,15% 
sebagai pencegah mukositis akibat radioterapi pada karsinoma nasofaring. Metode: Sampel dibagi ke dalam 2 kelompok. Kelompok 
A yang menggunakan obat kumur benzydamine HCl selama 10 hari. Kelompok B menggunakan obat kumur plasebo selama 10 hari. 
Evaluasi dilakukan pada tahap awal, hari ke-5 radioterapi dan hari ke-10 radioterapi. Alat ukur adalah skor mukositis α Spijkervet. 
Hasil: Analisis Independent t-test menunjukkan awal terjadinya mukositis antara kedua kelompok tersebut tidak berbeda bermakna. 
Hasil uji t berpasangan antara skor mukositis α awal dengan skor mukositis α evaluasi II pada masing-masing kelompok tersebut 
menunjukkan perbedaan yang bermakna. Berdasarkan uji t, skor mukositis α evaluasi II antara kelompok A dengan B tersebut tidak 
berbeda bermakna. Kesimpulan: Disimpulkan bahwa obat kumur benzydamine HCl 0,15% tidak efektif sebagai pencegah mukositis 
akibat radioterapi pada penderita KNF.

Kata kunci: Obat kumur benzydamine hydrochloride 0,15%, pencegahan, oral mukositis akibat radiasi, karsinoma nasofaring

Correspondence: Remita Adya Prasetyo, c/o Divisi Penyakit Mulut, Instalasi/SMF Kesehatan Gigi dan Mulut, RSUD Dr. Soetomo. 
Jl. Mayjend. Prof. Dr. Moestopo No. 6-8 Surabaya, Indonesia. E-mail: mitaprasetyo@gmail.com



89Prasetyo: Effectivity of 0.15% benzydamine on radiation

INTRODUCTION

Nasopharynx carcinoma (NPC) is the most common of 
malignant tumor in head and neck region and also in the 
Department of Ear, Nose and Threat. NPC also showed 
increasing number from year to year.1,2 NPC is a malignant 
tumor located in the nasopharynx, which manifestation 
including initial symptoms in the nose and ear, and late 
symptoms because of the expansion of primary tumor to 
surrounding organ in nasopharynx, or regional metastases 
to lymph nodes in the neck.2 

 Radiotherapy is the first choice of treatment for NPC 
that had not been distant metastases.1,3 This therapy is 
aimed to eradicate cancer cells with ionizing radiation. 
Radiotherapy is also occasionally associated with 
dysfunction and disintegration of healthy tissue during and 
after therapy, including oral mucosa, through delayed of 
cell maturation and development.4 

During the treatment of the head and neck radiotherapy, 
oral cavity is always in the risk of exposure of radiation. 
Therefore, oral complications are expected, such as 
radiation-induced oral mucositis, which is the most common 
oral complications (± 80%). Oral mucositis generally 
begin about ± 1–2 weeks after the start of radiotherapy 
(± 1000 cGy–2000 cGy). Oral mucositis is associated with 
significant pain, inability to tolerate food and fluids, affect 
speech, and further compromising patients’ response to 
complete planned radiotherapy, thus it can prolong the 
duration of radiotherapy.4–10 

Planning of the precise therapy before radiotherapy 
is aimed to prevent radiation-induced oral mucositis.9,11 

In several literatures, to prevent radiation-induced oral 
mucositis, 0.15% benzydamine hydrochloride (HCl) oral 
rinse was used. Benzydamine HCl is a nonsteroidal rinse 
with anti-inflammatory, local anesthetic, antipyretic and 
antimicrobial activities.9,12 This oral rinse can be effective 
in preventing oral mucositis.5,7,13 According to the 
medical records in the ENT Oncology Outpatient Clinic of 
Dr. Soetomo Hospital, there had not been any effort to 
prevent radiation-induced oral mucositis in NPC’s patients. 
No attention to radiation-induced oral complications 
is given yet. The purpose of this research was to study 
the effectivity of 0.15% benzydamine HCl oral rinse for 
prevention of radiation-induced oral mucositis in NPC.

MATERIALS AND METHODS

The design of this research used randomized controlled 
trial. Population of this research was NPC patients in the 
Department of Radiotherapy Dr. Soetomo Hospital who 
received radiotherapy. Inclusion criteria of the sample was 
cooperative sample, stage III & IV NPC without distant 
metastases (loco-regional advanced), histopathology results 
showed undifferentiated carcinoma (WHO type 3), which 

planned to receive fractional dose radiation 200 cGy per 
day, five times a week, man & woman, 30–60 years old, not 
undergoing chemotherapy, no symptoms about oral mucositis 
and xerostomia, no infection disease, no allergy, no systemic 
disease (liver and nephrotic disease, hypertension and 
diabetes mellitus), no consumption of drugs that could cause 
xerostomia (antidepressant, antihistamin, antihypertension, 
opiate, sedative and diuretic drugs), and no consumption of 
systemic analgesic drugs. Exclusion criteria of the sample 
was absent of visit and not using oral rinse as it was planned, 
could not undergo radiotherapy as it was planned, allergy to 
benzydamine HCl or other signs of side effect, and refused 
to continue this research.

Samples were divided into 2 groups. Group A was 
using 0.15% benzydamine HCl oral rinse 120 ml for 
10 days, rinse or gargle 15 ml for 60 seconds, three times 
daily. Each time before the radiation was conducted, 
samples were using oral rinse under supervision from 
researcher. Group B was using placebo oral rinse 120 ml for 
10 days, with the same protocol as group A. There was no 
intervention before, including dental treatment. Evaluation 
was conducted 3 times: first day, fifth day and tenth day 
of radiotherapy. The results of evaluations were recorded 
in the dental records. 

The assessment of oral mucositis used Spijkervet’s 
mucositis α score. This scoring technique was specifically 
developed to measure tissue changes relative to dose-
response relationships and the effects of preventative 
mucositis strategies. Spijkervet states that the mucositis 
scores developed by this technique are basically useful 
for research and are of limited value clinically because the 
total score α does not always reflect the clinical condition 
of the patient. This scoring distinguishes the most common 
and significant local clinical signs of radiation mucositis 
that represent the order or progression of mucosal radiation 
damage (k) that includes no mucositis, white discoloration, 
erythema, pseudomembranes, and ulceration. Eight 
anatomical areas (n) of the mouth are scored (right and 
left buccal mucosa, hard palate, soft palate, dorsum of 
tongue, right and left border of tongue, and floor of mouth), 
although any one area might include several subareas 
with different local signs of mucositis observed in that 
area. The length (k) of each identical local sign for each 
subarea is measured (in centimetres) and then summed 
and corresponds with a value E (1 ≤1 cm, 2 = 1.0–2.0 cm, 
3 = 2.1–4.0 cm, 4 ≥ 4 cm). The degree of mucositis for each 
subarea was defined as the product of the values k and E; 
the score for mucositis in an area was defined as the sum of 
these products. Finally, the overall Spijkervet’s mucositis 
α score is calculated as the mean of the scores assigned to 
the number of irradiated areas (n).6

Data analysis used descriptive and inferential 
(Independent t-test, Paired t-test, Mann-Whitney test and 
Fisher’s Exact test), with level of significance (α) was 
0.05 (5%).



90 Dent. J. (Maj. Ked. Gigi), Vol. 44. No. 2 June 2011: 88–92

Table 1. Homogenity test between group A and Group B 

Data type Group A Goup B Statistic test p

Sex:
- Man
- Woman

7 (70%) 
3 (30%)

7 (77.88%)
2 (22.22%)

Fisher’s exact test 1.000**

Age:
- Rate (years)
- SD

45.10
 7.95

45.11
 6.95

Independent t-test 0.997**

Level of education:
- Elementary
- Junior school
- High school

7 (70%)
2 (20%)
1 (10%)

5 (55.56%)
2 (22.22%)
2 (22.22%)

Mann-Whitney test 0.476**

NPC Stage:
- III
- IV

4 (40%)
6 (60%)

4 (44.44%)
5 (55.56%)

Fisher’s exact test 1.000**

OHI-S (first day)
- Rate 
- SD

2.60
0.88

2.26
0.96

Independent t-test 0.426**

Notes: **: no significant different (p > 0.05)

Table 2. Independent t-test analysis for initial occurence of oral 
mucositis between group A and group B

Group N Rate SD p

Initial occurence
of oral mucositis

A
B

10
 9

7.20
7.56

1.14
1.13

0.504**

Notes: ** : no significant difference (p > 0.05)

Table 3. Paired t-test analaysis for mucositis α score in group 
A (The 1st, 5th and 10th day of radiotherapy)

Group A N Rate SD p

Mucositis α score (1st day)
Mucositis α score (5th day)
Mucositis α score (1st day)
Mucositis α score (10th day)

10
10
10
10

0.00
0.00
0.00
1.37

0.00
0.00
0.00
0.79

- ***

0.00*

Notes: *: significant difference (p < 0.05); ***: could not 
be analyzed

Table 4. Paired t-test analaysis for mucositis α score in group 
B (The 1st, 5th and 10th day of radiotherapy)

Group B N Rate SD p

Mucositis α score (1st day)
Mucositis α score (5th day)
Mucositis α score (1st day)
Mucositis α score (10th day)

9
9
9
9

0.00
0.00
0.00
1.86

0.00
0.00
0.00
0.96

- ***

0.00*

Notes: *: significant difference (p < 0,05); ***: could not 
be analyzed

RESULTS  

This research was completed in 3 months and included 
19 samples. Group A was 10 samples and group B was 
9 samples. Statistic analysis (Table 1) showed the 
homogenity of sex, age, level of education, NPC stage 
and Oral Hygiene Index Simplified (OHI-S) in the first 
day of radiotherapy, between group A and B (p > 0.05). 
Independent t-test analysis for initial occurence of oral 
mucositis between group A and group B (Table 2) showed 
p = 0.504 (p > 0.05), it meaning there was no significant 
difference between 2 groups.

Paired t test analysis showed significant difference 
between initial mucositis α score and mucositis α score in 
tenth day in each group (Table 3 & 4). Independent t test 
analysis showed no significant difference in mucositis α 
score in tenth day between 2 groups (Table 5).

DISCUSSION

The design of this research was randomized controlled 
trial. This clinical trial was an experimental trial with human 
being as the sample. This research was phase III clinical 
trial because it aimed to evaluate new treatment, compared 
with placebo.14 The homogenity between 2 groups (Table 1) 
must be tested to know about the factor that could affect 
mucositis α score. If there was any difference between 
2 groups, the reason of difference was only because of 
the experiment that were given in both groups.14 Table 1 
showed that group A and B were homogen.

Initial occurence of oral mucositis between 2 groups 
showed no significant difference among them (Table 2). 
It meant that 0.15% benzydamine HCl was not effective 
to delay the initial occurence of oral mucositis, as in 
placebo. This was similar with Putwatana et al.,15 that 

comparing benzydamine with natural agents, glycerine 
payayor (herbal product) was found to be superior in 
preventing and relieving radiation-induced oral mucositis 
than benzydamine hydrochloride. Although 0.15% 
benzydamine HCl also had antimicrobial effect, it could 



91Prasetyo: Effectivity of 0.15% benzydamine on radiation

Table 5. Independent t-test analysis for mucositis α score between group A and group B in 1st, 5th and 10th day of radiotherapy

Group N Rate SD p

Mucositis α score (1st day)

Mucositis α score (5th day)

Mucositis α score (10th day)

A
B
A
B
A
B

10
9
10
9
10
9

0.00
0.00
0.00
0.00
1.37
1.86

0.00
0.00
0.00
0.00
0.79
0.96

- ***

- ***

0.245**

Notes: **: no significant difference (p > 0.05); ***: could not be analyzed

not delay this disorders. It might because rinsing was not 
guaranteed to have enough contact between antimicrobial 
agent with microorganism, so 0.15% benzydamine HCl as 
antimicrobial could not help the antiinflammation effect. 
But the research of Epstein et al.13 and Worthington et 
al.,16 stated the opposite things. These differences because 
the method to assess oral mucositis was different. Epstein 
et al.,13 used mucositis score based on subjective and 
clinical manifestation of oral mucositis (erythema, 
ulceration and pain). Worthington et al.16 recommended 
in additional large trials to determine benefit, dosage, and 
administration method. While Spijkervet’s mucositis α 
score used in this research was a special method for research 
so the assessment is accurate. This method assessed clinical 
changes of radiation-induced oral mucosa in qualitative 
and qualitative ways (white discoloration, erythema, 
pseudomembrane and ulceration), not subjective complaint 
or dysfunction of oral cavity. It is important to note that, 
whereas the score developed by the Spijkervet technique 
will not always reflect the clinical state of the patient, it does 
quantify the degree of tissue change or damage.6 Besides 
that, the differences might be caused by initial occurence of 
oral mucositis was not due to the microba, but because of 
the radiotherapy’s side effect. Thus the use of antimicrobial 
agent did not have effect, and the antiinflammation was 
playing the role. The antiinflammation effect depends 
on oral hygiene, tissue resistance to radiotherapy, total 
dose of radiotherapy and how long the patient received 
radiotherapy. In this research, oral hygiene in the first day 
of radiotherapy between 2 groups was homogenous (Table 
1), but it meant both groups had bad oral hygiene, so it 
might stimulate the initial occurence of oral mucositis. 
This was similar with Köstler et al.,12 Berger & Kilroy,17 
Cheng et al.,18 which reinforced oral hygiene as a important 
direct factor that could affect the degree of severity and 
duration of mucositis. Besides oral hygiene, there were 
also radiation source, daily doses, cumulative doses and 
irradiated mucosa volume. The side effect of radiotherapy, 
especially sensitive to cell with faster proliferation such as 
tumor cell, but this effect also affect healthy tissue in the 
radiation field, so tissue resistance was decreased because 
of radiotherapy.4

There was significant differences between the rates 
of mucositis α score in the first and the tenth day of 

radiotherapy in each group (Table 3 and 4). This fact 
could be caused by the initiation of oral mucositis in both 
groups, so mucositis α score could be assessed already. 
There was no significant different of mucositis α score’s 
rates between group A and group B in the tenth days. 
(Table 5). It meant that 0.15% benzydamine HCl was 
not effective, as in the placebo. This was similar with 
Rosenthal and Trotti8, Hancock et al.11 which stated that 
the risk for developing radiation-induced oral mucositis 
depends on different factors, such as anti cancer treatment 
protocol, age and diagnosis of the patient, level of oral 
hygiene during therapy, genetic factors. Kartabrata et al.4 

and Beck,19 said that disintegrity of lining mucosa was port 
d’entry of microorganism and caused local infection which 
potentially disseminated through blood stream. According 
to Stokman et al.,7 Epstein et al.13 and Kazemian et al.,20 
there was significant different of mucositis score between 
group using benzydamine with placebo as a prevention 
because it proved could prevent or reduce the severity 
and the risk of secondary infection and bleeding because 
of benzydamine’s antiinflamation effect. Besides, those 
research used different definition of prevention, that 
was to prevent or reduce clinical manifestation of oral 
mucositis. While in this research, the definition was to 
prevent the occurence of oral mucositis. Therefore, it can 
be concluded that 0.15% benzydamine HCl oral rinse was 
not effective to prevent radiation-induced oral mucositis in 
nasopharynx carcinoma. It will need further research and 
better cooperation between specialists of oncology radiation 
and oral medicine.

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