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Anatomy & Physiology

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Received: January 01, 1970 | Published: ,

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Abstract

This research was designed to study the parasitic infection and prevalence of juvenile and adult stages of Clarias gariepinus in Lake Geriyo. The study was conducted between June and November, 2016. A total of one hundred and thirty-two (132) fish were sampled for parasitic investigation. Out of these, adults (66) and juveniles (66), were procured from fishermen at the landing site. They were examined for parasitic infections using direct wet mount microscopy and stained smears. Fish body weights, and total length, were determined. Data generated were analysed using t-test and chi-square. The results showed that, a total number of 60 adult C. gariepinus were infected out of which 316 parasites were recovered, while in juvenile C. gariepinus, a total of 41 fish were infected in which 80 parasites were recovered. Parasitic infestations in the adult and juvenile females were significantly higher than male adults and juvenile with 91.11% for female adult and 66.67% for female juvenile. Nine classes of parasites and nineteen (19) parasites species were recorded from the gills, stomach, intestine, and skin mucus in the research study. There were significant differences (p<0.05) between incidence of infestation and standard length and body weight of Clarias gariepinus.

Keywords: parasitic infection, prevalence, incidence, Clarias gariepinus, lake geriyo

Introduction

In aquaculture, some parasites may be highly pathogenic and contribute to high fish mortalities and economic loss, while in natural systems they may threaten the abundance and diversity of indigenous fish species.1 Parasites in fish are of concern since they often weakening the host`s immune system thereby increasing their susceptibility to secondary infections, resulting in the nutritive devaluation of fish and subsequent economic losses.2 Parasites also compete for food, thereby depriving fish of essential nutrients and inhibiting growth leading to morbidity and mortality with consequent economic losses.3 Under intensive fish culture conditions, parasites tend to proliferate, because of compromised water quality and other stress imposing factors.4 In recent times, attention has shifted to fish parasites due to increased aqua cultural practices. Several studies have been reported on parasites of cultured and wild fish.5 Parasites and bacteria may be of minimal significance under natural conditions, but can cause substantial problems when animals are crowded and stressed under culture conditions. Poor handling of fish is a major cause of both bacterial and parasitic infections. Translocation of fingerlings/fry from one place to another without proper care can spread diseases and parasites. Increased nutrient levels due to intensive cage culture promote proliferation of parasites.

Parasites of fish often deteriorates the host immune system thereby resulting to secondary infections, nutritional reduction, reproduction, energy loss, inhibiting growth leading to morbidity and mortality with consequent economic losses.2 Clarias gariepinus is one of the most resistant and widely accepted and highly valued fish that are been cultivated in Nigeria, therefore the need for documented research on parasites which might constitute serious problems on this fish cannot be over emphasized Dankishiya & Zakari6 Irrespective of these, various parasites are associated with C. gariepinus in the wild and cultured environment where they cause morbidity, mortality and economic losses in aquaculture practice in the world.7 Therefore, this research work aims at investigating the parasitic infection and prevalence in juvenile and adult Clarias gariepinus in Lake Geriyo in Yola, Adamawa state of Nigeria.

Materials and method

location

 Lake Geriyo is located at the outskirts of Jimeta-Yola metropolis on the north-west region (Longitude 12 25 E and between latitude 9 81N and 9 17N). It has a high level of 750ha and low level of 200ha. The area amiable to fisheries development is about 250ha; consequently, most of the settlers around the lake are fishermen (Upper Benue River Basin Development Authority, UBRBDA) (1985).

Sample collection and identification of Clarias gariepinus

Fish samples were collected from the selected study area for a period of six (6) months. The fish samples were transported alive to the Fisheries laboratory, Modibbo Adama University of Technology, Yola, in a plastic container filled with water for identification and examination. The fish was identified as described by Teugels.8 They have an elongated body, a soft rayed dorsal fin extending to or nearly to the caudal fin base, a soft rayed anal fin extending from just behind the anus to the caudal base, pectoral fins each with a serrated anterior bony spine, head depressed, covered largely by firmly sutured, surface sculptured bony plates forming a protective helmet, four pairs of flagellate barbells (nasals, maxillaries, inner and outer mandibular), air breathing organs derived from the 2nd and 4th epibranchialis within a super branchial chamber.

Sexing of fish

Sexing of fish was done by physical observation of the urogenital papillae. It is long or distended in male while in the female it is round and reddish in the matured ones. Also visual observation of the gonads in male and ovaries in the female is confirmatory.9

Measurement of fish

The standard length was measured with a meter rule while the weight was measured using top loading sensitive weighing balance (Model; Mettler Toledo).

Examination of samples for ecto and endo parasites

The external surface (skin and fins) were placed under a light microscope for examination. Gills were cut out and placed into separate Petri dishes and observed with hand lens for parasites. Parasites were collected and fixed in buffered formalin for further processing and specimen identification.4 The fish was dissected to expose the alimentary canal. The alimentary canal was removed and sectioned into various parts; esophagus and stomach, intestine and rectum. The gut was used for parasitic examination because this is where food is most abundant for the parasites. Each section was placed separately in Petri dishes containing 0.9% normal saline. Each section was slit longitudinally and examined for parasites under a dissecting microscope between 10 and 30X magnification. The emergence of any worm was easily noticed by its wriggling movement in the saline solution under a microscope. Parasites found were counted, and thereafter fixed and preserved in 5% formalin. Representative parasites were stained overnight with weak solution of Erich’s haematoxylin.

Parasite prevalence and intensity estimation 

Prevalence of parasite infection: The prevalence of parasites infection was calculated using the model:10

Prevalence( % )= No of fish host infectedx100 Total no. of fish host Examined MathType@MTEF@5@5@+= feaagKart1ev2aaatCvAUfeBSjuyZL2yd9gzLbvyNv2CaerbuLwBLn hiov2DGi1BTfMBaeXatLxBI9gBaerbd9wDYLwzYbItLDharqqtubsr 4rNCHbGeaGqkY=Mj0xXdbba91rFfpec8Eeeu0xXdbba9frFj0=OqFf ea0dXdd9vqaq=JfrVkFHe9pgea0dXdar=Jb9hs0dXdbPYxe9vr0=vr 0=vqpWqaaeaabiGaciaacaqabeaadaqaaqaaaOqaaKqzGeaeaaaaaa aaa8qacaWGqbGaamOCaiaadwgacaWG2bGaamyyaiaadYgacaWGLbGa amOBaiaadogacaWGLbGcdaqadaqaaKqzGeGaaiyjaaGccaGLOaGaay zkaaqcLbsacqGH9aqpkmaalaaabaqcLbsacaWGobGaam4Baiaaccka caWGVbGaamOzaiaacckacaWGMbGaamyAaiaadohacaWGObGaaiiOai aadIgacaWGVbGaam4CaiaadshacaGGGcGaamyAaiaad6gacaWGMbGa amyzaiaadogacaWG0bGaamyzaiaadsgacaWG4bGaaGymaiaaicdaca aIWaaakeaajugibiaabsfacaqGVbGaaeiDaiaabggacaqGSbGaaeiO aiaab6gacaqGVbGaaiOlaiaabckacaqGVbGaaeOzaiaabckacaqGMb GaaeyAaiaabohacaqGObGaaeiOaiaabIgacaqGVbGaae4Caiaabsha caqGGcGaaeyraiaabIhacaqGHbGaaeyBaiaabMgacaqGUbGaaeyzai aabsgaaaaaaa@7E71@

Prevalence based on sex:

The prevalence of parasites infection base on sex of fish was estimated using:11

Prevalence( % )= No. of a particular sex of fish infected x 100 Total no. of particular sex of fish examined MathType@MTEF@5@5@+= feaagKart1ev2aaatCvAUfeBSjuyZL2yd9gzLbvyNv2CaerbuLwBLn hiov2DGi1BTfMBaeXatLxBI9gBaerbd9wDYLwzYbItLDharqqtubsr 4rNCHbGeaGqkY=Mj0xXdbba91rFfpec8Eeeu0xXdbba9frFj0=OqFf ea0dXdd9vqaq=JfrVkFHe9pgea0dXdar=Jb9hs0dXdbPYxe9vr0=vr 0=vqpWqaaeaabiGaciaacaqabeaadaqaaqaaaOqaaKqzGeaeaaaaaa aaa8qacaWGqbGaamOCaiaadwgacaWG2bGaamyyaiaadYgacaWGLbGa amOBaiaadogacaWGLbGcdaqadaqaaKqzGeGaaiyjaaGccaGLOaGaay zkaaqcLbsacqGH9aqpkmaalaaabaqcLbsacaWGobGaam4Baiaac6ca caGGGcGaam4BaiaadAgacaGGGcGaamyyaiaacckacaWGWbGaamyyai aadkhacaWG0bGaamyAaiaadogacaWG1bGaamiBaiaadggacaWGYbGa aiiOaiaadohacaWGLbGaamiEaiaacckacaWGVbGaamOzaiaacckaca WGMbGaamyAaiaadohacaWGObGaaiiOaiaadMgacaWGUbGaamOzaiaa dwgacaWGJbGaamiDaiaadwgacaWGKbGaaiiOaiaadIhacaGGGcGaaG ymaiaaicdacaaIWaaakeaajugibiaadsfacaWGVbGaamiDaiaadgga caWGSbGaaiiOaiaad6gacaWGVbGaaiOlaiaacckacaWGVbGaamOzai aacckacaWGWbGaamyyaiaadkhacaWG0bGaamyAaiaadogacaWG1bGa amiBaiaadggacaWGYbGaaiiOaiaadohacaWGLbGaamiEaiaacckaca WGVbGaamOzaiaacckacaWGMbGaamyAaiaadohacaWGObGaaiiOaiaa dwgacaWG4bGaamyyaiaad2gacaWGPbGaamOBaiaadwgacaWGKbaaaa aa@9D06@

Intensity of parasite: The intensity of parasites was estimated using model:11

Intensity= Total no. of parasite species in a sample of fish Examined No. of fish host infected MathType@MTEF@5@5@+= feaagKart1ev2aaatCvAUfeBSjuyZL2yd9gzLbvyNv2CaerbuLwBLn hiov2DGi1BTfMBaeXatLxBI9gBaerbd9wDYLwzYbItLDharqqtubsr 4rNCHbGeaGqkY=Mj0xXdbba91rFfpec8Eeeu0xXdbba9frFj0=OqFf ea0dXdd9vqaq=JfrVkFHe9pgea0dXdar=Jb9hs0dXdbPYxe9vr0=vr 0=vqpWqaaeaabiGaciaacaqabeaadaqaaqaaaOqaaKqzGeaeaaaaaa aaa8qacaWGjbGaamOBaiaadshacaWGLbGaamOBaiaadohacaWGPbGa amiDaiaadMhacqGH9aqpkmaalaaabaqcLbsacaWGubGaam4Baiaads hacaWGHbGaamiBaiaacckacaWGUbGaam4Baiaac6cacaGGGcGaam4B aiaadAgacaGGGcGaamiCaiaadggacaWGYbGaamyyaiaadohacaWGPb GaamiDaiaadwgacaGGGcGaam4CaiaadchacaWGLbGaam4yaiaadMga caWGLbGaam4CaiaacckacaWGPbGaamOBaiaacckacaWGHbGaaiiOai aadohacaWGHbGaamyBaiaadchacaWGSbGaamyzaiaacckacaWGVbGa amOzaiaacckacaWGMbGaamyAaiaadohacaWGObGaaiiOaiaadweaca WG4bGaamyyaiaad2gacaWGPbGaamOBaiaadwgacaWGKbaakeaajugi biaab6eacaqGVbGaaiOlaiaabckacaqGVbGaaeOzaiaabckacaqGMb GaaeyAaiaabohacaqGObGaaeiOaiaabIgacaqGVbGaae4Caiaabsha caqGGcGaaeyAaiaab6gacaqGMbGaaeyzaiaabogacaqG0bGaaeyzai aabsgaaaaaaa@9213@

Statistical analysis

Prevalence and Intensity of infection was calculated using simple percentage (%). Length range frequencies in relation to prevalence within the samples were analysed. The dependence of infection on sex was statistically determined using chi-square analysis and t-test.

Results

Incidence of parasites in juvenile and adult clarias gariepinus from lake Geriyo of Adamawa state

This research investigated the prevalence of parasitic infection of two stages of wild Clarias gariepinus. A total of nine (9) classes of parasites were prevalence in the study which were Flagellata, Dinoflagellata, Trematoda, Copepoda, Nematoda, Motile ciliata, Protozoan, Sessile ciliata and Oomycota. Table 1 & 2 showed the parasitic incidence occurring in C. gariepinus at Lake Geriyo, Yola, and Adamawa state. A total of 60 adult Clarias gariepinus were found to be infected and 316 parasites were recovered while in juvenile Clarias gariepinus, a total of 41 fish were found to be infected and 80 parasites were recovered in Lake Geriyo. Therefore adult C. gariepinus was more prevalence with 316 parasites than juvenile. Regarding the incidence of parasites in the examined fish species based on the site locations of the parasites, it was recorded that the highest number of parasites recovered was found in the intestine with 138(43.67) at lake Geriyo, followed by the stomach 84(26.58), the gill 68(21.52) and the skin 26(8.23) while in juvenile C. gariepinus the prevalence site was the skin with 41(51.25) followed by the gill 28(35.0), the intestine 6(7.5) and the least prevalent site was in the stomach with 5(6.25).

Parasite species

No. of fish infected

%

Gill

%

Skin

%

Intestine

%

Stomach

%

Ergasilus sp

5

8.33

28

8.86

-

-

-

-

-

-

Spironucleus vortens

4

6.67

-

-

-

-

37

11.71

-

-

Coccidia sp

-

-

-

-

-

-

-

-

-

-

Protoopalina symphysodinium

4

6.67

-

-

-

-

-

-

15

4.75

Piscinoodinium sp

8

13.33

8

2.53

22

6.96

-

-

-

-

Dactylogyrid sp

3

5

8

2.53

-

-

-

-

-

-

Tetrahymena sp

7

11.66

4

1.27

4

1.27

-

-

15

4.75

Chilodonella

3

5

11

4.48

-

-

-

-

-

-

Capillaria sp

10

16.67

-

-

-

-

36

11.39

15

4.75

Contracaecum sp

-

-

-

-

-

-

-

-

-

-

Myxozoans

2

3.33

-

-

-

-

8

2.53

-

-

Microsporidians

-

-

-

-

-

-

-

-

-

-

Digeneans sp

12

20

-

-

-

-

57

18.04

39

12.34

Planaria sp

-

-

-

-

-

-

-

-

-

-

Apiosoma sp

2

3.33

9

2.33

-

-

-

-

-

-

Total

60

 

68

 

26

 

138

 

84

 

Table 1 Incidence of parasites in adult Clarias gariepinus

Parasite species

No. of fish infected

%

Gill

%

Skin

%

Intestine

%

Stomach

%

Argulus sp

1

2.43

-

-

1

15.2

-

-

-

-

Ergasilus lizae

2

4.88

2

2.5

-

-

-

-

-

-

Piscinoodinium pillulare

5

12.2

8

10

9

11.25

-

-

-

-

Crypto

6

14.64

-

-

-

-

6

7.5

5

6.25

biaiubilans

Chilodonalla

2

4.88

-

-

4

5

-

-

-

-

Ichthyopthiirus multifiliis

4

9.76

2

2.5

3

3.75

-

-

-

-

Tetrahymena

12

29.27

8

10

14

17.5

-

-

-

-

Trichodina sp

8

19.51

5

6.25

10

12.5

-

-

-

-

Capillaria sp

 -

-

-

-

-

-

-

-

-

-

Saprolegnia sp

 -

-

-

-

-

-

-

-

-

-

Microsporidians

 -

-

-

-

-

-

-

-

-

-

Capriniana sp

1

2.43

3

3.75

-

-

-

-

-

-

Total

41

 

28

 

41

 

6

 

5

 

Table 2  Incidence of parasites in juvenile Clarias gariepinus

Prevalence of parasites in adult Clarias gariepinus based on sex

Table 3 represents the prevalence parasites in the wild (Lake Geriyo) C. gariepinus fish samples. Out of the examined C. gariepinus, fishes were found infected with parasites with an infection rate that reaches 91.11% and 75.00% in female fish in the wild. The Infection rate and intensity of the parasites were higher in the wild C. gariepinus. 91.11% of females were infected while 36.67% of males were infected. The mean parasite intensity is higher in the wild (5.32) than in the cultured environment (3.36). The chi square value shows that there is no significant difference (p>0.05) between the prevalence and intensity of parasite infection in adult C. gariepinus based on sex.

Location

Sex

Number examined

No of fish infected

Total no of parasites

Prevalence (%)

Intensity of parasite

Mean parasite intensity

Lake Geriyo

Male

21

19

104

90.45

5.47

Female

45

41

212

91.11

5.17

5.32

Table 3 Prevalence and intensity of parasite infection in adult Clarias gariepinus based on sex

x 2 MathType@MTEF@5@5@+= feaagKart1ev2aaatCvAUfeBSjuyZL2yd9gzLbvyNv2CaerbuLwBLn hiov2DGi1BTfMBaeXatLxBI9gBaerbd9wDYLwzYbItLDharqqtubsr 4rNCHbGeaGqkY=Mj0xXdbba91rFfpec8Eeeu0xXdbba9frFj0=OqFf ea0dXdd9vqaq=JfrVkFHe9pgea0dXdar=Jb9hs0dXdbPYxe9vr0=vr 0=vqpWqaaeaabiGaciaacaqabeaadaqaaqaaaOqaaKqzGeGaamiEaO WaaWbaaSqabeaajugWaiaaikdaaaaaaa@3ABB@ =0.08099, df, 1, p=0.7760 (p>0.05)
Key x2=Chi square
Df, degree of freedom
P, probability level

Prevalence of parasites in juvenile Clarias gariepinus based on sex

Table 4 represents the prevalence of parasites in the juvenile C. gariepinus fish samples. Out of the examined C. gariepinus, fishes were found infected with parasites with an infection rate that reaches 66.67 % and 15.91% in female fish in the wild. The Infection rate and intensity of the parasites were higher in the wild C. gariepinus. Males were infected with the prevalence rate of 55.56% to 13.64% male. The chi square value shows that there was no significant difference (p>0.05) between the prevalence and intensity of parasite infection in juvenile C. gariepinus based on sex.

Location

Sex

No of Fish Examined

No of Fish Infected

Total No of Parasites recovered

Prevalence (%)

Intensity of Parasite

Mean Parasite Intensity

Lake Geriyo

Male

27

15

32

55.56

2.13

 

 

Female

39

26

48

66.67

1.85

 1.99

Table 4 Prevalence and intensity of parasite infection in juvenile Clarias gariepinus based on sex

x 2 MathType@MTEF@5@5@+= feaagKart1ev2aaatCvAUfeBSjuyZL2yd9gzLbvyNv2CaerbuLwBLn hiov2DGi1BTfMBaeXatLxBI9gBaerbd9wDYLwzYbItLDharqqtubsr 4rNCHbGeaGqkY=Mj0xXdbba91rFfpec8Eeeu0xXdbba9frFj0=OqFf ea0dXdd9vqaq=JfrVkFHe9pgea0dXdar=Jb9hs0dXdbPYxe9vr0=vr 0=vqpWqaaeaabiGaciaacaqabeaadaqaaqaaaOqaaKqzGeGaamiEaO WaaWbaaSqabeaajugWaiaaikdaaaaaaa@3ABB@  0.1527; p=0.6960; p>0.05; df=1
Key x 2 MathType@MTEF@5@5@+= feaagKart1ev2aaatCvAUfeBSjuyZL2yd9gzLbvyNv2CaerbuLwBLn hiov2DGi1BTfMBaeXatLxBI9gBaerbd9wDYLwzYbItLDharqqtubsr 4rNCHbGeaGqkY=Mj0xXdbba91rFfpec8Eeeu0xXdbba9frFj0=OqFf ea0dXdd9vqaq=JfrVkFHe9pgea0dXdar=Jb9hs0dXdbPYxe9vr0=vr 0=vqpWqaaeaabiGaciaacaqabeaadaqaaqaaaOqaaKqzGeGaamiEaO WaaWbaaSqabeaajugWaiaaikdaaaaaaa@3ABB@ = Chi square
Df, degree of freedom
P, probability level

Prevalence and intensity of parasite infection in adults Clarias gariepinus based on total length and body weight in lake Geriyo

The length frequency and weight distribution of adult C. gariepinus in Lake Geriyo are presented in Table 5. In the fish samples, the 41.21–44.20cm total length group had the highest number of parasites recovered with a total of 84 parasites and body weight of 305.00-355.00 g. The least number of 19 parasites recovered was recorded in the 35.21-38.20cm size groups, with a body weight of 203.00-253.00g. There was no particular consistency in the condition factor values.

Total length (cm)

Body weight(g)

No of fish examined

No of fish infected

Total no of parasites recovered

Prevalence
(%)

Intensity of parasite

26.20-29.20

50.00-100.00

10

13

39

86.67

3

29.21-32.20

101.00-151.00

8

9

22

90

2.44

32.21-35.20

152.00-202.00

12

12

52

100

4.33

35.21-38.20

203.00-253.00

11

6

19

100

3.17

38.21-41.20

254.00-304.00

10

8

46

100

5.75

41.21-44.20

305.00-355.00

6

5

84

50

16.8

44.21-47.20

356.00-406.00

9

5

20

71.43

4

Table 5 Prevalence and intensity of parasite infection in adults Clariasgariepinus based on total length and body weight in lake geriyo

Prevalence and intensity of parasite infection in juvenile Clarias gariepinus based on total length and body weight in Lake Geriyo

The length frequency and weight distribution of juvenile C. gariepinus in Lake Geriyo are presented in Table 6. In the fish samples, the 32.22–42.22g body weight group had the highest number of parasites recovered with a total of 17parasites and total length of 17.9-22.90cm. The least number of 5 parasites recovered was recorded in the 73.25– 83.25g size groups, with a total length of 37.91–42.90cm. There was no particular consistency in the condition factor values Figure 1.

Body weight (g)

Total length (cm)

No of fish examined

No of fish infected

Total no of parasites recovered

Prevalence (%)

Intensity of parasite

12.20-22.20

7.90-12.90

15

6

7

40

1.17

22.21-32.21

12.91-17.90

4

4

10

100

2.5

32.22-42.22

17.91-22.90

18

10

17

55.56

1.7

42.23-53.22

22.91-27.90

10

7

9

70

1.29

53.23-63.23

27.91-32.90

7

5

7

71.43

1.4

63.24-73.24

32.91-37.90

5

2

8

40

4

73.25-83.25

37.91-42.90

7

2

5

50

2.5

Table 6  Prevalence and intensity of parasite infection in Juveniles Clariasgariepinus Based on Total Length and Body Weight in Lake Geriyo

Figure 1 Map of Lake Gerio.

Source Tukura Echuano Eyiseh Research field work (2016)

Discussion

Incidence of parasites in juvenile and adult Clarias gariepinus

This study investigated 132 C. gariepinus species for parasitic infection, a total of 60 adult Clarias gariepinus were found to be infected and 316 parasites were recovered while in juvenile Clarias gariepinus, a total of 41 fish were found to be infected and 80 parasites were recovered in Lake Geriyo. This study reported higher infection rates in adult fish as compared to the absence of infection in small fish. This finding confirms the works of12‒15 who observed that the condition of infection was age factor. These investigators argued that the higher infection rates in adults than young may be due to the longer duration of time the older fish were exposed to the agents of infection in the environment. To substantiate this, Roberts13 reported that larger fish show greater surface area for infection than younger ones; Oniye et al.12 revealed that no parasitic infection of juveniles but higher in adult fish due to change in diet during adulthood, while Bichi and Dawaki. (200) stated that increase in the abundance of parasites is associated with host size. Prevalence of parasites was higher in the intestine than the stomach; gill and skin, similar to the findings by Mohammed A et al.16 Bichi & Yelwa.14 They argued that regional localization in the gut can be attributed to several factors, such as Hydrogen ion concentration, chemotactic response as well as food reserve. Onwuliri COE & Mgbemena MO.17 reported that helminthes differ in their nutritional and respiratory requirements which may influence their choice of habitat.

Prevalence and intensity of parasite infection in Clarias gariepinus based on sex

From this study, sampled female fish were more parasitized than males. Females had higher incidence rate and prevalence rate than males. The parasite prevalence results based on sex showed that female adult and juveniles in the wild had higher prevalence rate of 91.11% respectively than their corresponding males of adult and juveniles from the fish farm with prevalence rate of 75% and 90.45% respectively. Emere and Egbe reported that due to the physiological state of the female, most gravid females could have reduced resistance to infection by parasites. This is consistent with the findings of Emere who reported differences in the incidence of infestation between male and female fish, which may be due to differential feeding either by quantity or quality of feed, or as a result of different degrees of resistance to infection.18

The result obtained in this study revealed varying degree of prevalence and intensity rate of parasitic infection in the two studied area at Lake Geriyo and Gesedaddo’s Farm. The sex percentages found in this study indicated that more females than males occurred in sampled fish population from the two locations. Similarly a higher number of helminth parasites were found in females than the males. There was a significant difference (p<0.05) in the prevalence of infection between the males and the females.

Prevalence and intensity of parasite infection in Clarias gariepinus based on length in Lake Geriyo

Based on length, adult fish length range of 17.91-22.90cm had the highest incidence rate of parasites at 84.00%. This means that the adult fish were more infested than the juvenile ones. This could be attributed to the fact adult fish have less immunity against parasites whereas juvenile fish have fully developed immunity against parasitic infestation. This observation is not in consonance with Adeyemo (2001) who investigated the incidence and pathogenesis of Chrostomium tilapiae in Oyo State farms and reported that juvenile fish were more susceptible to C. tilapiae infection. This is also not in consonance with Akinsanya et al.10 who reported that the smaller fish were more infested than the bigger ones. But Kudoro (1995) studied some parasites of culture fish and reported that there was a gradual increase in the percentage infection with increase in weight. From this study, female fish were more parasitized than males. Females had higher incidence rate than males. This is consistent with the findings of Emere, who reported differences in the incidence of infestation between male and female fish, which may be due to differential feeding either by quantity or quality of feed, or as a result of different degrees of resistance to infection. Emere and Egbe also reported that due to the physiological state of the female, most gravid females could have reduced resistance to infection by parasites.

Prevalence and intensity of parasite infection in Clarias gariepinus based on weight in lake Geriyo

In relation to weight, weight range of 254-304, and 305-355grams had the highest incidence rate of parasites at 100.00%. This means that the adult fish were more infested than the juvenile ones. This could be attributed to the fact adult fish have less immunity against parasites whereas juvenile fish have fully developed immunity against parasitic infestation. This observation is not in consonance with Adeyemo who investigated the incidence and pathogenesis of Chrostomium tilapiae in Oyo State farms and reported that juvenile fish were more susceptible to C. tilapiae infection. This is also not in consonance with Akinsanya et al.10 who reported that the smaller fish were more infested than the bigger ones. But Kudoro studied some parasites of culture fish and reported that there was a gradual increase in the percentage infection with increase in weight. From this study, female fish were more parasitized than males. Females had higher incidence rate than males. This is consistent with the findings of Emere who reported differences in the incidence of infestation between male and female fish, which may be due to differential feeding either by quantity or quality of feed, or as a result of different degrees of resistance to infection. Emere and Egbe, also reported that due to the physiological state of the female, most gravid females could have reduced resistance to infection by parasites.

Prevalence of parasites based on total length showed that total length of the adult C. gariepinus in the wild of the range 32.20-35.20, 35.20-38.20 and 38.20-41.20cm gave the highest prevalence of 100% while highest prevalence in cultured C. gariepinus was 84% having the total length range of 17.91-22.90cm. Prevalence of parasites based on weight showed that weight range of the adult C. gariepinus in the wild 254-304g and 305-355g gave 100% prevalence compared to cultured adult and juvenile which gave 83.33% with weight range of 460-500g. The incidence of parasites revealed that the gill and intestine of adult C. gariepinus in the wild recorded the highest incidence of parasites of 30(22.73%) of the class Flagellates and Dinoflagellata respectively.

From this study, sampled female fish were more parasitized than males. The adult/bigger fish were more infested than the juvenile or smaller ones. This could be attributed to the fact that the value of the condition factor is influenced by age of fish, sex, season, stage of maturation, fullness of gut, type of food consumed, amount of fat reserve and degree of muscular development. The occurrence of parasites in this study leads to the conclusion that the source of juveniles is an important determinant of the distribution and occurrence of parasites. Therefore, it is recommended that: Thorough screening and sanitary control of juveniles from wild is necessary before restocking activities. Also education about proper preparation of fish is a proper preventive measure. Considering the prevalence sites, a proper cooking and degutting of fish is highly recommended to avoid zoonotic disease.

Acknowledgements

None.

Conflict of interest

Author declares that there is no conflicts of interest.

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