In-Seok Park1, Hyun Woo Gil1, Tae Ho Lee1, Yoon Kwon Nam2, Sang Gu Lim3, Dong Soo Kim2. 1. Division of Marine Bioscience, College of Ocean Science and Technology, Korea Maritime and Ocean University, Busan 606-791, Korea. 2. Institute of Marine Living Modified Organisms (iMLMO), Pukyung National University, Busan 608-737, Korea. 3. Future Aquaculture Research Center, National Fisheries Research & Development Institute, Jeju 690-192, Korea.
Abstract
Optimum concentrations of anesthetic clove oil and anesthetic lidocaine-HCl were determined for a species of adult marine medaka, Oryzias dancena, over a range of salinity conditions, and investigated in a transport simulation experiment by analyzing various water and physiological parameters. Research indicated that the higher the concentration of anesthetic at each salinity, the shorter the anesthesia time at each salinity. At each concentration, fish were anesthetized slower at water salinities over 10 ppt (P<0.05). Anesthesia time at 10 ppt was faster than any other salinity. In 10 ppt salinity, the dissolved oxygen (DO) concentrations and respiratory frequencies of the clove-oil-administered groups decreased until 48 hours (P<0.05), whereas the NH4+ and CO2 concentrations increased until 48 hours (P<0.05). In same period, the DO, NH4+, and CO2 concentrations and respiratory frequencies all decreased as the clove oil concentration increased (P<0.05). The trends in the DO, NH4+, and CO2 concentrations and respiratory frequencies in the lidocaine-HCl-administered groups were similar to those in the clove-oil-administered groups. In conclusion, clove oil and lidocaine-HCl are effective anesthetics, improving the transportation of the marine medaka. The results from this study will contribute to safe laboratory handling of the marine medaka, which are commonly required by many research studies and experiments.
Optimum concentrations of anesthetic cloveoil and anesthetic lidocaine-HCl were determined for a species of adult marine medaka, Oryzias dancena, over a range of salinity conditions, and investigated in a transport simulation experiment by analyzing various water and physiological parameters. Research indicated that the higher the concentration of anesthetic at each salinity, the shorter the anesthesia time at each salinity. At each concentration, fish were anesthetized slower at water salinities over 10 ppt (P<0.05). Anesthesia time at 10 ppt was faster than any other salinity. In 10 ppt salinity, the dissolved oxygen (DO) concentrations and respiratory frequencies of the clove-oil-administered groups decreased until 48 hours (P<0.05), whereas the NH4+ and CO2 concentrations increased until 48 hours (P<0.05). In same period, the DO, NH4+, and CO2 concentrations and respiratory frequencies all decreased as the cloveoil concentration increased (P<0.05). The trends in the DO, NH4+, and CO2 concentrations and respiratory frequencies in the lidocaine-HCl-administered groups were similar to those in the clove-oil-administered groups. In conclusion, cloveoil and lidocaine-HCl are effective anesthetics, improving the transportation of the marine medaka. The results from this study will contribute to safe laboratory handling of the marine medaka, which are commonly required by many research studies and experiments.
The marine medaka, Oryzias dancena (Beloniformes; Teleostei), is a
euryhalineteleost that mainly inhabits the brackish or freshwater of river mouths
and estuaries around Bengal Bay and the Malay Peninsula (Roberts, 1998). It also has a short interval
between generations, with spawning possibilities just 60 days after hatching (Kim et al., 2009a; Goo et al., 2015). Most of its physiological attributes are
similar across a wide spectrum of salinities, ranging from complete freshwater to
normal seawater (Inoue & Takei, 2003;
Kang et al., 2008; Goo et al., 2015). The marine medaka isn’t indigenous to Korea.
However, this species is accredited by the Ministry of Land, Transport and Maritime
Affairs, Korea (Ordinance of Agriculture, Food and Fisheries, No. 1) and is imported
legally from Indonesia (Kim et al., 2009a,
2009b). Recently, the Institute of Marine
Living Modified Organisms (iMLMO) selected this species for a
living modified organism evaluation project. In line with this purpose, detailed
information on marine medaka biology has begun to be exploited, especially regarding
early gonadogenesis, sex differentiation, early ontogenesis, and embryogenesis
(Kim et al., 2009a, 2009b). In addition, Nam et al.
(2010) researched tolerance capacity to salinity changes in this species.
This species is highly capable of hyper-osmoregulation as well as
hypo-osmoregulation. Also, no marine medaka in the experimental group (0 to 40 ppt)
died from stress of salinity changes (Nam et al.,
2010).An effective high-density transport method for fish is essential to minimize stress
and reduce the chance of mass mortality (Ferreira et
al., 1984) during long periods of transportation and handling, and to
reduce expenses and avoid losses (Ferreira et al.,
1984; Staurnes et al., 1994). The
production of new equipment and transport procedures has had increasingly positive
effects on the transportation of live fish. In addition, anesthetics are also
effective method of transporting fish. Because, the use of anesthetics in
aquaculture reduces fish energy, allowing for the efficient transportation of fish,
ease of handling when measurements are taken, a reduction in the pain and trauma
experienced by experimental fish, and reduced handling stress (Park et al., 2009; Gil et al.,
2016). For example, the use of nonpoisonous salt has been shown to
alleviate stress and promote higher survival rates (Tomasso et al., 1980; Carmichael et al.,
1984; Carmichael & Tomasso,
1988; Gil et al., 2016). The use of
low-concentration calcium chloride is a cheap and effective method of handling and
transporting live fish (Grizzle et al., 1985;
Carmichael & Tomasso, 1988).In recent years, Park et al. (2014) reported
that anesthe-tic effect by changing water temperature (cold shock and heat shock).
Temperature shock anesthesia in fish is characterized by an absence of motion,
reduced power of exertion, and diminished nervous sensitivity. Temperature shock
anesthesia is reversible and leaves no residue in the tissues. No danger is imposed
to the user, other than the risk inherent in handling solid carbon dioxide if that
material is used (Park et al., 2014). But
temperature shock anesthesia has short anesthetic time for handling samples. Mass
mortality of samples may cause by this method, because process of this method is to
faint by temperature shock. Therefore, based on the fact that it is safe,
inexpensive, non-toxic to the environment and stable, and does not require a
withdrawal period compared to other synthetic-based anesthetics, the use of cloveoil and lidocaine-HCl has become more popular in the aquaculture industry (Kang et al., 2005; Park et al., 2011). The effects of cloveoil and lidocaine-HCl
as anesthetics have been studied in a number of fish species (Woody et al., 2002; Park et
al., 2004, 2009, 2011; Gil et
al., 2016).However, previous research on marine medaka has investigated the effects of
anesthetic cloveoil and lidocaine-HCl on water temperature and anesthetic effects
of changing water temperature and stress responses in the marine medaka (Park et al., 2011; Park et al., 2014). No previous research has investigated the
anesthetic effects of cloveoil and lidocaine-HCl on the marine medaka during
transportation. We have determined the aim of this research should concern a
euryhalineteleost, so the marine medaka was chosen. The aim of this study was to
determine optimum concentrations of anesthetic cloveoil and anesthetic
lidocaine-HCl for the marine medaka in various salinity conditions, and analyzing
various physiological and water parameters by a simulation experiment in optimum
salinity condition.
MATERIALS AND METHODS
1. Fish production and sampling
On 12 January 2009, 30 specimens of adult marine medaka, Oryzias dancena
were obtained from iMLMO, Pukyung National University,
Korea. The fish were reared and bred in the Fishery Genetics and Breeding
Sciences Laboratory of the Korea Maritime University. Ten thousand specimens of
adult marine medaka were bred from the original 30 specimens in 11 months. The
marine medaka used in the study were selected at random from the entire
population. Samples were measured using an electronic balance (Shimadzu, Japan)
and vernier caliper (Mitutoyo, Japan). Average body length and body weight of
the group were 30.8±3.52 mm (n = 50) and 334.9±60.04 mg
(n = 50), respectively.
2. Condition of anesthesia
The anesthetic experiment began on 29 December 2015 and ended on 20 February
2016. Fifty specimens from each of the groups were randomly selected for
respective experiment to investigate the anesthetic effects of cloveoil (Sigma,
USA) and lidocaine-HCl (Hongsung Chemical, Korea). Five water salinities, 0, 10,
20, 30, and 40 ppt, were set for the study and anesthetic water salinity was
identical with recovery water salinity. Water salinity of each group was
regulated to be same as the anesthetic water salinity during the experiment.
Until experiment termination, the water temperature was maintained at 26℃. All
the fish were deprived of food for 24 hours before the study. The study methods
for the anesthetic effect of cloveoil and lidocaine were taken from the methods
of Park et al. (2011). Furthermore, all
experiments were completed in duplicate.
3. Criteria of anesthetic effect
The decision-based anesthetic effect table shows the stages of anesthesia and
recovery that were used as endpoints (only opercular movement: A6; normal
swimming, responsiveness to visual stimuli: R6) in the present study (Summerfelt & Smith 1990; Woolsey et al., 2004; Park et al., 2011). During this experiment, anesthetizing
marine medaka involved several stages, from slowed swimming speed and side to
side rolling (stage A2) to only opercular movement (stage A6). At stage A6,
individuals were transferred to a recovery tank. Recovery time was established
as the point at which erratic swimming began. Recovery time included redressing
the balance (stage R5) and normal swimming, as well as responsiveness to visual
stimuli (stage R6).
4. Respiratory frequency
After anesthetic experiment, a simple sealed container, comprising an acrylic
resin box with a wall thickness of 8 mm and overall dimensions of 10 cm
(width)×50 cm (length)×10 cm (height), was used as a respirometer chamber. The
hose for the inflow water was equipped with a temperature controller and 10 µm
and 3 µm cartridge filters to exclude any particles. A flow-through ultraviolet
lamp was used to reduce the oxygen consumption by microbes. The temperature of
the water flowing into the respirometer chamber was maintained at 26±0.3℃ with a
heater. The water salinity was maintained optimum anesthetic salinity by
brackish water, and optimum anesthetic salinity of each group were analyzed by
anesthetic experiment. The respirometer chambers were prepared and labeled
according to the measurement times and anesthetic concentrations.
5. Criteria of water parameter effect
For determine the appropriate experimental concentrations of cloveoil and
lidocaine-HCl, we performed a pilot experiment for 48 hours. To prevent
mortality in the experimental sample, the anesthetized marine medaka were
maintained at several levels of anesthesia during the pilot study, ranging from
normal swimming, opercular movement, and general movement (stage A1) to slow
swimming and side-to-side rolling (stage A2) (Summerfelt & Smith, 1990; Woolsey et al., 2004; Park et al.,
2011). The anesthetic effects of cloveoil were determined at five
concentrations: 0.2, 0.4, 0.6, 0.8, and 1 ppm. The stock solution of cloveoil
was dissolved in 95% methanol (Sigma, St. Louis, USA) at a ratio of 1:10. The
effects of lidocaine-HCl were determined at five concentrations: 20, 40, 60, 80,
and 100 ppm. To neutralize the anesthetic solution (lidocaine-HCl solution) and
to amplify its effect (Park et al.,
2011), Na-HCO3 (Sigma, St. Louis, USA) at a total
concentration of 1,000 ppm was added to the solution.
6. Water parameter in anaesthetic experiment
Measurements were made at 6 hours intervals after experiment was begun, for 48
hours. Before the dissolved oxygen (DO) was measured, the concentrations of
ammonium (NH4+) and carbon dioxide (CO2) were
measured with a spectrophotometer (DR2800, HACH, Loveland, Colorado, USA) and
the respiratory frequencies (gill cover movements) of the fish were measured
with a counter and a digital timer. DO was measured with an oxygen electrode and
a multidata logger system (Oxyguard, Denmark).
7. Statistical analysis
The data were analyzed with one- and two-way ANOVA with the SPSS statistical
package (SPSS 9.0, SPSS Inc., USA). Differences between means were evaluated
with Duncan’s multiple range test and considered significantly different at
P<0.05.
RESULTS
No fish died from stress due to anesthesia during this anesthetic experiment. Table 1 shows the anesthetic effects of cloveoil at each concentration and water salinity. Anesthetic time was significantly
affected by water salinity and cloveoil concentrations, and decreased drastically
as the concentration of cloveoil increased (P<0.05). However,
the anesthetic effects on water salinity show a different trend. Anesthesia times
increased in the other salinities excepted for 0 ppt. Furthermore, at each salinity
concentration, the anesthetic time at 10 ppt was faster than the other salinities.
In addition, the pattern of recovery time was similar to that of anesthetic time
(P<0.05). With the exception of 0 ppt, recovery time
increased gradually at all other salinities. At 10 ppt, the recovery time at each
salinity concentration was faster than the other salinities. It is important to note
that the recovery times of cloveoil in each concentration were similar that each
salinity. Fig. 1 shows the concentration of
cloveoil and the ratios of recovery times in relation to anesthesia time relative
to the water salinity. In terms of trends, the ratio of recovery time to anesthesia
time gradually increased as cloveoil concentration increased at each water salinity
group (P<0.05). However, at each cloveoil concentration, the
ratio of the recovery time to anesthesia time in relations to the water salinity
decreased with the exception of 75 ppm (P<0.05).
Table 1
Effects of clove oil dose and starting water salinity on anesthesia among
marine medaka, Oryzias dancena
Dose(mgL-1)
Exposure time
(sec)*
0 ppt
10 ppt
20 ppt
30 ppt
40 ppt
50
160.0±9.43b
126.6±11.02a
206.0±19.83c
218.6±40.25d
226.4±39.10e
75
138.4±8.28b
83.0±18.38a
154.7±16.46c
159.9±39.76d
164.3±17.24e
100
100.8±4.29b
61.5±5.52a
108.9±6.31c
112.2
±15.75d
120.4±7.88e
125
73.5±12.61b
52.1±4.91a
80.9±11.59c
85.2±6.61d
90.9±8.97e
150
50.1±6.06a
44.2±2.94a
62.9±4.93b
62.8±8.93b
73.8±9.77c
Dose(mgL-1)
Recovery time
(sec)*
0 ppt
10 ppt
20 ppt
30 ppt
40 ppt
50
185.0±26.94c
133.2±14.81a
163.2±26.33b
160.8±20.84b
159.1±21.48b
75
188.5±29.02d
125.7±18.49a
155.7±15.10b
145.9±16.04c
145.8±18.59c
100
196.5±22.98c
116.7±13.28a
146.7±21.73b
145.6±20.58b
146.2±20.05b
125
193.8±34.00d
123.5±20.38a
143.5±20.97b
151.9±13.03bc
152.1±12.04c
150
175.6±33.94d
131.3±9.20a
157.4±12.10b
151.3±14.33c
157.5±13.20b
Two-way ANOVA (exposure time)
DF
Anova SS
Mean square
F-value
P-value
Salinity
4
30,475.440
7,618.860
26.055
<0.0001
Dose
4
618,919.0
154,729.7
529.150
<0.0001
Interaction
16
12,833.400
802.087
2.743
<0.0001
Two-way ANOVA (recovery time)
DF
Anova SS
Mean square
F-value
P-value
Salinity
4
48,654.896
12,163.724
29.521
<0.0001
Dose
4
5,557.856
1,389.464
3.372
<0.0110
Interaction
16
9,551.864
596.992
1.449
<0.1210
* Each value is mean±standard error of duplicate experiments.
Values in the same column not sharing common superscripts are
significantly different (P<0.05).
Fig. 1
Effect of clove oil dose and water salinity on the ratio of recovery
time/exposure time among marine medaka, Oryzias
dancena.
Error bar represents the standard error of duplicate experiments. Different
letters on the bars indicate statistical significance
(P<0.05).
* Each value is mean±standard error of duplicate experiments.
Values in the same column not sharing common superscripts are
significantly different (P<0.05).
Effect of clove oil dose and water salinity on the ratio of recovery
time/exposure time among marine medaka, Oryzias
dancena.
Error bar represents the standard error of duplicate experiments. Different
letters on the bars indicate statistical significance
(P<0.05).Table 2 shows the anesthetic effects of
lidocaine-HCl at each concentration and water salinity. At each salinity, the
anesthesia time decreased drastically as the concentration of lidocaine-HCl
increased (P<0.05). The anesthesia time increased as water
salinity increased between 200 ppm and 400 ppm. At other concentrations, the pattern
of lidocaine-HCl was similar to that of cloveoil. Recovery time exhibitted a
similar pattern, but the anesthesia time pattern differed. As the concentration of
lidocaine-HCl increased, recovery time at each concentration decreased at each
salinity group. At 0 ppt, the recovery time at each concentration was slower than at
any other salinity. However, at 10 ppt, the recovery time was faster than at any
other salinity. At water salinities over 20 ppt, recovery time decreased as water
salinity increased (P<0.05).
Table 2
Effects of lidocaine-HCl dose and starting water salinity on anesthesia
among marine medaka, Oryzias dancena
Dose(mgL-1)
Exposure time
(sec)*
0 ppt
10 ppt
20 ppt
30 ppt
40 ppt
200
250.1±14.90a
313.3±12.43b
323.8±38.75c
397.4±95.78d
396.1±63.49d
300
182.4±21.25a
255.8±29.20b
255.2±33.69b
260.9±39.18bc
263.0±30.29c
400
150.0±33.78a
170.1±17.76b
187.9±15.38c
200.9±27.14d
199.0±16.46d
500
110.4±15.46b
105.3±32.22a
158.9±28.97c
167.1±23.27c
167.9±28.31c
600
83.0±15.32a
82.4±28.19a
134.9±27.12b
134.8±16.75b
138.8±43.29c
700
76.0±16.63b
62.4±15.66a
95.6±35.76c
99.5±0 9.14c
101.5±34.31d
800
57.0±8.91b
47.6±7.21a
74.7±12.05c
76.6±0 4.86c
78.7±17.18c
Dose(mgL-1)
Recovery time
(sec)*
0 ppt
10 ppt
20 ppt
30 ppt
40 ppt
200
379.0±35.45d
208.2±20.83
a
330.0±37.33c
310.4±39.40b
308.2±58.47b
300
350.0±24.81d
234.4±131.83a
320.5±73.06c
305.2±34.50b
300.5±40.80b
400
327.2±68.13d
260.5±169.29a
280.5±48.56c
272.2±38.34b
270.4±84.46b
500
325.4±68.10d
214.0±92.94a
238.5±38.07c
223.8±35.34b
220.1±53.95b
600
325.8±156.61b
168.7±179.91a
169.8±29.72a
171.1±20.71a
170.0±33.56a
700
323.3±67.40c
146.9±56.28a
167.0±43.54b
166.8±31.70b
166.9±40.39b
800
322.1±60.25c
129.6±70.31a
132.3±20.15b
133.1±15.88b
132.5±24.74b
Two-way ANOVA (exposure
time)
DF
Anova SS
Mean square
F-value
P-value
Salinity
4
179,621.5
4,905.379
46.625
<0.0001
Dose
6
2,583,927
430,654.5
447.147
<0.0001
Interaction
24
92,106.646
3,837.777
3.985
<0.0001
Two-way ANOVA (recovery
time)
DF
Anova SS
Mean square
F-value
P-value
Salinity
4
638,164.1
159,541.0
52.927
<0.0001
Dose
6
1,248,225
208,037.6
69.016
<0.0001
Interaction
24
191,254.8
7,968.949
2.644
<0.0001
* Each value is mean±standard error of duplicate experiments.
Values in the same column not sharing common superscripts are
significantly different (P<0.05).
* Each value is mean±standard error of duplicate experiments.
Values in the same column not sharing common superscripts are
significantly different (P<0.05).Fig. 2 shows the concentrations of lidocaine-HCl
and recovery time ratios in relation to anesthesia time according to water salinity.
In terms of trends, the ratio of recovery time to anesthesia time gradually
increased as the lidocaine-HCl concentration increased at each water salinity group
(P<0.05). However, at each lidocaine-HCl concentration, the
ratios of recovery time to anesthesia time according to water salinity were
different from the cloveoil trend. At 0 ppt, the ratio of recovery time to
anesthesia time was higher than other salinities. Moreover, at all salinities
excepted for 0 ppt, the ratios of t recovery time to anesthesia time were similar
(P<0.05).
Fig. 2
Effect of lidocaine-HCl dose and water salinity on the ratio of recovery
time/exposure time among marine medaka, Oryzias
dancena.
Error bar represents the standard error of duplicate experiments. Different
letters on the bars indicate statistical significance
(P<0.05).
Effect of lidocaine-HCl dose and water salinity on the ratio of recovery
time/exposure time among marine medaka, Oryzias
dancena.
Error bar represents the standard error of duplicate experiments. Different
letters on the bars indicate statistical significance
(P<0.05).At each concentration of cloveoil and lidocaine-HCl, fish were anesthetized slower
at water salinities over 10 ppt. Anesthesia time at 10 ppt was faster than at any
other salinity. With the exception of 10 ppt, relationships between water salinity
and anesthesia time presented a positive gradual curve, with increased water
salinity (over 10 ppt) resulting in increased anesthesia time. Such a proportional
relationship has not been found in previous studies. For this species, lower
salinity resulted in significantly shorter anesthesia induction from cloveoil and
lidocaine-HCl (P<0.001).The results for the DO concentrations, the respiratory frequencies, and the
NH4+ and CO2 concentrations in the
clove-oil-administered groups are presented in Tables 3, 4, and 5 and Fig.
3, respectively. The DO concentrations and the respiratory frequencies
decreased in all the experimental groups up to 48 hours (P<0.05;
Tables 3 and 4, respectively), whereas the NH4+ and
CO2 concentrations in all the experimental groups increased up to 48
hours (P<0.05; Table 5
and Fig. 3, respectively). At 6 hours, both the
DO and NH4+ concentrations and the respiratory frequencies had
decreased with increasing cloveoil concentrations (all P<0.05).
At 6 hours, CO2 was 12.1±2.83 ppm for the control group, 10.5±3.35 ppm
for the 0.2 ppm cloveoil group, 9.2±2.13 ppm for the 0.4 ppm cloveoil group,
8.4±2.01 ppm for the 0.6 ppm cloveoil group, 7.7±1.99 ppm for the 0.8 ppm cloveoil
group, and 7.5±1.97 ppm for the 1 ppm cloveoil group. At 12 hours, the DO,
NH4+, and CO2 concentrations and respiratory
frequencies had decreased with increasing cloveoil concentrations. The
CO2 concentration at 12 hours was 15.4±2.95 ppm for the control
group, 14.7±2.59 ppm for the 0.2 ppm cloveoil group, 14.2±2.67 ppm for the 0.4 ppm
cloveoil group, 13.7±3.54 ppm for the 0.6 ppm cloveoil group, 12.9±2.44 ppm for
the 0.8 ppm cloveoil group, and 12.2±1.75 ppm for the 1 ppm cloveoil group. At all
other times (18, 24, 30, 36, 42, and 48 hours), the trends in the DO,
NH4+, and CO2 concentrations and the
respiratory frequencies for the control and clove-oil-administered groups were
similar to those at 6 and 12 hours.
Table 3
Dissolved oxygen concentrations during clove-oil-induced anesthesia in
the marine medaka, Oryzias dancena, in a simulated
transport experiment
Exposuretime (hours)
Dose
(mgL-1)*
Control
0.2
0.4
0.6
0.8
1.0
6
6.51±0.83a
6.65±0.79b
6.77±0.64c
6.85±0.71d
6.98±0.72e
7.41±0.79f
12
6.04±0.79a
6.16±0.51b
6.23±0.48c
6.37±0.54d
6.46±0.45e
6.58±0.66f
18
5.46±0.94a
5.55±0.88b
5.64±0.55c
5.77±0.57d
5.87±0.64e
5.99±0.89f
24
5.01±0.75a
5.12±0.43b
5.22±0.37c
5.31±0.66d
5.46±0.81e
5.58±0.75f
30
4.67±0.92a
4.78±0.52b
4.88±0.49c
4.97±0.43d
5.11±0.66e
5.22±0.71f
36
4.00±0.77a
4.11±0.86b
4.23±0.59c
4.32±0.61d
4.44±0.50e
4.59±0.62f
42
3.87±0.76a
3.99±0.44b
4.12±0.51c
4.25±0.65d
4.33±0.45e
4.47±0.56f
48
3.41±0.81a
3.52±0.52b
3.66±0.45c
3.74±0.50d
3.89±0.67e
3.97±0.40f
* Each value is the mean±standard deviation (n
= 60) of triplicate experiments. Values in the same column not
sharing common superscripts are significantly different among doses
(P<0.05).
Table 4
Respiratory frequencies (gill cover movements) during clove-oil-induced
anesthesia in the marine medaka, Oryzias dancena, in a
simulated transport experiment
Exposuretime (hours)
Dose
(mgL-1)*
Control
0.2
0.4
0.6
0.8
1.0
6
128±5.77a
125±6.91b
117±5.64c
105±4.13d
98±6.22e
91±5.93f
12
135±4.48a
130±4.11b
123±6.13c
117±6.44d
106±7.41e
98±4.66f
18
129±5.31a
125±4.38b
114±5.55c
107±4.77d
98±5.58e
93±6.38f
24
125±3.75a
121±5.43b
112±6.72c
101±6.98d
96±5.81e
88±4.96f
30
117±6.75a
108±6.88b
101±7.42c
97±7.39d
88±6.13e
77±6.88f
36
110±5.13a
101±8.86b
99±4.99c
92±7.06d
84±3.65e
75±7.13f
42
109±4.39a
100±6.54b
98±5.61c
85±6.51d
81±4.09e
72±6.88f
48
108±5.81a
98±4.22b
96±6.75c
84±7.01d
79±6.12e
67±5.43f
* Each value is the mean±standard deviation (n
= 60) of triplicate experiments. Values in the same column not
sharing common superscripts are significantly different among doses
(P<0.05).
Table 5
Ammonium concentrations during clove-oil-induced anesthesia in the marine
medaka, Oryzias dancena, in a simulated transport
experiment
Exposuretime (hours)
Dose
(mgL-1)*
Control
0.2
0.4
0.6
0.8
1.0
6
0.21±0.03a
0.17±0.02b
0.15±0.04c
0.14±0.05d
0.11±0.03e
0.07±0.01f
12
0.32±0.09a
0.27±0.05b
0.25±0.04c
0.23±0.03d
0.21±0.05e
0.20±0.04f
18
0.38±0.04a
0.35±0.04b
0.33±0.06c
0.32±0.03d
0.30±0.04e
0.28±0.04f
24
0.44±0.05a
0.42±0.07b
0.40±0.05c
0.37±0.03d
0.34±0.05e
0.31±0.08f
30
0.49±0.02a
0.46±0.04b
0.44±0.05c
0.43±0.04d
0.41±0.06e
0.38±0.07f
36
0.58±0.07a
0.55±0.07b
0.52±0.04c
0.50±0.06d
0.47±0.09e
0.43±0.05f
42
0.64±0.06a
0.61±0.05b
0.59±0.07c
0.56±0.03d
0.52±0.05e
0.50±0.07f
48
0.69±0.01a
0.66±0.05b
0.63±0.08c
0.60±0.09d
0.57±0.05e
0.54±0.08f
* Each value is the mean±standard deviation (n
= 60) of triplicate experiments. Values in the same column not
sharing common superscripts are significantly different among doses
(P<0.05).
Fig. 3
Carbon dioxide (CO2) concentrations during clove-oil-induced
anesthesia in the marine medaka, Oryzias dancena, in a
simulated transport experiment.
Each value is the mean±standard deviation (n = 60) of
triplicate experiments. Values in the same column not sharing common
superscripts are significantly different among doses
(P<0.05).
* Each value is the mean±standard deviation (n
= 60) of triplicate experiments. Values in the same column not
sharing common superscripts are significantly different among doses
(P<0.05).* Each value is the mean±standard deviation (n
= 60) of triplicate experiments. Values in the same column not
sharing common superscripts are significantly different among doses
(P<0.05).* Each value is the mean±standard deviation (n
= 60) of triplicate experiments. Values in the same column not
sharing common superscripts are significantly different among doses
(P<0.05).
Carbon dioxide (CO2) concentrations during clove-oil-induced
anesthesia in the marine medaka, Oryzias dancena, in a
simulated transport experiment.
Each value is the mean±standard deviation (n = 60) of
triplicate experiments. Values in the same column not sharing common
superscripts are significantly different among doses
(P<0.05).The results for the DO concentrations, respiratory frequencies, and
NH4+ and CO2 concentrations in the
lidocaine-HCl-administered groups are presented in Tables 6, 7, and 8 and Fig.
4, respectively. The DO concentrations and respiratory frequencies
decreased up to 48 hours in all experimental groups (P<0.05;
Tables 6 and 7, respectively), whereas the NH4+ and
CO2 concentrations increased up to 48 hours in all the experimental
groups (both P<0.05; Table
8, Fig. 4). At 6 hours, the DO,
NH4+, and CO2 concentrations and the
respiratory frequencies had all decreased with increasing lidocaine-HCl
concentrations (P<0.05). The CO2 concentration at 6
hours was 12.1±2.83 ppm for the control group, 11.4±3.57 ppm for the 20 ppm
lidocaine-HCl group, 9.7±2.39 ppm for the 40 ppm lidocaine-HCl group, 8.2±2.12 ppm
for the 60 ppm lidocaine-HCl group, 7.5±1.68 ppm for the 80 ppm lidocaine-HCl group,
and 7.1±1.84 ppm for the 100 ppm lidocaine-HCl group. At 12 hours, the DO,
NH4+, and CO2 concentrations and the
respiratory frequencies had all decreased with increasing lidocaine-HCl
concentrations. The CO2 concentration at 12 hours was 15.4±2.95 ppm for
the control group, 14.8±2.51 ppm for the 20 ppm lidocaine-HCl group, 14.2±2.15 ppm
for the 40 ppm lidocaine-HCl group, 13.4±3.64 ppm for the 60 ppm lidocaine-HCl
group, 12.6±2.11 ppm for the 80 ppm lidocaine-HCl group, and 12.0±1.15 ppm for the
100 ppm lidocaine-HCl group. At all other times (18, 24, 30, 36, 42, and 48 hours),
the trends in the DO, NH4+, and CO2 concentrations
and respiratory frequencies for the control and lidocaine-HCl-administered groups
were similar to those at 6 and 12 hours.
Table 6
Dissolved oxygen concentrations during lidocaine-HCl-induced anesthesia
in the marine medaka, Oryzias dancena, in a simulated
transport experiment
Exposuretime (hours)
Dose
(mgL-1)*
Control
20
40
60
80
100
6
6.51±0.83a
6.66±0.88b
6.76±0.74c
6.88±0.70d
6.97±0.52e
7.45±0.89f
12
6.04±0.79a
6.14±0.55b
6.24±0.88c
6.35±0.65d
6.41±0.87e
6.59±0.96f
18
5.46±0.94a
5.56±0.86b
5.67±0.95c
5.78±0.76d
5.85±0.91e
5.98±1.02f
24
5.01±0.75a
5.14±0.45b
5.23±0.57c
5.34±0.86d
5.45±0.90e
5.56±0.88f
30
4.67±0.92a
4.77±0.58b
4.89±0.79c
4.99±0.93d
5.13±0.98e
5.28±0.91f
36
4.00±0.77a
4.13±0.81b
4.25±0.69c
4.40±0.78d
4.45±1.05e
4.58±0.88f
42
3.87±0.76a
3.97±0.47b
4.15±0.81c
4.28±0.77d
4.37±1.01e
4.49±0.94f
48
3.41±0.81a
3.51±0.52b
3.67±0.45c
3.78±0.56d
3.91±0.91e
3.99±0.80f
* Each value is the mean±standard deviation (n
= 60) of triplicate experiments. Values in the same column not
sharing common superscripts are significantly different among doses
(P<0.05).
Table 7
Respiratory frequencies (gill cover movements) during
lidocaine-HCl-induced anesthesia in the marine medaka, Oryzias
dancena, in a simulated transport experiment
Exposuretime (hours)
Dose
(mgL-1)*
Control
20
40
60
80
100
6
127±5.57a
124±6.76b
116±5.64c
104±4.13d
98±7.25e
92±5.93f
12
134±4.67a
129±4.25b
121±6.13c
115±6.44d
106±8.14e
97±4.66f
18
127±5.77a
123±4.86b
112±5.55c
106±4.77d
98±6.76e
91±6.38f
24
124±3.16a
118±5.36b
109±6.72c
100±6.98d
96±6.11e
87±4.96f
30
116±6.19a
107±6.64b
100±7.42c
94±7.39d
88±5.12e
75±6.88f
36
109±5.76a
100±8.27b
98±4.99c
90±7.06d
85±6.78e
74±7.13f
42
105±4.09a
97±6.86b
96±5.61c
83±6.51d
80±7.12e
71±6.88f
48
100±5.14a
98±4.27b
94±6.75c
80±7.01d
78±8.20e
66±5.43f
* Each value is the mean±standard deviation (n
= 60) of triplicate experiments. Values in the same column not
sharing common superscripts are significantly different among doses
(P<0.05).
Table 8
Ammonium concentrations during lidocaine-HCl-induced anesthesia in the
marine medaka, Oryzias dancena, in a simulated transport
experiment
Exposuretime (hours)
Dose
(mgL-1)*
Control
20
40
60
80
100
6
0.21±0.03a
0.17±0.02b
0.15±0.04c
0.13±0.05d
0.11±0.03e
0.07±0.01f
12
0.32±0.09a
0.25±0.05b
0.24±0.04c
0.22±0.03d
0.20±0.05e
0.18±0.04f
18
0.38±0.04a
0.34±0.04b
0.32±0.06c
0.30±0.03d
0.28±0.04e
0.26±0.04f
24
0.44±0.05a
0.40±0.07b
0.38±0.05c
0.36±0.03d
0.33±0.05e
0.30±0.08f
30
0.49±0.02a
0.45±0.04b
0.43±0.05c
0.42±0.04d
0.40±0.06e
0.37±0.07f
36
0.58±0.07a
0.54±0.07b
0.51±0.04c
0.50±0.06d
0.47±0.09e
0.44±0.05f
42
0.64±0.06a
0.60±0.05b
0.57±0.07c
0.55±0.03d
0.52±0.05e
0.48±0.07f
48
0.69±0.01a
0.64±0.05b
0.62±0.08c
0.58±0.09d
0.55±0.05e
0.53±0.08f
* Each value is the mean±standard deviation (n
= 60) of triplicate experiments. Values in the same column not
sharing common superscripts are significantly different among doses
(P<0.05).
Fig. 4
Carbon dioxide (CO2) concentrations during
lidocaine-HCl-induced anesthesia in the marine medaka, Oryzias
dancena, in a simulated transport experiment.
Each value is the mean±standard deviation (n = 60) of
triplicate experiments. Values in the same column not sharing common
superscripts are significantly different among doses
(P<0.05).
* Each value is the mean±standard deviation (n
= 60) of triplicate experiments. Values in the same column not
sharing common superscripts are significantly different among doses
(P<0.05).* Each value is the mean±standard deviation (n
= 60) of triplicate experiments. Values in the same column not
sharing common superscripts are significantly different among doses
(P<0.05).* Each value is the mean±standard deviation (n
= 60) of triplicate experiments. Values in the same column not
sharing common superscripts are significantly different among doses
(P<0.05).
Carbon dioxide (CO2) concentrations during
lidocaine-HCl-induced anesthesia in the marine medaka, Oryzias
dancena, in a simulated transport experiment.
Each value is the mean±standard deviation (n = 60) of
triplicate experiments. Values in the same column not sharing common
superscripts are significantly different among doses
(P<0.05).
DISCUSSION
Study results indicate that the higher the concentration of anesthetic at each
salinity, the shorter the anesthesia time at each salinity. The patterns of cloveoil and lidocaine-HCl observed in the marine medaka are similar to previous studies
on other bony fishes such as the sockeye salmon, Oncorhynchus
nerka, (Woody et al., 2002) the rock
bream, Oplegnthus fasciatus (Park
et al., 2009), the greenling, Hexagrammos otakii (Park et al., 2003), and the winter flounder,
Pleuronectes americanus (Park
et al., 2004). The dose response of the marine medaka to cloveoil and
lidocaine-HCl presented a negative exponential curve, with increased doses resulting
in decreased time until the anesthesia stage A6.Optimum anesthetic concentrations are usually expected to induce anesthesia within 3
min and recovery within 10 min (Son et al.,
2001; Park et al., 2003). For this
study, it was decided that the optimum anesthesia concentration should be at about 1
min. Considering that the optimal anesthesia time is around 1 min, concentrations of
cloveoil for the marine medaka were 150 ppm at 0 ppt, 20 ppt, and 30 ppt, and 100
ppm at 10 ppt. The optimal anesthesia concentrations of lidocaine-HCl on the marine
medaka were 800 ppm and 700 ppm at 0 ppt and 10 ppt, respectively. At 10 ppt, the
optimum anesthetic concentration of cloveoil and lidocaine-HCl for the marine
medaka was similar to that found in a previous study on the marine medaka and water
temperature (Park et al., 2011). Park et al. (2011) also reported that the
optimum anesthetic concentration of both anesthetics at 26 ℃ was 100 ppm and 700
ppm, respectively.If the ratio of recovery time to anesthetic time is greater than 1, the recovery time
is longer than the anesthesia time. For the cloveoil, the ratio is less than 1 at
50 ppm, 100 ppm in 20 ppt, 30 ppt and 40 ppt. Other data were recorded greater than
1 and, at each water salinity, the ratio of recovery time to anesthesia time
increased as the anesthesia concentration was increased
(P<0.05). That is, anesthesia time was shortened as anesthesia
concentration increased, but recovery time increased relatively. On the contrary,
anesthesia time increased as anesthesia concentration was reduced, but recovery time
was shortened relatively (P<0.05). A similar result was reported
for the rock bream (Park et al., 2009) in
that the increment of cloveoil concentration corresponds to the increment of ratio
of recovery time to anesthesia time. For lidocaine-HCl, the ratio is less than 1 at
200 ppm in 30 ppt and 40 ppt. Other ratios of recovery time to anesthesia time are
greater than 1. This means that recovery time is longer than the anesthesia time for
lidocaine-HCl. No other specific regulation was found from this result.For specific details of this research, anesthesia time and recovery time were fastest
at 10 ppt. Anesthesia of fish is accomplished through the gills. High metabolism
causes rapid breathing. If metabolism is high, the anesthesia is absorbed faster
through the gills (Summerfelt & Smith,
1990). Thus, metabolism of the marine medaka at 10 ppt is expected to be
higher than at any other salinity. Results show that anesthetic time and recovery
time at 10 ppt are faster than other salinities for further confirmation,
comparative physiology research needs to be undertaken to determine these
details.The patterns of DO decline in the water of the control groups, the
clove-oil-administered groups, and the lidocaine-HCl-administered groups are
consistent with the trends reported in studies of Rhynchocypris
steindachneri, olive flounder, Paralichthys olivaceus,
and winter flounder, Pleuronectes americanus (Ko et al., 1995; Park et al.,
1998; Park et al., 2009). Based on
these results, we can assume that the high oxygen consumption during the early stage
of transportation is attributable to the high levels of stress induced by handling
or netting. The results of this study are similar to those of a transportation
experiment by Ferreira et al. (1984), in which
benzocaine-HCl was used as an anesthetic for the Java tilapia, Oreochromis
mossambicus. In general, both studies showed a reduction in fish
metabolism after the application of the anesthetic, which is an indication of
declining oxygen consumption. In this study, there seemed to be a positive
relationship between the concentrations of lidocaine-HCl and DO, insofar as the
group treated with the highest concentration of anesthetic exhibited the smallest
decline in DO (Ferreira et al., 1984). A
similarly designed experiment by Park et al.
(1998), with R. steindachneri as the test organism,
showed that the trends in DO and ventilation rates exhibited the same patterns for 2
h as were observed for 3 h in our study. Park et al.
(1998) used lower lidocaine-HCl concentrations (5, 10, and 20 ppm), but
at a lower temperature (18℃ compared with the 26℃ we used in this experiment), which
ultimately produced nearly identical trends. This is an important comparison,
because it indicates the wide-ranging effects of lidocaine-HCl over a broad spectrum
of temperatures.Guo et al. (1995) performed a transportation
experiment on the playfish, Xiphophorus maculatus (Günther),
treated with three different anesthetics: 2-phenoxyethanol (200 ppm), quinaldine
sulfate (10 ppm), and MS-222 (30 ppm). At 16 hours after the administration of the
anesthetic, the NH4+ concentration in the water of the
2-phenoxyethanol group was only 65% that of the control group, 20% that of the
quinaldine sulfate group, and relatively lower concentration compared with that of
the MS-222 group. The trends in ammonium concentrations exhibited by the five
experimental groups were consistent with the trends reported by Park et al. (1998, 2009) and Guo et al. (1995). Our
conclusions are in accord with those of Park et al. (1998, 2009), insofar as the
overall reduction in NH4+ excretion was directly related to
the anesthetic-induced decline in metabolism.Lidocaine-HCl induced the expected anesthetic effects for teleost fish in terms of
their increased sedation, which is associated with a reduced metabolic rate and
reduced oxygen consumption, together with reduced production of both
NH4+ and CO2 (McFaland, 1959; Park et al.,
1998, 2004, 2009). Currently, MS-222 remains the only fish anesthetic
approved by the FDA for the United States (Schnick
& Meyer, 1978). However, fish treated with MS-222 are not edible
until 21 days after its administration, which is the withdrawal period required for
traces of the chemical to disappear from the flesh of the fish (Carmichael & Tomasso, 1988). This clearly
raises operational issues because the fish cannot be harvested for three weeks.This study shows that cloveoil and lidocaine-HCl are effective techniques for
anesthetizing the marine medaka. Moreover, the relationship between anesthetic
effect and water salinity was examined. The two anesthetics used in this study meet
the requirements of an ideal anesthesia with 3 min anesthesia times and 5 min
recovery time. As mentioned by Park et al.
(2011), the anesthetic effect is significantly affected by the water
temperature and the cloveoil or lidocaine-HCl concentration, and decreases
proportionally as the cloveoil or lidocaine-HCl concentration or water temperature
increases. The results of Park et al. (2011)
suggest that the anesthetic effects of cloveoil are similar to those of
lidocaine-HCl. The results of our experiment suggest that cloveoil and
lidocaine-HCl both reduce the metabolic activity of the marine medaka,
Oryzias dancena, thus reducing its ammonium excretion and its
oxygen consumption. Both anesthetics are cost-effective, efficient, safe and
non-toxic to the fish and the user (Park et al.,
2003).Park et al. (2014) reported that the operculum
movement number increased under heat anesthesia and cold anesthesia by changing
temperature. With anaesthetization at either 38°C or 8°C, the whole-body cortisol
level was highest at 0 hour and decreased gradually until 6 hours, whereas the
whole-body glucose level was highest at 1 hour and decreased until 2 hours (Park et al., 2014). In conclusion, cloveoil
and lidocaine-HCl have been shown to be effective anesthetics, improving the
transportation of the marine medaka. Results from this study will contribute to safe
laboratory handling of the marine medaka, which are commonly required for use by
many research studies and experiments. The results of our study should be useful for
aquaculturists and transporters who require that minimal stress is imposed on fish
during transport. In this study, we were not analyzed change of physiological
response by cloveoil and lidocaine-HCl anesthesia. So, future investigations on the
marine medaka should focus on comparative analysis of physiological reactions by
salinity and anesthetics.
Fig. 1
Fig. 2
Fig. 3
Fig. 4