نوع مقاله : مقاله پژوهشی
نویسندگان
1 گروه بهداشت و بیماریهای آبزیان، دانشکده دامپزشکی، دانشگاه تهران، تهران، ایران.
2 مؤسسه تحقیقات علوم شیلاتی کشور، مرکز تحقیقات ذخایر آبزیان آبهای داخلی، گرگان، ایران.
3 گروه آبزی پروری، دانشکده شیلات، دانشگاه آکدنیز، آنتالیا، ترکیه.
چکیده
کلیدواژهها
Introduction
With the rapid increase in global population, aquaculture stands out as an important agricultural and food production sector to ensure the worldwide demand for fish consumption and food security. For this reason, aquaculture production and income from this sector are rising every year. Undoubtedly, the new technologies and beneficial outcomes of scientific studies have contributed to promoting the aquaculture sector.
It is equally beneficial for fish and fish producers that fish experience a minimum stress level during aquaculture activities. Fish are susceptible to mechanical injury and physiological stress during routine procedures in aquaculture, which may result in undesirable conditions, such as reduced growth rate and increased fish morbidity. For example, the transportation process frequently used in fish farming is stressful for fish and may cause various injuries, leading to the loss of their scales and mucus and increasing the outbreak of bacterial and fungal diseases (Zeppenfeld et al., 2014; Adah Sylvanus et al., 2022).
One solution to this problem is using sedatives in transportation water. These chemicals may lower oxidative stress and fish metabolism and improve the welfare of aquatic species (Toni et al., 2015; Aydın & Barbas, 2020; Ventura et al., 2020). Accordingly, using sedative agents in the aquaculture sector is essential for producers.
Various studies have been performed in recent years on using sedatives in aquaculture (Aydın & Barbas, 2020). Some studies approved using sedatives in fish transportation (Boaventura et al., 2020; Ventura et al., 2020). However, it was reported that anesthetic or sedative drugs used in farming procedures can cause stress at various levels and have undesirable effects on the physiology of fish (Zeppenfeld et al., 2014; Aydın & Barbas, 2020; Rahman et al., 2020). Aydın & Barbas, (2020) stated that while some drugs positively affect the blood biochemistry of fish, some medications, especially those of synthetics, have a negative effect. Furthermore, fish transport is a complex physiological process, and more information is needed on the physiological responses of fish during and after transport using sedative agents. Hence, it is crucial to investigate the detailed analysis of the side effects of sedative substances on fish.
For this purpose, some studies have been carried out on different types of sedatives synthetic drugs such as 2-phenoxyethanol (Shaluei et al., 2012), benzocaine (Boaventura et al., 2022), natural drugs, such as Lippia alba essential oil (EO) (Becker et al., 2012), Aloysia triphylla EO (Becker et al., 2012), and Ocimum basilicum EO (Ventura et al., 2020), and active compounds such as menthol (da Silva et al., 2016), citral (de Freitas Souza et al., 2018), and citronellal (Yousefi et al., 2019).
Common carp, Cyprinus carpio, is an important freshwater fish widely cultured around the world with a production amount of about 4.24 million tons (FAO 2019). It is known for its rapid growth, good adaptation to farming conditions, and low-cost feed. To date, only a few studies have been conducted to evaluate the impacts of transport with sedative drugs on this species (Taheri Mirghaed & Ghelichpour, 2019; Hoseini et al., 2022; Mirzargar et al., 2022).
In recent years, myrcene has been investigated for its sedative and anesthetic effects in fish (Taheri Mirghaed et al., 2016; Taheri Mirghaed et al., 2019). No studies have reported the common carp’s biochemical profile transported under sedation with myrcene. Thus, this study aimed to evaluate the effects of different concentrations of myrcene in transportation water on plasma biochemical characteristics, electrolytes, and immune parameters of common carp.
Material and Methods
Experimental protocol
This research used 126 common carp (45.3±1.65 g) placed in eighteen 55-L aquaria, each containing 7 fish. They were kept there for 14 days to get acclimatized and were fed twice a day with commercial carp food at a rate of 3% biomass. Then, one fish was selected from each tank and anesthetized with eugenol (100 mg/L), and its blood was taken from the caudal vein with a heparinized syringe. Finally, 12 samples were tested before transportation (BT). The remaining fish were placed in plastic bags containing 2 L of water and 4 L of pure oxygen (6 fish in each plastic).
Afterward, the plastic bags were divided into 5 groups, and 0 (CTL), 10 (10 M), 20 (20 M), 30 (30 M), and 50 (50 M) µL/L myrcene were added to either of the bags. The plastic lids were fastened and transported for 6 hours. After transportation, 4 fish were caught from each plastic bag, and their blood samples were taken. Fish were anesthetized with eugenol (100 mg/L), and their blood was collected from the caudal vein by heparin syringes. About 1 mL of blood was taken from each fish and centrifuged for plasma separation.
Plasma analysis
Sodium and potassium were measured with a flame photometer. The photometric method was used to measure calcium with a commercial kit (Pars Azmoun). Chloride was measured by Zischem kit according to the manufacturer’s instructions. Plasma total protein and albumin were determined by Pars Azmoun commercial kits, based on the Biuret and bromocresol green methods, respectively (Alishahi et al., 2014). Plasma alanine aminotransferase (ALT), aspartate aminotransferase (AST), and alkaline phosphatase (ALP) were measured using Pars Azmoun commercial kits based on kinetic methods (Tulaby Dezuly et al., 2019).
Plasma lysozyme activity was measured at 530 nm using Micrococcus luteus as the target. Every 0.001 decrease in sample absorbance per minute was considered one unit of lysozyme (Mohseni et al., 2021a). Plasma alternative complement (ACH50) activity was measured according to hemolytic activity against sheep erythrocytes (Jami et al., 2019). Plasma total immunoglobulin (Ig) was determined after precipitation with polyethylene glycol (Mohseni et al., 2021b).
Statistical analysis
The normal distribution of the data was checked by the Shapiro-Wilk test. Then, the data were analyzed by one-way ANOVA test. The treatment groups’ means were compared by Duncan’s test. SPSS software, version 22 was used to analyze the data. Significance was determined at the level of P<0.05. Data were presented as Mean±SD.
Results
Plasma total protein and albumin decreased significantly (P<0.001) after transportation in the CTL, 10 M, 20 M, and 30 M treatments (Figure 1). The most significant decrease in the plasma total protein and albumin levels was observed in the CTL, 10 M, and 20 M treatments. The plasma globulin after transportation remained unchanged in the CTL, 10 M, 30 M, and 50 M treatments but increased significantly (P<0.001) in the 20 M treatment (Figure 1).
Transportation caused a significant decrease (P<0.001) of plasma sodium in the CTL, 10 M, 20 M, and 30 M treatments, and the greatest reduction was observed in the CTL treatment (Figure 2). Plasma potassium increased significantly (P=0.006) in the CTL and 10 M treatments. Still, there was no significant change among the other treatments (Figure 2). Transportation caused a significant decrease (P<0.001) in the plasma chloride in all treatments. The greatest reduction was observed in the CTL, 10 M, and 30 M treatments (Figure 2). The plasma calcium increased significantly (P<0.001) in the CTL, 10 M, 30 M, and 50 M treatments (Figure 2).
The activity of ALT increased significantly (P<0.001) in the treatment groups of the CTL, 10 M, 30 M, and 50 M, and the highest activity was observed in the CTL, 30 M, and 50 M treatments (Figure 3). Plasma AST activity increased significantly (P<0.001) in all treatments after transportation. Still, the highest increase was seen in the CTL treatment (Figure 3). Plasma ALP activity increased significantly (P<0.001) in all treatments after transportation. The lowest increase was observed in the 20 M treatment and the highest in the 50 M treatment (Figure 3).
After transportation, plasma lysozyme decreased significantly (P<0.001) in the CTL, 10 M, 20 M, and 30 M treatments and increased in the 50 M (Figure 4). Plasma ACH50 decreased significantly (P<0.001) in all treatments after transportation. The lowest values were observed in the CTL and 50 M treatments, while the 30 M treatment had the highest activity (Figure 4). Transportation did not have a significant effect on the plasma total Ig levels (Figure 4).
Discussion
The positive or negative effects of sedatives in the transport water are not fully explored in aquaculture. It has been indicated that anesthetic or sedative type, concentration, and exposure time affect immune and stress-related responses in fish (Cao et al., 2019), characterized by changes in plasma biochemical (Ventura et al., 2020; Ventura et al., 2021), and gene expression (Cao et al., 2019; Zapata-Guerra et al., 2020) findings.
Therefore, this study examined the plasma biochemical profile of the common carp transported with different myrcene concentrations for 6-h medium-distance transportation. Blood protein reflects fish health, mainly liver and non-specific immunity, and our results suggest that myrcene in transportation water positively impacts the common carp’s health condition. According to the current findings, eugenol and O. basilicum EO did not affect blood protein, albumin, and globulin levels of Nile tilapia transported for 2 h (Ventura et al., 2020). Similarly, no significant changes were observed in total protein levels of fish transferred with 5-10 mg/L eugenol and benzocaine (Boaventura et al., 2022). It should be noted that research findings of studies can vary due to the fish species, sedative concentration, water temperature, and transport time (Bowker et al., 2015). For example, a long-duration transportation process suppresses the immune system and increases fish morbidity or mortality (Gomes et al., 2003).
Plasma electrolytes are essential for the normal physiological function of fish. Freshwater fish exhibit chloride loss during stress due to increased ventilation from the gills (Barton et al., 2003; Mirzargar et al., 2022). In this study, chloride levels in the transport treatments decreased significantly compared to BT. This finding has also been reported in different fish species, such as Stizostedion vitreum (Barton et al., 2003) and Labeo rohita (Biswal et al., 2021). The 20 M treatment chloride level was less influenced by transportation than the other treatments in the present study. Myrcene prevented hyperkalemia in the 20 M-50 M treatments, similar to Ventura et al., (2020), who reported no change in Nile tilapia plasma potassium values after transportation with eugenol, compared to not-transported fish. The results indicate that the myrcene concentration affects electrolyte concentrations. In the present study, myrcene (20 µL/L) was the most efficient concentration for mitigating osmotic disturbance after transporting common carp. Similar results were observed in tambaqui sedated with O. basilicum EO at 800 μL/L (Ventura et al., 2021). However, chloride levels exhibited significant elevation after 3-h transportation using thymol as a sedative (Mirzargar et al., 2022). This difference might be due to the hyperventilation and different physiological and pharmacodynamic effects of the sedative drugs on the fish.
ALT, AST, and ALP enzymes as markers of hepatic function have been frequently used to investigate tissue damage and the health status of fish (Yousefi et al., 2022). In this study, the 6-h transportation stress elevated these parameters. The present results are consistent with earlier studies showing the benefits of using Ocimum gratissimum EO (10 mg/L) (Boaventura et al., 2020) and 1,8-cineole (30 μg/L) (Liu et al., 2022) in transportation water on fish plasma enzymes. The highest level of AST in transported treatments in the current study may be related to AST participation in glucose production. In the 20 M treatment, AST and ALP values were closest to BT, whereas ALT values were similar. These results indicated that myrcene improved hepatic function and lowered the effect of liver damage in common carp exposed to the transportation process.
The present study found no difference in total Ig among treatments after the 6-h transportation process. Nevertheless, the transportation process led to a significant decrease in plasma ACH50 activities, and the highest reduction was found in the control and 50 M treatments compared to other treatments. This study determined that using myrcene at 20-30 µL/L concentrations in the transport water was effective in significantly improving lysozyme and ACH50 activities of common carp. Protein supplements are essential in fish non-specific immune responses involving opsonization, inflammation, and resistance to various stress conditions (Ghafarifarsani et al., 2021). Therefore, stimulating immune functions may increase fish resistance against transport stress and diseases. In the current study, adding myrcene (20-30 µL/L) to the transport water positively contributed to the immune responses of common carp. In line with our results, in a recent study, eugenol (20 mg/L) and MS-22 (100 mg/L) were found to activate immune gene expression in transported Carassius auratus (Cao et al., 2019). This improvement may be attributed to the sedative effect of sedative drugs during the transport period and its direct effect on the immune system. These results are inconsistent with another study in that there was no significant difference in lysozyme levels of Pelteobagrus fulvidraco between the MS-222 treatment and the control (Liu et al., 2022).
In conclusion, compared with CTL, myrcene at 20 µL/L concentration significantly improved the biochemical (globulin), hepatic enzyme activity (ALT, AST, and ALP), plasma electrolytes (sodium, calcium, potassium, and chloride), and immune (lysozyme and ACH50) parameters. Thus, myrcene (20 mg/L) can provide greater protection against transport stress for common carp.
Ethical Considerations
Compliance with ethical guidelines
All parts of the study were conducted under a protocol approved by the Committee of Ethics of the Faculty of Sciences of the University of Tehran (No.: 357; 8 November 2000).
Funding
This study has been supported by the Center for International Scientific Studies and Collaboration (CISSC), Ministry of Science Research and Technology.
Authors' contributions
Conceptualization and supervision: Hoseinali Ebrahimzadeh Mousavi, Ali Taheri Mirghaed and Seyyed Morteza Hoseini; Methodology: Behrouz Gharavi; Visualization: Melika Ghelichpour; Investigation: Behrouz Gharavi and Melika Ghelichpour; Data curation: Seyyed Morteza Hoseini; Formal analysis: Hoseinali Ebrahimzadeh Mousavi, Seyyed Morteza Hoseini, Melika Ghelichpour and Abbasali Aghaei Moghaddam; Writing - original draft: Seyyed Morteza Hoseini, Baki Aydın and Seyyed Morteza Hoseini; Review & editing: Seyyed Morteza Hoseini and Baki Aydın.
Conflict of interest
The authors declared no conflict of interest.
Acknowledgments
The authors thanks staffs of University of Tehran and Inland Waters Aquatics Resources Research Center (Gorgan for their supports.
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