E-ISSN 2983-757X
 

Research Article
Online Published: 31 Aug 2023


Ulkhaq, Azizah, Apriliani, Tjahjaningsih, Abdillah: Clinicopathological and hematological profile of silver rasbora (Rasbora argyrotaenia) after experimentally infection with Aeromonas hydrophila

ABSTRACT

Aim:

The study aims to analyze clinicopathological changes and hematology profiles for early detection in silver rasbora infected by Aeromonas hydrophila.

Methods:

This study was conducted in January–February 2022. The treatment used in this study was experimental infection with A. hydrophila intramuscularly in silver rasbora using several concentrations, including 104 (P1), 106 (P2), 108 (P3), 1010 (P4) CFUml−1, and negative control (P0) (injected with normal saline) and reared for 2 days post infection. The research data focused on histopathological alteration in the liver and kidney and the hematological profile of infected fish. The mortality data and histopathology organ were analyzed using a one-way analysis of variance. Furthermore, if a significant value was detected, further tests would be carried out using the Duncan multiple range test and Mann-Whitney test, respectively. Other parameters, including hematological profile and clinical signs, were analyzed descriptively.

Results:

Infected silver rasbora (R. argyrotaenia) showed clinical signs, consisting of behavioral changes, external lesions, a hematological profile, and histopathological changes, in the kidney and liver. An increase in the density of A. hydrophila infected in silver rasbora caused severe changes in the clinicopathological characteristics of liver and kidney cells, consisting of degeneration and necrosis. The result presented significant hematology changes, including an increase in neutrophil and monocyte percentages. In contrast, decreasing total erythrocyte, hemoglobin level, total leucocyte, and lymphocyte percentages were observed.

Conclusion:

The silver rasbora infected by 1010 CFUml−1 of A. hydrophila exhibited the lowest survival rate, significant changes in hematology profiles, and severe histological damage.

Introduction

Silver rasbora (Rasbora argyrotaenia Bleeker, 1849) is one of the freshwater consumption fish from the Cyprinidae family with highly economical values. The demand for this fish has enormously increased, reaching 80% annually [1]. A bacterial disease that frequently infected Cyprinid fish was motile Aeromonads septicaemia (MAS) caused by Aeromonas hydrophila [2]. Aeromonas hydrophila infection caused high economic losses in fish culture and high fish mortality until 100% in several days [3], including in several cultured fishes in India [4], China [5], and ornamental fish industry in Malaysia [6]. Early detection is needed to confirm fish infected with A. hydrophila, such as the clinical symptoms it causes.
Fish infected with A. hydrophila present several clinical signs [7], including tail rot, hemorrhage in the fin and skin, septicemia, fin erosion, depigmentation in the skin, and exophthalmia [8]. Internally, infected fish show deposition of blood in the abdominal cavity; edema in the swim bladder and renal; and hemorrhage in the liver, renal, and lymph [9]. In addition, some can be detected from histopathology in liver and renal tissues including hemorrhage, atrophy, degeneration, and necrosis [10]. It is caused by extracellular products/toxins secreted by A. hydrophila, such as hemolysin, aerolysin, protease, and lecithinase enzymes [11]. This toxin could disrupt the cell membrane and inactivate the erythrocyte, which was assisted by other enzymes [12].
Kidney and liver tissue could be used as indicators to demonstrate the tissue changes caused by A. hydrophila toxins through histopathology examination. The liver is a metabolism organ that could be a detoxification organ, and the renal is a hemopoetic organ in fish. Therefore, this organ was targeted for A. hydrophila infection [13]. Furthermore, hematology profiles can be used as indicators of infected fish with A. hydrophila [14]. Previous studies reported that experimental infection of silver rasbora with Streptococcus agalactiae affected the hematology profile [15] and pathological changes [16]. Limited information about bacterial infection diseases in silver rasbora mainly caused by A. hydrophila encourages this study to analyze clinicopathological changes and hematology profiles in silver rasbora infected by A. hydrophila. The data obtained were used for the early detection of MAS disease in silver rasbora.

Materials and Methods

Ethical approval

The research was conducted and approved by the examiner committee of the Fisheries and Marine Faculty, Universitas Airlangga (Letter of Assignment from Dean of Fisheries and Marine Faculty, Universitas Airlangga, 53/UN3.1.16/KP/2022). The fish were well-cared for throughout the study. Furthermore, feeding methods and water quality monitoring were done in accordance with Indonesian National Standard (SNI) 7733:2018.

Study period and location

This study was conducted in January–February 2022 in the Teaching Farm, School of Health and Life Sciences, Universitas Airlangga, Indonesia.

Animals

Four hundred silver rasbora (R. argyrotaenia) (6 ± 0.1 cm and 3.6 ± 0.2 gm) from local farmers were immersed in 30 ppm NaCl solution for 5 min and acclimatized for 7 days.

Bacterial preparation

Aeromonas hydrophila was cultured in a selective medium (M-Aeromonas selective medium) (Himedia, India) and biochemically tested, including Gram staining, catalase test, oxidase test, motility test, and oxidative/fermentative test, to confirm the pure isolate bacteria referred to Barrow and Feltham [17]. Aeromonas hydrophila was diluted in NaCl 0.9% solution until the bacterial densities desired were 1010 CFU ml−1 based on McFarland standard number 4 (0.1 × 1010 CFU ml−1), and diluted according to the treatment.

Experimental fish and design

This study was conducted using a complete randomized design with five treatments in quadruplicate. The treatments were an intramuscular injection of 0.1 ml A. hydrophila with densities 104 CFUml−1 (P1), 106 CFUml−1 (P2), 108 CFUml−1 (P3), and 1010 CFUml−1 (P4), respectively, and NaCl 0.9% solution for the negative control (P0). Post infection with A. hydrophila, silver rasbora was reared in a glass aquarium (40 × 30 × 20 cm) with a water volume of 200 l (densities 1 tail l−1) and aerated using an air blower for 48 h (Resun LP 100). During the rearing period, fish were dietary with commercial feed (30% protein content) twice daily, with ad satiation methods. Water quality parameters (temperature, pH, dissolved oxygen, and ammonia) were maintained optimally with syphoning and 50% water replacement daily.

Clinicopathological observation

Fish were maintained for 28 h post-infection (hpi) until the clinicopathological signs included behavioral changes, external lesions, and histopathology changes after infection. The organs for histopathology observation were collected from the liver and kidney and taken at different periods consisting of 3 (P4), 9 (P3), 20 (P2), and 28 hpi (P1 and P0). The sample organs were obtained in sterile glass bottles, fixed in 10% neutral buffered formalin, and processed with a standard histological method based on Slaoui and Fiette [18].

Blood sampling

Blood sampling was conducted during similar periods with histopathology preparation. Fish blood was taken after being stunned with ice from artery caudals with a 1 ml spuit (Terumo, Japan) that was already given with an anticoagulant (Na-citrate 3%). Hematological observation consists of the erythrocyte; leucocytes; hemoglobin and percentages of neutrophils, monocytes, and lymphocytes was calculated based on Witeska et al. [19].

Data analysis

Data on survival rate (SR) (percentage of fish alive from a total of fish used) [20] and histopathology organ were analyzed using one-way analysis of variance (p < 0.05). Furthermore, if a significant value was detected, further tests would be carried out using Duncan multiple range test and Mann-Whitney test (p < 0.05), respectively. The clinicopathological alteration from infected fish consisting of external findings and hematological parameters was analyzed descriptively and compared with a normal value from the literature.

Result

Survival rate

The SR (Fig. 1) in P0 (negative control) shows the highest value (100%) and the lowest (10%) in P4 (infection of 1010 CFUml−1 A. hydrophila) compared with other treatments. In the treatment of P1 (infection of 104 CFUml−1 A. hydrophila) and P2 ((infection of 106 CFUml−1 A. hydrophila) were no significant differences. However, all treatments showed statistically different from the control (p < 0.05).

Gross clinical sign

Infected fish exhibit passive and irregular swimming (crashing at the bottom and floating on the surface), as well as congregating around aeration. External lesions (Fig. 2) show hemorrhage in the abdomen (Fig. 2A), operculum (Fig. 2C), and anus (Fig. 2D and F), scaling (Fig. 2B), and skin ulceration (Fig. 2E).

Histopathological alteration

Several clinical abnormalities, including lipid degradation and necrosis, were discovered in the kidney (Fig. 3) and liver (Fig. 4). The percentage of every cell damaged in internal organs was highest at P4 (1010 CFUml−1) and lowest at P0 (negative control), as shown in Table 1. The Mann-Whitney test revealed that the normal cell at P0 (negative control) differed significantly from the other treatments. Nevertheless, the total number of damaged cells was statistically different between treatments, with the largest in P4 (1010 CFUml−1). The results demonstrated a linear correlation between bacterial density and cell damage in the fish liver and kidney.
Figure 1.
The SR in silver rasbora after being infected with A. hydrophila at 28 hpi. P1 (infection of A. hydrophila 104 CFUml−1), C=P2 (infection of A. hydrophila 106 CFUml−1), D=P3 (infection of A. hydrophila 108 CFUml−1), and E=P4 (infection of A. hydrophila 1010 CFUml−1).
Figure 2.
Clinical signs from infected fish with A. hydrophila. A=ventral hemorrhage, B=scaling, C=hemorrhage in abdomen and operculum, D=hemorrhage in anal, E=ulceration, and F=hemorrhage in abdomen.
Figure 3.
Histopathological section of kidney with HE staining. (1) P0 (negative control), (2) P1 (infection of A. hydrophila 104 CFU ml−1), (3) P2 (106 CFU ml−1), (4) P3 (108 CFU ml−1), and (5) P4 (1010 CFU ml−1). T=Tubule, D=Degeneration, N=Necrosis.
Figure 4.
Histopathological section of liver with HE staining. (1) P0 (negative control), (2) P1 (infection of A. hydrophila 104 CFU ml−1), (3) P2 (106 CFU ml−1), (4) P3 (108 CFU ml−1), and (5) P4 (1010 CFU ml−1). H=Hepatocyte, N=Necrosis, D=Degeneration.

Hematological profile

The hematological profile (Table 2) displayed the number of erythrocytes, leucocytes, and hemoglobin levels declined from P4 (infection of A. hydrophila 1010 CFUml−1) to P0 (negative control). Total erythrocyte and leucocyte; hemoglobin levels from infected fish were lower than the normal range. In contrast, the percentage of neutrophils, monocytes, and lymphocytes rose from P0 (negative control) to P4 (infection with 1010 A. hydrophila CFUml−1). The percentage of neutrophils and lymphocytes was greater than the optimum range.

Discussion

Aeromonas hydrophila is a Gram-negative, rod-shaped bacteria found in various natural aquatic environments. The bacterium is primarily harmful to poikilothermy animals especially fish, turtles, snakes, and amphibians [21]. Several regions reported that A. hydrophila as a primary pathogen caused significant mortality in freshwater fish farming including in Nile tilapia (Oreochromis niloticus) in Egypt [22]; channel catfish (Ictalurus punctatus) in the United States [23], and freshwater cultured Murray cod (Maccullochella peelii) from Shanghai, China [24]. Our finding demonstrated that the mortality of silver rasbora was increasing linearly with bacterial density. The highest value (100%) presented in P0 (negative control), whereas the lowest (10%) was at P4 (infection of A. hydrophila 1010 CFUml−1). It was caused by the high amounts of virulence factors (enterotoxin, adhesins, aerolysin, cholinesterase, hemolysin, hemagglutinin, and protease) that were lethal to fish [25]. Zhao et al. [26] claimed that A. hydrophila is highly virulent, especially when present in large quantities or concentrations. It also indicates that A. hydrophila was the primary bacterial pathogen for many fish and aquatic organisms, causing high mortality and economic losses, and representing a risk to public health and environmental safety [27].
Table 1.
Average percentage of histology alteration in organ of silver rasbora during A. hydrophila infection.
Treatment Kidney Liver
Normal Degeneration Necrosis Normal Degeneration Necrosis
P0 92 ± 2 1a 6 ± 1.8b 2 ± 1.1c 93 ± 0.9a 5 ± 0.8b 2 ± 0.9c
P1 65 ± 6 1a 21 ± 5.2b 14 ± 3.5b 68 ± 10.5a 22 ± 8.3b 10 ± 3.1b
P2 39 ± 7 3a 33 ± 6.2a 28 ± 12a 31 ± 10.6a 40 ± 11.9a 29 ± 9.9a
P3 25 ± 7 9b 30 ± 7.4b 45 ± 3.1a 20 ± 4.9b 46 ± 8.5a 34 ± 10.4a
P4 13 ± 3 1b 37 ± 10.7a 50 ± 9.5a 8 ± 2.1c 21 ± 4.2b 71 ± 5.9a
P0: negative control, P1: A. hydrophila 104 CFU ml−1, P2: 106 CFU ml−1, P3: 108 CFU ml−1, P4: 1010 CFU ml−1. Average ± standard deviation.
a,b,cShowing significancy of the treatment (p < 0.05).
Table 2.
Hematology profile of silver rasbora experimentally infected with A. hydrophila. (average ± standard deviation).
Parameters Treatment Normal range
P0 P1 P2 P3 P4
Erythrocyte (×104 cell ml−1) 22.54 ± 3.11 16.26 ± 2.65 10.68 ± 2.87 8.95 ± 1.97 4.52 ± 1.65 20.80 ± 3.6
Leucocyte (×104 cell ml−1) 6.29 ± 1.43 5.48 ± 2.95 5.40 ± 1.76 5.35 ± 0.89 5.16 ± 0.95 6.11 ± 3.5
Hemoglobin (gm%) 5.05 ± 0.87 5.2 ± 2.41 4.75 ± 1.83 3.95 ± 0.54 3.6 ± 1.32 5 ± 2.06
Neutrophil (%) 36.5 ± 1.0 39 ± 1.5 40 ± 1.0 40.5 ± 2.0 41.5 ± 1.5 33.62 ± 3.5
Lymphocyte (%) 33.5 ± 0.5 31 ± 1.5 31 ± 2.0 30.5 ± 2.0 29 ± 1.0 31.4 ± 3.26
Monocyte (%) 26 ± 1.5 28 ± 1.5 29 ± 3.0 29.5 ± 2.5 33 ± 3.0 25.12 ± 6.1
(P0): negative control, (P1): A. hydrophila 104 CFU ml−1, (P2): 106 CFU ml−1, (P3): 108 CFU ml−1, (P4): 1010 CFU ml−1.
External clinical signs displayed passive and abnormal swimming and hemorrhage in the fin and skin. Another study also reported similar results in several aquatic species including red hybrid tilapia (O. niloticus × Oreochromis mossambicus) [28]; Chinese soft-shelled turtle (Trionyx sinensis) [29] and Siberian sturgeon (Acipenser baerii) [30]. Hemolysin activity could lysis the red blood cells and cause hemorrhage in the skin and fin of infected fish [31]. Furthermore, lytic erythrocytes release many nutrients and ions, which can promote bacterial growth. Erythrocytolysin reduces the number of erythrocytes and causes oxygen deficiency, leading to organism dysfunction and even death [32].
In severe cases, histological lesions in the kidney (Fig. 3) and liver (Fig. 4) revealed numerous cell damage, such as degeneration and necrosis. Vacuoles or rounded empty areas containing lipid globules indicated cell degeneration; thus, the nucleus shrank and was pushed to the edge [33]. It is caused by cytolytic enterotoxin generated by A. hydrophila, which reduces hepatocyte ability to effectively metabolize lipids, resulting in lipid deposits and injury to renal tissue as a hematopoietic organ [34]. Furthermore, Ahangarzadeh et al. [32] revealed that not only do A. hydrophila hemolysin toxins have hemolysis activity, but they also have cytolytic action which causes cell damage in infected fish.
Necrosis is irreversible cell destruction in tissue caused by pathogen toxins [35]. The previous study also found similar findings in gold fish (Carassius auratus) [36]; stripped catfish (Pangasius hypophthalmus) [37], and Chinese sucker (Myxocyprinus asiaticus) [38]. It is related to several toxins and enzymes secreted by A. hydrophila and diffused to the cell including serine proteases, elastase, and lipase [26]. Furthermore, two enzymes (proteases and lecithinase) may be the primary enzymes responsible for cell necrosis [39]. Long-term toxicity exposure leads to more severe cell and tissue damage [40].
Hematology profiles, such as total erythrocyte, leucocyte, and hemoglobin levels, can indicate disease infection in fish [14]. The average total erythrocytes count from the Cyprinid range is 20.80 ± 3.6 × 104 cellml−1 [41]. All treatments revealed a decrease in total erythrocytes after A. hydrophila infection. This bacterium is thought to release various toxins, including aerolysin and hemolysin. Aerolisin toxin can secrete monomers, be influenced by proteolytic modifications, and release propeptides. It is activated after attaching to receptors on the cell surface and causing cellular reactions such as erythrocyte vacuolization [42]. Furthermore, aerolysin is a primary virulent factor secreted by A. hydrophila that can bind to specific gly-cophosphatidylinositol-anchored proteins on the surface of erythrocytes and cause significant damage to fish erythrocytes by forming pores in the cell membrane, then exhibiting strong hemolytic activity and triggering deep wound infection [31]. Hemoglobin levels were lower in all treatments post A. hydrophila infection compared to the normal range (5 ± 2.06 gm%) [41]. It has also been caused by a decrease in the total number of erythrocytes, which has a significant positive relationship with hemoglobin levels [43]. Several previous study also revealed the similar finding, including in red crucian carp (C. auratus red var) [31]; snakehead murrel (Channa striata) [44]; and zebrafish (Danio rerio) [45] after infection with A. hydrophila.
After infection with A. hydrophila, the number of leucocyte demonstrated a decreasing value in all treatments compared with the average value in Cyprinid fish (6.11 ± 3.5 ×104 cell ml−1) [41]. It implied that leucocyte cells had moved to the tissue. Leukocyte cells were found in the blood vessels of the fish. When there is inflammation in the body’s tissues, leukocyte cells move to the inflamed tissue by penetrating the capillary walls. They participate in intracellular and extracellular systems that produce antibacterial compounds in response to infections [46].
Neutrophil is a type of leucocyte cell that rapidly migrates from a blood artery to the infected cell and contains vacuole and lysozyme to inactivate the pathogen. Neutrophils can cause significant collateral damage while destroying pathogenic germs [47]. The percentage of neutrophils in experimental fish after being infected by A. hydrophila show increased to the peak in the P4 treatment (injection of 1010 CFUml−1 A. hydrophila), which is almost 42%, higher than the normal value (33.62% ± 3.5%) [48]. This condition indicates that neutrophil cells were stimulated to eliminate the infection of A. hydrophila in silver rasbora. When infected, they rapidly recruit from tissues such as the head kidney, eventually accounting for up to 50% of total blood leukocytes. Neutrophils contribute significantly to antimicrobial defenses via mechanisms such as respiratory burst, phagocytosis, and the production of neutrophil extracellular traps and other toxic components. Neutrophils have unique granules that store bactericidal chemicals that kill microorganisms intracellularly or extracellularly via exocytosis [49]. Furthermore, Abarike et al. [50] stated that neutrophils are thought to be important in controlling and neutralizing infection at wound sites, as well as cleaning debris. They are also likely to have other immunomodulatory effects that contribute directly to regeneration processes.
The greatest monocyte percentage found in the P4 treatment (injection of 1010 CFUml−1 A. hydrophila) was about 33% more than expected (25.12% ± 6.1%) [48]. It showed that the immune system was eliminating the pathogen. Monocytes have been demonstrated to respond to inflammatory chemokines by migrating to the site of inflammation and exerting antimicrobial defenses. Monocytes migrate to tissues, where they differentiate into macrophages and are regulated by chemokines (e.g., CCL1 and CXCL12) [49]. Several roles played by macrophages during pathogen infection include phagocytosis, tryptophan degradation, respiratory burst, and nitric oxide responses [51]. After infection with A. hydrophila, silver rasbora showed a lower lymphocyte percentage compared with normal conditions (31.4% ± 3.26%) [48]. It was believed that lymphocyte cells move to tissues to eliminate pathogens. Lymphocytes stimulate innate immunological and regulatory functions, which help initiate and resolve acute inflammation. These cells were concentrated in the mucosal tissues of the intestine and gills demonstrating cytotoxic activity [49]. Fish lymphocytes are divided into T cells and B cells that produce three types of immunoglobulins (IgM, IgT, and IgD) to provide cellular immunity [52]. Other studies reported similar result in ornamental koi carp (Cyprinus carpio) [53]; golden mahseer (Tor putitora) [54]; and C. carpio var. Communis [55].

Conclusion

Infection with A. hydrophila caused many clinicopathological alterations in silver rasbora (R. argyrotaenia), including behavioral changes, external lesions, and histological changes in the kidney and liver (cell degeneration and necrosis). The hematological profile revealed an increase in neutrophil and monocyte percentages while decreasing erythrocyte, hemoglobin level, leucocyte, and lymphocyte percentages. Silver rasbora infected with 1010 CFUml−1 of A. hydrophila had the highest mortality rate, significant changes in hematological profiles, and severe histolopathological alterations. Further study was needed to determine whether herbal medicine might be used to prevent A. hydrophila infection in silver rasbora.

Acknowledgment

The authors would like to thank the support of the Teaching Farm, School of Health and Life Sciences Universitas Airlangga for all equipment. The authors also thank the anonymous reviewer for their valuable comments to revise the paper.

References

1. Anggararatri Y, Muslih M, Rukayah S, Lestari W. Study of population dynamics silver rasbora (Rasbora argyrotaenia Bleeker, 1849) in PB. Soedirman Reservoir, Banjarnegara. Genbinesia 2023; 2(2):81–92.
2. Semwal A, Kumar A, Kumar N. A review on pathogenicity of Aeromonas hydrophila and their mitigation through medicinal herbs in aquaculture. Heliyon [Internet] 2023; 9(3):e14088; doi: 10.1016/j.heliyon.2023.e14088
3. Nhinh DT, Le DV, Van KV, Huong Giang NT, Dang LT, Hoai TD. Prevalence, virulence gene distribution, and alarming the multidrug resistance of Aeromonas hydrophila associated with disease outbreaks in freshwater aquaculture. Antibiotics 2021; 10(5):532.
4. Nayak SK. Current prospects and challenges in fish vaccine development in India with special reference to Aeromonas hydrophila vaccine. Fish Shellfish Immunol [Internet] 2020; 100:283–99; doi: 10.1016/j.fsi.2020.01.064
5. Zhu W, Zhou S, Chu W. Comparative proteomic analysis of sensitive and multi-drug resistant Aeromonas hydrophila isolated from diseased fish. Microb Pathog [Internet] 2020; 139:103930; doi: 10.1016/j.micpath.2019.103930
6. Anjur N, Sabran SF, Daud HM, Othman NZ. An update on the ornamental fish industry in Malaysia: Aeromonas hydrophila-associated disease and its treatment control. Vet World 2021; 14(5):1143–52.
7. Khalil F, Emeash H. Behavior and stereotypies of Nile Tilapia (Oreochromis niloticus) in response to experimental infection with Aeromonas hydrophila. Aquat Sci Eng 2018; 33(4):124–30.
8. Pauzi NA, Mohamad N, Azzam-Sayuti M, Yasin ISM, Saad MZ, Nasruddin NS, et al. Antibiotic susceptibility and pathogenicity of Aeromonas hydrophila isolated from red hybrid tilapia (Oreochromis niloticus×Oreochromis mossambicus) in Malaysia. Vet World 2020; 13:2166–71.
9. Tartor YH, EL-Naenaeey ESY, Abdallah HM, Samir M, Yassen MM, Abdelwahab AM. Virulotyping and genetic diversity of Aeromonas hydrophila isolated from Nile tilapia (Oreochromis niloticus) in aquaculture farms in Egypt. Aquaculture [Internet] 2021; 541:736781; doi: 10.1016/j.aquaculture.2021.736781
10. Alavinezhad SS, Kazempoor R, Ghorbanzadeh A, Gharekhani A. Isolation of Aeromonas hydrophila and evaluation of its pathological effects on Koi fish (Cyprinus carpio). Iran J Med Microbiol 2021; 15(4):465–76.
11. Sarkar P, Issac PK, Raju SV, Elumalai P, Arshad A, Arockiaraj J. Pathogenic bacterial toxins and virulence influences in cultivable fish. Aquac Res 2021; 52(6):2361–76.
12. Avila-Calderón ED, Otero-Olarra JE, Flores-Romo L, Peralta H, Aguilera-Arreola MG, Morales-García MR, et al. The outer membrane vesicles of Aeromonas hydrophilaATCC®7966TM: a proteomic analysis and effect on host cells. Front Microbiol 2018; 9:1–14.
13. Pal S, Roy D, Ray SD, Homechaudhuri S. Aeromonas hydrophila induced mitochondrial dysfunction and apoptosis in liver and spleen of Labeo rohita mediated by calcium and reactive oxygen species. Turk J Fish Aquat Sci 2020; 20(4):255–66.
14. Fazio F. Fish hematology analysis as an important tool of aquaculture: a review. Aquaculture [Internet] 2019; 500:237–42; doi: 10.1016/j.aquaculture.2018.10.030
15. Nugrahani WA, Kusdarwati R, Ulkhaq MF. Experimental infection of Streptocccus agalactiae in silver rasbora (Rasbora argyrotaenia): effect to hematological profile from infected fish. IOP Conf Ser Earth Environ Sci 2021; 718(1):8–13.
16. Rahayu NN, Hayuningtyas C, Abidin IS, Bahtiar SA, Kusdarwati R, Ulkhaq MF. Experimental streptococcosis infection in silver rasbora (Rasbora argyrotaenia): a clinicopathological findings. In Proceedings of The Hokkaido Indonesian Student Association Scientific Meeting, 2022, pp 34–8.
17. Barrow GI, Feltham RK. Cowan and Steel’s manual for the identification of medical bacteria. 3rd edition, Cambridge University Press, Cambridge, UK, 1999.
18. Slaoui M, Fiette L. Histopathology procedures: from tissue sampling to histopathological evaluation. Methods Mol Biol 2011; 691:69–82.
19. Witeska M, Kondera E, Ługowska K, Bojarski B. Hematological methods in fish—not only for beginners. Aquaculture 2022; 547:1–17.
20. Arianto SR, Syah FA, Sari LA, Nafisyah AL, Arsad S, Musa N. Analyze the toxicities of benzalkonium chloride as a COVID-19 disinfectant in physiological goldfish (Carassius auratus). Vet World 2023; 16:1401–7.
21. Liu J, Gao S, Dong Y, Lu C, Liu Y. Isolation and characterization of bacteriophages against virulent Aeromonas hydrophila. BMC Microbiol 2020; 20(1):1–13.
22. Abdel-Latif HMR, Abdel-Tawwab M, Khafaga AF, Dawood MAO. Dietary oregano essential oil improved the growth performance via enhancing the intestinal morphometry and hepato-renal functions of common carp (Cyprinus carpio L.) fingerlings. Aquaculture [Internet] 2020; 526:735432; doi: 10.1016/j.aquaculture.2020.735432
23. Zhang D, Xu DH, Shoemaker C. Experimental induction of motile Aeromonas septicemia in channel catfish (Ictalurus punctatus) by waterborne challenge with virulent Aeromonas hydrophila. Aquac Rep [Internet] 2016; 3:18–23; doi: 10.1016/j.aqrep.2015.11.003
24. Gai C, Ye W, Lu L, Li Y, Yang X, Cao H. Aeromonas hydrophila: a causative agent for tail rot disease in freshwater cultured Murray cod Maccullochella peelii. Isr J Aquac 2016; 68:1–8.
25. Pattanayak S, Priyadarsini S, Paul A, Kumar PR, Sahoo PK. Diversity of virulence-associated genes in pathogenic Aeromonas hydrophila isolates and their in vivo modulation at varied water temperatures. Microb Pathog [Internet] 2020; 147:104424; doi: 10.1016/j.micpath.2020.104424
26. Zhao XL, Wu G, Chen H, Li L, Kong XH. Analysis of virulence and immunogenic factors in Aeromonas hydrophila: towards the development of live vaccines. J Fish Dis 2020; 43(7):747–55.
27. Abdul Kari Z, Wee W, Mohamad Sukri SA, Che Harun H, Hanif Reduan MF, Irwan Khoo M, et al. Role of phytobiotics in relieving the impacts of Aeromonas hydrophila infection on aquatic animals: a mini-review. Front Vet Sci 2022; 9(5):1023784.
28. Pauzi NA, Mohamad N, Azzam-Sayuti M, Yasin ISM, Saad MZ, Nasruddin NS, et al. Antibiotic susceptibility and pathogenicity of Aeromonas hydrophila isolated from red hybrid tilapia (Oreochromis niloticus×Oreochromis mossambicus) in Malaysia. Vet World 2020; 13(10):2166–71.
29. Lv Z, Hu Y, Tan J, Wang X, Liu X, Zeng C. Comparative transcriptome analysis reveals the molecular immunopathogenesis of chinese soft-shelled turtle (Trionyx sinensis) infected with Aeromonas hydrophila. Biology (Basel) 2021; 10(11):1218.
30. Bakiyev S, Smekenov I, Zharkova I, Kobegenova S, Sergaliyev N, Absatirov G, et al. Isolation, identification, and characterization of pathogenic Aeromonas hydrophila from critically endangered Acipenser baerii. Aquac Rep [Internet] 2022; 26:101293; doi: 10.1016/j.aqrep.2022.101293
31. Xiong NX, Luo SW, Fan LF, Mao ZW, Luo KK, Liu SJ, et al. Comparative analysis of erythrocyte hemolysis, plasma parameters and metabolic features in red crucian carp (Carassius auratus red var) and triploid hybrid fish following Aeromonas hydrophila challenge. Fish Shellfish Immunol [Internet] 2021; 118:369–84; doi: 10.1016/j.fsi.2021.09.025
32. Ahangarzadeh M, Najafabadi MG, Peyghan R, Houshmand H, Rohani MS, Soltani M. Detection and distribution of virulence genes in Aeromonas hydrophila isolates causing infection in cultured carps. Vet Res Forum 2022; 13(1):55–60.
33. Rajme-Manzur D, Gollas-Galván T, Vargas-Albores F, Martínez-Porchas M, Hernández-Oñate MÁ, Hernández-López J. Granulomatous bacterial diseases in fish: an overview of the host’s immune response. Comp Biochem Physiol A Mol Integr Physiol 2021; 261:111058.
34. Pellin GP, Martins RA, de Queiroz CA, Sousa TF, Muniz AW, da Silva GF, et al. Aeromonas from farmed tambaqui from North Brazil: molecular identification and pathogenic potential. Cienc Rural 2023; 53(4):1–7.
35. Zhang G, Wang J, Zhao Z, Xin T, Fan X, Shen Q, et al. Regulated necrosis, a proinflammatory cell death, potentially counteracts pathogenic infections. Cell Death Dis 2022; 13(7):637.
36. Rosidah, Yunita MD, Nurruhwati I, Rizal A. Histopathological changes in gold fish (Carassius auratus (Linnaeus, 1758)) infected by Aeromonas hydrophila bacteria with various densities. World Sci News [Internet] 2020; 142:150–68. Available via www.worldscientificnews.com
37. Aisiah S, Prajitno A, Maftuch M, Yuniarti A. Effect of Nauclea subdita (Korth.) Steud. leaf extract on hematological and histopathological changes in liver and kidney of striped catfish infected by Aeromonas hydrophila. Vet World 2020; 13(1):47–53.
38. Li F, Zhao J, Zhao Y, Liu X, Huang J, Zhang Y, et al. Pathological findings of Chinese sucker (Myxocyprinus asiaticus) infected with virulent Aeromonas hydrophila. Aquac Rep [Internet] 2021; 21:100884; doi: 10.1016/j.aqrep.2021.100884
39. Al-Fatlawy HNK. The effect of environmental factors on the enzyme production of Aeromonas Hydrophila isolates. Medico-Legal Update 2021; 21(1):1043–50.
40. Pessoa RBG, Marques DSC, Lima ROHA, Oliveira MBM, Lima GMS, Maciel de Carvalho EVM, et al. Molecular characterization and evaluation of virulence traits of Aeromonas spp. isolated from the tambaqui fish (Colossoma macropomum). Microb Pathog [Internet] 2020; 147:104273; doi: 10.1016/j.micpath.2020.104273
41. Ahmed I, Reshi QM, Fazio F. The influence of the endogenous and exogenous factors on hematological parameters in different fish species: a review. Aquac Int 2020; 28(3):869–99.
42. Fikri F, Wardhana DK, Purnomo A, Khairani S, Chhetri S, Purnama MTE. Aerolysin gene characterization and antimicrobial resistance profile of Aeromonas hydrophila isolated from milkfish (Chanos chanos) in Gresik, Indonesia. Vet World 2022; 15(7):1759–64.
43. Esmaeili M. Blood performance: a new formula for fish growth and health. Biology (Basel) 2021; 10(12):1–17.
44. Vignesh S, Krishnaveni G, Walter Devaa JC, Muthukumar S, Uthandakalaipandian R. Experimental challenge of the freshwater fish pathogen Aeromonas hydrophila Ah17 and its effect on snakehead murrel Channa striata. Aquac Int [Internet] 2022; 30(3):1221–38; doi: 10.1007/s10499-022-00856-0
45. Qosimah D, Santoso S, Maftuch M, Khotimah H, Fitri LE, Aulanni’Am A, et al. Aeromonas hydrophila induction method in adult zebrafish (Danio rerio) as animal infection models. Vet World 2023; 16(2):250–7.
46. Andriawan S, Hadi S, Andayani S, Sanoesi E, Maftuch. Study of Holothuria scabra effect on the immune activity of Pangasianodon hypophthalmus against Aeromonas hydrophila. AACL Bioflux 2019; 12(6):2167–76.
47. Ley K, Hoffman HM, Kubes P, Cassatella MA, Zychlinsky A, Hedrick CC, et al. Neutrophils: new insights and open questions. Sci Immunol 2018; 3(30):eaat4579.
48. Chen H, Yuan G, Su J, Liu X. Hematological analysis of Ctenopharyngodon idella, Megalobrama amblycephala and Pelteobagrus fulvidraco: morphology, ultrastructure, cytochemistry and quantification of peripheral blood cells. Fish Shellfish Immunol [Internet] 2019; 90:376–84; doi: 10.1016/j.fsi.2019.04.044
49. Soliman AM, Barreda DR. The acute inflammatory response of teleost fish. Dev Comp Immunol [Internet] 2023; 146:104731; doi: 10.1016/j.dci.2023.104731
50. Abarike ED, Kuebutornye FKA, Jian J, Tang J, Lu Y, Cai J. Influences of immunostimulants on phagocytes in cultured fish: a mini review. Rev Aquac 2019; 11(4):1219–27.
51. Grayfer L, Kerimoglu B, Yaparla A, Hodgkinson JW, Xie J, Belosevic M. Mechanisms of fish macrophage antimicrobial immunity. Front Immunol 2018; 9:1105.
52. Scapigliati G, Fausto AM, Picchietti S. Fish lymphocytes: an evolutionary equivalent of mammalian innate-like lymphocytes? Front Immunol 2018; 9:1–8.
53. Phuvaneswari R, Manickam N, Santhanam P. Recovery of Cyprinus carpio (ornamental koi carp) experimentally infected with Aeromonas hydrophila through phytotherapy. J Aquat Res Mar Sci 2018; 1(2):1–14.
54. Sultana F, Sajid S, Jamshed W. A study on the hematology of Golden Mahseer Tor putitora (Hamilton) in relation to Aeromonas hydrophila. Int J Multidiscip Acad Res 2023; 1(1):15–8.
55. Hanief F, Shah FA, Abubakr A, Asimi O, Bhat BA, Afshan H. Immunopathogenesis of haemato-biochemical parameters and haematopoietic organs of Cyprinus carpio var. communis challenged with Aeromonas hydrophila. Aquac Res 2021; 52(12):6280–7.


How to Cite this Article
Pubmed Style

Azizah A, Ulkhaq MF, Apriliani DP, Tjahjaningsih W, Abdillah AA. Clinicopathological and hematological profile of silver rasbora (Rasbora argyrotaenia) after experimentally infection with Aeromonas hydrophila. J Res Vet Sci. 2023; 1(1): 18-26. doi:10.5455/JRVS.20230811124754


Web Style

Azizah A, Ulkhaq MF, Apriliani DP, Tjahjaningsih W, Abdillah AA. Clinicopathological and hematological profile of silver rasbora (Rasbora argyrotaenia) after experimentally infection with Aeromonas hydrophila. https://www.wisdomgale.com/jrvs/?mno=164871 [Access: December 22, 2024]. doi:10.5455/JRVS.20230811124754


AMA (American Medical Association) Style

Azizah A, Ulkhaq MF, Apriliani DP, Tjahjaningsih W, Abdillah AA. Clinicopathological and hematological profile of silver rasbora (Rasbora argyrotaenia) after experimentally infection with Aeromonas hydrophila. J Res Vet Sci. 2023; 1(1): 18-26. doi:10.5455/JRVS.20230811124754



Vancouver/ICMJE Style

Azizah A, Ulkhaq MF, Apriliani DP, Tjahjaningsih W, Abdillah AA. Clinicopathological and hematological profile of silver rasbora (Rasbora argyrotaenia) after experimentally infection with Aeromonas hydrophila. J Res Vet Sci. (2023), [cited December 22, 2024]; 1(1): 18-26. doi:10.5455/JRVS.20230811124754



Harvard Style

Azizah, A., Ulkhaq, . M. F., Apriliani, . D. P., Tjahjaningsih, . W. & Abdillah, . A. A. (2023) Clinicopathological and hematological profile of silver rasbora (Rasbora argyrotaenia) after experimentally infection with Aeromonas hydrophila. J Res Vet Sci, 1 (1), 18-26. doi:10.5455/JRVS.20230811124754



Turabian Style

Azizah, Aulia, Mohammad Faizal Ulkhaq, Dian Putri Apriliani, Wahju Tjahjaningsih, and Annur Ahadi Abdillah. 2023. Clinicopathological and hematological profile of silver rasbora (Rasbora argyrotaenia) after experimentally infection with Aeromonas hydrophila. Journal of Research in Veterinary Sciences, 1 (1), 18-26. doi:10.5455/JRVS.20230811124754



Chicago Style

Azizah, Aulia, Mohammad Faizal Ulkhaq, Dian Putri Apriliani, Wahju Tjahjaningsih, and Annur Ahadi Abdillah. "Clinicopathological and hematological profile of silver rasbora (Rasbora argyrotaenia) after experimentally infection with Aeromonas hydrophila." Journal of Research in Veterinary Sciences 1 (2023), 18-26. doi:10.5455/JRVS.20230811124754



MLA (The Modern Language Association) Style

Azizah, Aulia, Mohammad Faizal Ulkhaq, Dian Putri Apriliani, Wahju Tjahjaningsih, and Annur Ahadi Abdillah. "Clinicopathological and hematological profile of silver rasbora (Rasbora argyrotaenia) after experimentally infection with Aeromonas hydrophila." Journal of Research in Veterinary Sciences 1.1 (2023), 18-26. Print. doi:10.5455/JRVS.20230811124754



APA (American Psychological Association) Style

Azizah, A., Ulkhaq, . M. F., Apriliani, . D. P., Tjahjaningsih, . W. & Abdillah, . A. A. (2023) Clinicopathological and hematological profile of silver rasbora (Rasbora argyrotaenia) after experimentally infection with Aeromonas hydrophila. Journal of Research in Veterinary Sciences, 1 (1), 18-26. doi:10.5455/JRVS.20230811124754