149

Comparison of the Efficacy of Eleven Soil Termiticides on the 
Formosan Subterranean Termite (Coptotermes formosanus)

by

Izumi Fujimoto*, Akio Enoki, Shuji Itakura and Hiromi Tanaka

AbSTrAcT

Using the tunneling test, the standard test method recommended by the 
JWPA ( JWPS-TS-S), the minimum effective concentrations of 11 chemicals, 
known as major soil termiticides in Japan, were determined. Addition of the 
emulsifying agent, Tween 80, to the low water solubility chemicals among 
the termiticides yielded a 2- to 8-fold increase in their termiticidal efficacies. 
In contrast, addition of Tween 80 to the high water solubility chemicals 
produced no such enhancement of their termiticidal efficacies.

In the confined test, in the case of the repellent-type chemicals of the 11 
chemicals, all the test termites (10 workers and 2 soldiers) became intoxicated 
or paralyzed and moribund within one hour of exposure to the minimum 
concentration fulfilling the criteria of the JWPA standard test method. In 
the case of non-repellent type chemicals, all the workers became moribund 
within 2 hours of exposure to the minimum concentrations fulfilling the 
criteria of the standard test method; in contrast, it took 4 – 24 hours before 
the soldier termites became moribund.

Key words: Coptotermes formosanus Shiraki, termiticide, JWPA standard 
test method, tunneling test, confined test

InTrodUcTIon

 Formosan subterranean termites are considered as one of the most de-
structive insect pests of wooden structures throughout the world, especially 
in areas with warm, humid climates (Kuriachan and Gold 1998). control of 
subterranean termites has always been an important concern of homeown-
ers and the pest control industry. For the past 60 years, termite control has 
mainly relied on termiticide treatments (Schokecht et al. 1994; Ibrahim et al. 
2003). chlordane had nearly monopolized the termiticide market of Japan 

Faculty of Agriculture, Kinki University, nara 631-8505, Japan
*corresponding author; Email: felixfuji@mvf.biglobe.ne.jp



150  Sociobiolog y Vol. 59,  no. 1, 2012

until the first half of the 1980’s. However, this chemical was designated as a 
special chemical substance owing to its characteristics of not being readily 
degradable and showing high bioaccumulation and chronic toxicity, and was 
actually banned by an act passed in 1986 on the examination of chemicals and 
regulation of manufacture. organophosphates such as chlorpyrifos or phoxim 
began to be hastily employed as a substitute for chlordane, and were widely 
used. Termite damage recurred frequently within 5 years of the treatment in 
chlorpyrifos- or phoxim-treated houses, especially in areas of inhabitation of 
C. formosanus. The unusually short duration of the termiticidal performance 
of these chemicals became an issue of concern (Tsunoda et al. 1989). Further, 
many lawsuits for health reasons were filed by the inhabitants of chlorpyrifos-
treated houses, as well as by those of the neighboring houses. In an attempt 
to overcome these problems with chlorpyrifos and phoxim, the rates of dis-
appearance of these chemicals under various conditions and the minimum 
treatment concentrations of the two termiticides required to fulfill the criteria 
of JWPA Standard no.13 (1992) were investigated (Enoki et al. 1995). These 
experiments demonstrated that more than 70% of the chlorpyrifos or phoxim 
disappeared, mainly by evaporation, within a year from the soil underneath 
the floors of houses treated with chlorpyrifos or phoxim in Kyoto, nara 
or osaka. Also, the minimum treatment concentration of chlorpyrifos or 
phoxim required to fulfill the criteria of the JWPA standard was in the range 
of 0.05% to 0.1%. In those days, the treatment concentration of chlorpyrifos 
or phoxim for soil treatment defined by the specification of each chemical was 
1%. Therefore, it is almost impossible to obtain protection against termite 
attacks for 5 years of wood-constructions built on ground soil treated with 
1% solutions of chlorpyrifos or phoxim, because of the rapid evaporation 
of these chemicals from the soil. Thus, measurements of the decay rate of a 
termiticide at the treatment site and the minimum treatment concentrations 
of the chemicals for complete prevention of termite attacks are essential for 
the proper use of termiticides, that is, use of optimal concentrations that 
would provide adequate protection against termite damage, while not posing 
a threat to the environment or to the health of living beings.

 recently, numerous types of termiticidal formulations, consisting of a variety 
of chemicals, have been developed as substitutes for organophosphates, and 
are already available commercially. It has been established that examination 



151 Fujimoto, I. et al. — Efficacy of Termiticides on C. formosanus

of the boring activity of subterranean termites in treated soil is essential for 
evaluation of the termiticidal efficacy of a soil treatment chemical (Tamashiro 
et al.1987; Su et al.1997). In this study, to determine the minimum treatment 
concentrations of 11 chemicals which are widely used as soil termiticides in 
Japan fulfilling the criteria of the JWPS-TS-S, the termiticidal efficacies of 
the major chemicals were evaluated by laboratory tests.

MATErIAlS And METHodS

Test termites
The subterranean termites, Coptotermes formasanus shiraki, were used for 

the laboratory experiments. All the termites were collected from a labora-
tory colony maintained at the department of Applied biological chemistry, 
faculty of Agriculture, Kinki University.

Test chemicals
 All the chemicals tested were of technical grade: permethrin, bifenthrin, 

etofenprox, silafluofen, dinotefuran, clothianidin, imidacloprid, thiame-
thoxam, fipronil, chlorfenapyr and chlorantraniliprole.

Preparation of test samples
 A certain weight (mg ) of the chemical was dissolved in ethanol to obtain 

a given volume (undiluted solution). The solution was diluted with ethanol 
to the prescribed concentrations (diluted solutions). A certain weight (mg ) 
of Tween 80 (Tokyo chemical Industry co., ltd. Gr) was dissolved in a given 
volume (ml) of the undiluted solution; this solution was diluted to 50 times 
with distilled water to obtain an emulsion.

Tunneling test
 The tunneling test was carried out in accordance with the JWPS-TS-S. 

Sandy loam sieved through 20 meshes was heat-sterilized at 60°c until its 
weight became constant, to obtain the non-chemically treated dried soil. 
Twelve g of the dried soil was placed in a grass beaker (100 ml, 5 mm inside 
diameter). Three ml of the dilute solution of a chemical or emulsion of the 
chemical was added to the dried sandy loam in the glass beaker and mixed 
thoroughly. The glass beaker was allowed to stand in a thermostat at 40°c 
for 28 days. Three ml of distilled water was added to the soil in the beaker 
every 7 days. After 28 days, the beaker was taken out from the thermostat 



152  Sociobiolog y Vol. 59,  no. 1, 2012

and three ml of distilled water was added to the treated soil in the beaker. 
The moistened soil was tightly stuffed into the transparent part of a glass tube 
(15 mm inside diameter; 5 cm length of the transparent zone) with both the 
ends made of frosted glass for sliding contact. The glass tube was connected 
to two glass cylinders at both ends. Wood flakes (Ca. 5g ) were put into one 
of the two cylinders. Untreated soil (Ca. 20% moisture content) was placed 
in another cylinder, as shown in Fig. 1. one hundred worker and 10 soldier 
termites were introduced into the untreated soil in the cylinder. The assembled 
unit was incubated at 28°c in the dark for 3 weeks. After this test period, 
the boring distance (gallery) by the termites was measured and the degree of 
boring caused by the pests was rated on the following scale.

degree of boring 
0: no boring
1: boring distance under 1 cm
2: boring distance under 2 cm
3: boring distance under 3 cm
4: boring distance under 4 cm
5: boring distance over 4 cm

Fig.1. Apparatus for tunneling test.



153 Fujimoto, I. et al. — Efficacy of Termiticides on C. formosanus

 If all the test termites were dead before the end of the test period, the time 
elapsed (in days) was recorded. In order for the test chemicals fulfilling the 
criteria of the JWPS-TS-S, the degree of boring on the scale described above 
needs to be ranked 0 or 1. However, the test chemical is still considered to 
fulfill the criteria of the standard when the ranking of the degree of boring on 
the scale is 2, but all the test termites are dead within a week. Five replicates 
were prepared for each sample.

Confined test
 Twenty g of dried sandy loam was placed in a glass beaker (100 ml; 52 

mm inside diameter). Five ml of the dilute solution of a chemical or emulsion 
of the chemical was added to the soil in the beaker and mixed thoroughly. 
The beaker was allowed to stand in a thermostat at 40°c for 28 days. Five 
ml of distilled water was added to the soil in the beaker every 7 days. After 
28 days, the beaker was taken out from the thermostat. distilled water was 
added to the treated soil in the beaker to obtain a moisture content of ca. 
23%. The surface of the soil in the beaker was pressed and leveled off with the 
disk-shaped end (1.5 cm diameter) of a glass rod. Ten worker and two soldier 
termites were introduced into the soil 
in the beaker, as shown Fig. 2. The 
beaker was maintained at 28°c in the 
dark. The change in the activity of the 
termites was visually assessed every 
one hour for the first eight hours, 
and then every 24 hours. The times 
required for a 100% moribund rate 
(no ambulation) and 100% dead rate 
(no movement at all) of the termites 
were assessed. Three replicates were 
prepared for each sample.

rESUlTS And dIScUSSIon

Tunneling test
 The average distances and the average degrees of boring in the tunneling 

test of the 11 chemicals are shown in Table 1 - 3. Termites penetrated the 

Fig.2. Apparatus for confined test.



154  Sociobiolog y Vol. 59,  no. 1, 2012

untreated soil in the glass tube and reached the wood flakes in the opposite 
cylinder within 5 to 6 hours (Table 1). The termites also penetrated the soil 
layer containing 1,250 ppm (treated conc.; 5,000 ppm) of Tween 80 (w/w) 
and reached the wood flakes within 5 to 6 hours. The minimum effective 
concentrations in the soil of pyrethroids, permethrin, bifenthrin, etofenprox 
and silafluofen required to fulfill the criteria of the JWPS-TS-S were 50 ppm 
(treatment conc.; 200 ppm), 12.5 ppm (50 ppm), 200 ppm (800 ppm) and 
375 ppm (1,500 ppm), respectively (Table 1). When Tween 80 was added to 
each of the four pyrethroids at 5 to 10 times the amount of each pyrethroid, 
the minimum effective concentrations decreased to 25 ppm (treatment conc.; 
100 pm), 6.25 ppm (25 ppm), 100 ppm (400 ppm) and 200 ppm (800 ppm), 

Table 1. Termiticidal efficacy of 4 pyrethroids, permethrin, bifenthrin, etofenprox, and silafluofen, in 
the tunneling test ( JWPS-TS-S).

chemicals
conc.
in soil (ppm)

Mean boring 
distance 
(mm)

Mean 
boring 
degree

notes

Permethrin 
+ Tween 80

25 + 0 27 3 All the termites were dead within 17 days

50 + 0 4 1 All the termites were dead within 11 days

25 + 125 3 1 All the termites were dead within 11 days

bifenthrin 
+ Tween 80

6.25 + 0 16 2 All the termites were dead within 11 days

12.5 + 0 3 1 All the termites were dead within 11 days

6.25 + 62.5 1 1 All the termites were dead within 11 days

Etofenprox 
+ Tween 80

100 + 0 23 3 All the termites were dead within 12 days

200 + 0 5 1 All the termites were dead within 12 days

100 + 500 1 1 All the termites were dead within 11 days

Silafluofen 
+ Tween 80

200 + 0 15 2 All the termites were dead within 11 days

375 + 0 9 1 All the termites were dead within 11 days

200 + 1,000 4 1 All the termites were dead within 12 days

375 + 125 9 1 All the termites were dead within 11 days

Tween 80 1,250 50 5 Termites reached the wood flakes within 5 to 6 hours

Untreated - 50 5 Termites reached the wood flakes within 5 to 6 hours



155 Fujimoto, I. et al. — Efficacy of Termiticides on C. formosanus

respectively (Table 1). no dead termites were found in the borings in the 
treated soil (Fig. 3). The water solubility levels of permethrin, bifenthrin, 
etofenprox and silafluofen were 0.2 ppm (30°c), <0.1ppb (23°c), 0.02ppm 
(20°c) and 0.001 ppm (20°c), respectively. The treated soil layer contained 
3 ml of water. Therefore, the concentrations of the chemicals in the soil layer 
water were supposed to be lower than their minimum effective concentra-
tions. Thus, the low water solubility pyrethroids were emulsified with the 
emulsifying agent, Tween 80, which raised the termiticidal efficacy of the 
chemicals by about two fold of that of the corresponding chemical in the 
absence of the emulsifying agent. In addition, it took more than 11 days for 
the pyrethroids at the minimum effective concentrations to kill all the test 
termites in the tunneling tests of the chemicals (Table 1).

 The minimum effective concentrations of the 4 neonicotinoids, dinote-
furan, clothianidin, imidacloprid and thiamethoxam, required to fulfill the 

Table 2. Termiticidal efficacy of 4 neonicotinoids, dinotefuran, clothianidin, imidacloprid, and thiamethoxam, in 
the tunneling test. ( JWPS-TS-S).

chemicals
conc.
in soil (ppm)

Mean boring 
distance
(mm)

Mean 
boring 
degree (Avg.)

notes

dinotefuran 
+ Tween 80

12.5 + 0 33 4 All the termites were dead within 4 days.

25 + 0 11 2 All the termites were dead within 4 days.

12.5 + 125 31 4 All the termites were dead within 4 days

clothianidin 
+ Tween 80

12.5 + 0 26 3 All the termites were dead within 3 days

25 + 0 18 2 All the termites were dead within 3 days

12.5 + 125 24 3 All the termites were dead within 3 days

Imidacloprid 
+ Tween 80

25 + 0 22 3 All the termites were dead within 4 days

37.5 + 0 10 2 All the termites were dead within 4 days

25 + 125 22 3 All the termites were dead within 4 days

Thiamethoxam 
+ Tween 80

50 + 0 26 3 All the termites were dead within 3 days

100 + 0 16 2 All the termites were dead within 3 days

50 + 250 24 3 All the termites were dead within 3 days



156  Sociobiolog y Vol. 59,  no. 1, 2012

criteria of the JWPS-TS-S were 25 ppm (treatment conc.; 100 ppm), 25 ppm 
(100 ppm), 37.5 ppm (150 ppm) and 100 ppm (400 ppm) , respectively 
(Table 2). no enhancement of the efficacy was obtained with the addition of 
Tween 80 to the neonicotinoids. The water solubility levels of dinotefuran, 
clothianidin, imidacloprid and thiamethoxam are 40,000 ppm (20°c), 327 
ppm (20°c), 510 ppm (20°c) an 4,100 ppm (25°c), respectively. Each of 
the chemicals was supposed as dissolving completely in the soil-layer water, 

Fig. 3. Typical appearance of the soil in the tunneling test of a repellent 
rermiticide. no dead termites were found in the boring.

Fig. 4.  Typical appearance of the soil in the tunneling test of a non-repellent 
termiticide. About 20 dead termites were found in the boring.



157 Fujimoto, I. et al. — Efficacy of Termiticides on C. formosanus

yielding concentrations higher than the minimum-effective concentrations. 
Thus, the addition of an emulsifying agent to such high water solublity 
chemicals, which dissolve completely in the water existing in the soil layer, 
exerts no influence on the efficacy of the chemicals. All the test termites were 
dead within 3 or 4 days. Several dead termites were usually found inside the 
borings in the treated soil layer (Fig. 4).

 The minimum effective concentrations of fipronil, chlorfenapyr and 
chlorantraniliprole required to fulfill the criteria of the JWPS-TS-S were 
75 ppm (treated conc.; 300 ppm), 2,000 ppm (8,000 ppm) and 250 ppm 
(1,000 ppm) , respectively (Table 3). When Tween 80 was added to fipronil 
or chlorantraniliprole at 10 or 4 times the amount, the minimum effective 
concentrations of the chemicals decreased to 45 ppm (treatment conc.: 180 
ppm) and 125 ppm (500 ppm), respectively. In the presence of Tween 80 at 3 
to 5 times concentration of chlorfenapyr, the minimum effective concentration 
of chlorfenapyr significantly decreased to 250 ppm (1,000 ppm), one-eighth 

Table 3. Termiticidal efficacy of fipronil, chlorfenapyr and chlorantraniliprole in the tunneling test. 
( JWPS-TS-S).

chemicals
conc.
in soil (ppm)

Mean 
boring 
distance 
(mm)

Mean 
boring 
degree 
(Avg.)

notes

Fipronil 
+ Tween 80

45 + 0 31 4 All the termites were dead within 2 days.

75 + 0 11 2 All the termites were dead within 2 days.

45 + 225 22 3 All the termites were dead within 2 days.

45 + 450 12 2 All the termites were dead within 2 days.

chlorfenapyr 
+ Tween 80

250 + 0 42 5 All the termites were dead within 2 days.

2,000 + 0 19 2 All the termites were dead within 2 days.

250 + 250 24 3 All the termites were dead within 2 days.

250 + 500 20 3 All the termites were dead within 2 days.

250 + 750 18 2 All the termites were dead within 2 days.

250 + 1,250 4 1 All the termites were dead within 2 days.

chlorantraniliprole 
+ Tween 80

125 + 0 26 3 All the termites were dead within 3 days

250 + 0 13 2 All the termites were dead within 3 days

125 + 500 3 1 All the termites were dead within 3 days



158  Sociobiolog y Vol. 59,  no. 1, 2012

of that in the absence of Tween 80. The water solubility levels of fipronil, 
chlorfenapyr and chlorantraniliprole are 2.4 ppm(20°c), 0.12ppm(25°c) 
or 1ppm(20°c), respectively. Therefore, the concentration in the soil-layer 
water was supposed to be lower than its minimum effective concentration. 
Thus, the emulsification of low water solubility chemicals with Tween 80 
raises their termiticidal efficacy. 

All the test termites were dead within 2 or 3 days. Several dead termites 
were usually observed in the borings in the treated soil layer (Fig. 5).   

Confined test 
 After ten worker and two soldier termites were introduced into the soil 

with 23% moisture content treated with each of the chemicals, the activities 
of the termites was assessed (Tables 4 - 6). The activities of all the test termites 
were maintained for more than 24 hours in the soil containing 625 ppm or 
1,250 ppm of Tween 80 (Table 4). In the tunneling test, termites penetrated 
the soil layer containing 1,250 ppm of Tween 80 and reached the wood flakes 
within 5 to 6 hours (Table 1). Thus, the presence of Tween 80 at 1,250 ppm 
in the soil had no efficacy on the termites. All the termites in the soils treated 
with the minimum effective concentrations of the 4 pyrethroids required 
to fulfill the criteria of the JWPS-TS-S in the tunneling tests were seriously 
intoxicated or paralyzed, stopped walking within one hour, and were dead 

Fig. 5. Typical appearance of the soil in the tunneling test of a non-repellent 
termiticide. About 18 dead termites were found in the boring.



159 Fujimoto, I. et al. — Efficacy of Termiticides on C. formosanus

Table 4. Time required for a 100% moribund or dead rate after treatment with the 4 pyrethroids, 
permthirin, bifenthrin, etofenprox, and silafluofen, in the confined test.

chemicals
conc.
in soil (ppm)

Time required for 100% mori-
bund or dead rate (hr.)

Moribund dead

Permethrin + Tween 80

25 + 0
worker 1 48

soldier 1 24

50 + 0
worker 1 48

soldier 1 24

25 + 125
worker 1 48

soldier 1 24

bifenthrin + Tween 80

6.25 + 0
worker 2 24

soldier 2 24

12.5 + 0
worker 1 24

soldier 1 24

6.25 + 62.5
worker 1 24

soldier 1 24

Etofenprox + Tween 80

100 + 0
worker 1 48

soldier 1 24

200 + 0
worker 1 48

soldier 1 24

100 + 500
worker 1 48

soldier 1 24

Silafluofen + Tween 80

200 + 0
worker 1 24

soldier 1 24

375 + 0
worker 1 24

soldier 1 24

200 + 1,000
worker 1 24

soldier 1 24

Tween 80

625
worker >24 -

soldier >24 -

1,250
worker >24 -

soldier >24 -

Untreated -
worker >24 -

soldier >24 -



160  Sociobiolog y Vol. 59,  no. 1, 2012

within one day or two days (Table 4). The time required for a 100% moribund 
rate of the worker termites was the same as that for the soldier termites. This 
indicates that these pyrethroids penetrate into the termite bodies through 
their skin, because the soldier termites of C. formosanus are unable to ingest 
materials orally by themselves. The time periods required for a 100% moribund 
rate of the test termites in soil containing 25 ppm of permethrin, 6.25 ppm 
of bifenthrin, 100 ppm of etofenprox and 200 ppm of silafluofen were only 
1 hour, 1 hour, 2 hours and 1 hour, respectively, (Table 4) although none of 
the concentrations fulfilled the criteria for the tunneling test results (Table 
1). The time period required for a 100% dead rate of the test termites in soil 
treated with the minimum effective concentrations of permetnrin, bifenthrin, 
etofenprox and silafluofen was 1 day or 2 days (Table 4), while that in the 
tunneling test was in the range of 11 to 17 days (Table 1). Furthermore, not 
even one dead termite usually existed in the borings excavated by the termites 
in the soils treated with the four pyrethroids (Fig 2). That is, all the termites 
were dead and observed outside the treated soils in the tunneling tests. These 
findings suggest that the four pyrethroids showed a high repellent efficacy 
against C. formosanus.

The time required for a 100% moribund rate of the worker termites in soil 
treated with the minimum effective concentrations of dinotefuran, cloth-
ianidin, imidaclroprid and thiamethoxam required to fulfill the criteria of 
the JWPS-TS-S for the tunneling test was 2 hours, while that of the soldiers 
was 5 hours, 6 hours, 6 hours and 7 hours, respectively (Table 5). Thus, the 
time required for the soldiers was 3 to 3.5 times that for the workers. These 
findings indicate that a large portion of the total amount of each chemical 
incorporated into the workers was ingested orally from the dissolved water in 
the soil in which the chemicals were completely dissolved. The time required 
for a 100% dead rate of the termites in the soil treated with the minimum 
effective concentration of each neonicotinoid required to fulfill the criteria 
of the JWPS-TS-S for the tunneling test was 1 day or 2 days (Table 5), while 
that in the soil containing the same concentration as that in the confined 
test was 3 or 4 days (Table 2). In the tunneling tests, several dead termites 
were usually observed in the borings excavated by the termites (Fig. 4). These 
findings indicate that these neonicotinoids had no repellent effect against the 
termites. Imidaclroprid has also been reported to be a non-repellent type of 



161 Fujimoto, I. et al. — Efficacy of Termiticides on C. formosanus

termiticide (Ishizaka, 2004). The time required for a 100% moribund rate of 
the workers in soil containing 12.5 ppm of dinotefuran, 12.5 ppm of cloth-
ianidin, 25 ppm of imidaclroprid or 50 ppm of thiamethoxam was 3 hours. In 
the tunneling tests using the same concentrations of the neonicotinoids, the 
test termites dug a tunnel with a length of more than 20 mm in the treated 
soil, although all the test termites in the tunneling tests were dead within 4 
days (Table 2). Termites seem to dig tunnels in untreated soil and to advance 

Table 5. Time required for a 100% moribund or dead rate after treatment with the 4 neonicotinoids, 
dinotefuran, clothianidin, imidacloprid, and thiamethoxam, in the confined test.

chemicals
conc.
in soil (ppm)

Time required for 100% mori-
bund or dead rate (hr.)

Moribund dead

dinotefuran + Tween 80

12.5 + 0
worker 3 48

soldier 10 48

25 + 0
worker 2 48

soldier 5 24

12.5 + 125
worker 3 48

soldier 10 48

clothianidin + Tween 80

12.5 + 0
worker 3 48

soldier 6 24

25 + 0
worker 2 48

soldier 6 24

12.5 + 125
worker 3 48

soldier 6 24

Imidacloprid + Tween 80

25 + 0
worker 3 48

soldier 8 48

37.5 + 0
worker 2 48

soldier 6 48

25 + 125
worker 3 48

soldier 8 48

Thiamethoxam + Tween 80

50 + 0
worker 3 48

soldier 7 24

100 + 0
worker 2 24

soldier 7 24

50 + 250
worker 3 48

soldier 7 24



162  Sociobiolog y Vol. 59,  no. 1, 2012

by 8 to 10 mm per hour, because the termites penetrated the untreated soil 
layer over a length of about 5 cm and reached the wood flakes in the opposite 
cylinder within 5 to 6 hours (Table 1). These findings indicate that all the test 
workers were probably intoxicated or paralyzed within 2 hours in soil treated 
with the minimum effective concentration of a non-repellent type of chemical, 
required to meet the criteria of the JWPS-TS-S for the tunneling test. 

 The time required for a 100% moribund rate of the workers in soil treated 
with fipronil, chlorfenapyr and chlorantraniliprole at the minimum effec-
tive concentration required for fulfillment of the criteria of the JWPS-TS-S 
for the tunneling test was 2 hours (Table 6). This time period was the same 
as that for each of the neonicotinoids which exhibited no repellent effect 
against the termites. The value for the soldiers was 4 hours or 24 hours. The 
three chemicals were insoluble in water (Ca.4.6 ml), existing in the soil in 

Table 6. Time required for a 100% moribund or dead rate after treatment with fipronil, chlorfenapyr 
and chlorantraniliprole in the confined test.

chemicals
conc.
in soil (ppm)

Time required for  100% mori-
bund or dead rate (hr.)

Moribund dead

Fipronil + Tween 80

45 + 0
worker 3 24

soldier 5 24

75 + 0
worker 2 24

soldier 4 24

45 + 450
worker 2 24

soldier 4 24

chlorfenapyr + Tween 80

250 + 0
worker 4 6

soldier 7 8

250 + 250
worker 3 6

soldier 6 7

250 + 750
worker 2 6

soldier 4 7

chlorantraniliprole + Tween 80

125 + 0
worker 3 72

soldier 24 48

250 + 0
worker 2 72

soldier 24 48

125 + 500
worker 2 72

soldier 24 48



163 Fujimoto, I. et al. — Efficacy of Termiticides on C. formosanus

the confined tests. Emulsification of each of the chemicals with Tween 80 
enhanced the termiticidal activity of each by 2- to 8-fold as compared with 
the efficacies in the absence of the emulsifying agent, as mentioned above 
(Table 3). These findings indicate that a large portion of the total amount 
of each chemical incorporated into the worker termites was ingested orally 
when the chemicals were emulsified. The time required for a 100% dead rate 
of the test termites in soil treated with fipronil, chlorfenapyr and chlorantra-
niliprole at the minimum treatment concentration required for fulfillment of 
the criteria of the JWPS-TS-S for the tunneling test was 1 day, 6 hours and 
3 days, respectively (Table 6), while that in the tunneling test was 2 or 3 days 
(Table 3). Several dead termites usually existed in the borings excavated by 
the termites in the tunneling tests (Fig. 5). These findings indicate that the 
three chemicals had no repellent effect against the termites. Fipronil has also 
been reported as a non-repellent termiticide (Ibrahim et al., 2003).

The results of this study suggest that the water solubility of termiticides 
affects their termiticidal efficacy. Addition of an emulsifying agent improved 
the efficacy of the low  water solubility chemicals, showing the possibility of 
the efficacy being improved depending on the formulation employed.

In another study at the field site in Kagoshima Prefecture, soil treatment 
with the emulsion of the chemicals (3 l/m2) at the minimum effective con-
centrations needed to fulfill the criteria of the JWPS-TS-S for the tunneling 
test could protect against termite attacks for at least 5 years.

rEFErEncES
Enoki, A., K. Ueshima, S. Itakura, and H. Tanaka (1995) Termiticidal efficacy of 

organophosphates (II), rate of disappearance of organophosphates in soil and wood. 
Mem. Foc. Agr. Kinki Univ. 28:1 - 9 (in Japanease).

Ibrahim, S. A., G. Henderson, and H. Fei (2003) Toxity, repellency, and horizontal transmission 
of fipronil in the Formosan subterranean termite (Isoptera: rhinotermitidae). J. Econ. 
Entomol. 96: 461 - 467.

Ishizaka, K. (2004) new effective methods with a non-repellent termiticide, imidacloprid. 
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