Page 46 - Volume 2,Issue 2, July 2009
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© Benaki Phytopathological Institute
Papachristos & Stamopoulos
92
pours on
A. obtectus
development, longev-
ity and fecundity.
Materials and methods
Insects and essential oils
Second instar larvae and 3-day-old pu-
pae were obtained from laboratory cultures
of
A. obtectus
according to the procedure
described by Papachristos and Stamopou-
los (18). The essential oils tested were ex-
tracted from the following plants:
L. hybrida
(flowers),
R. officinalis
(leaves) and
E. globu-
lus
(unripe fruit). Plant samples were collect-
ed in mid July 1999 from an experimental
farm in the region of Thessaloniki, Northern
Greece, where they were cultivated at adja-
cent sites. Bulk samples of about 1 kg were
collected randomly from 20–30 lavender or
rosemary plants and three eucalyptus trees.
Samples were transferred to the laborato-
ry and 100 g subsamples were subjected to
hydro distillation using a Clevenger appara-
tus (Winzer
®
) within 24 h. The distilled es-
sential oils were dried over anhydrous sodi-
um sulphate and stored in a refrigerator at
5°C. The chemical composition of the essen-
tial oils used in the present study has been
reported by Papachristos
et al.
(17).
Exposure to essential oil vapours
Gastight glass jars of 710 ml volume with
screwedmetallic capswere used as exposure
chambers. A small piece of woven dental
cotton (diameter = 8 mm, height = 3.5 mm)
was attached to the undersurface of the cap
to serve as an oil diffuser following the ap-
plication of the appropriate amount of pure
essential oil. Dose levels were selected to
cause 10, 40 and 70% mortality according to
our findings in a previous study (19). The ex-
act doses of each essential oil applied were:
lavender: 0.2, 1.4, 2 μl/l air for larvae and 21,
36.8, 57.9 μl/l for pupae; rosemary: 1.4, 2.1,
2.8 μl/l air for larvae and 26.3, 52.6, 73.7 μl/l
for pupae; eucalyptus: 1.4, 4.2, 7.1 μl/l air for
larvae and 57.9, 73.7, 89.5 μl/l for pupae. For-
ty bean seeds containing about 30-40 sec-
ond instar larvae or 3-day-old pupae of
A.
obtectus
were placed in each jar. The same
methodology was followed for the control
without the application of essential oils. Six
replicates were used for each dose and in-
sect stage. After 48 h of exposure to essen-
tial oil vapours, the beans were transferred
to clean vials for four days and subsequently
the beans in half of the replicates were dis-
sected in order to count the dead larvae and
pupae. The beans from the other three rep-
licates remained intact and were observed
daily until the adult survivors emerged. The
developmental time from the end of expo-
sure to adult emergence was also recorded.
After emergence the beans were dissected
and dead larvae and pupae were counted.
Sublethal effects on adults
The effect of the essential oil vapours
on adult insects derived from the survived
treated larvae and pupae was also studied.
For this purpose male or female survivors
from each dose tested were weighted just
after their emergence and subsequently, 20-
30 of them were placed individually in plas-
tic Petri dishes (9 cm in diameter) in order to
record their longevity.
To study the fecundity and fertility of fe-
male survivors, about 15 females, emerged
from each dose tested, were placed individ-
ually with two untreated one-day-old males
taken from the mass culture in plastic Petri
dishes (9 cm in diameter) containing 10 beans
and allowed to mate and oviposit until their
death. The number of eggs laid was counted
daily. The eggs were kept in the Petri dishes
until the end of hatching and the number of
hatched and unhatched eggs was recorded.
Experimental conditions
All trials were conducted at 65 ± 5 r.h, 25
± 1 °C and a 12 h photoperiod.
Statistical analyses
All mortality data were corrected by us-
ing Abbott’s formula (1). T-test was used in
order to compare the average mortality cal-
culated four days after exposure to essen-
tial oil vapours with that recorded after the
emergence of the adults.
