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Aquaculture & Marine Biology

Research Article Volume 5 Issue 1

Production Assessment of Artemia franciscana (Imported Species) with the Local Species of Ghom Province Artemia Pond Culture at the Coast of Ghom Province (Iran) Namak Lake

Asadpour Osalou YA, Ganji S, Talebi A, Seidgar M, Mohebbi F

National Artemia Research Center, Iranian Fisheries Science Research Institute, Agricultural Research, Education and Extension Organization (AREEO), Urmia, Iran

Correspondence: Asadpour Osalou YA, National Artemia Research Center, Iranian Fisheries Science Research Institute, Agricultural Research, Education and Extension Organization (AREEO), Iran

Received: December 06, 2016 | Published: January 20, 2017

Citation: Asadpour Osalou YA, Ganji S, Talebi A, Seidgar M, Mohebbi F (2017) Production Assessment of Artemia franciscana (Imported Species) with the Local Species of Ghom Province Artemia pond culture at the Coast of Ghom Province (Iran) Namak Lake. J Aquac Mar Biol 5(1): 00109 DOI: 10.15406/jamb.2017.05.00109

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Abstract

Artemia is a Crustacean of Artemidae family, whose importance has been realized as of year 1930 in the field of aquaculture as live food source. Whereas under current global conditions, Artemia cannot be harvested from its natural habitats, today growing the same is deemed as one of the main approaches to achieve such species, as the environmental and genetic factors as well as type of Artemia directly affect the growing of this species. In this study, 2 species of local Artemia from Ghom Province, A. parthenogenetica, were cultured together with imported species, A. franciscana, in 6 constructed ponds, each in 3 treatments along the coast of Ghom’s Namak Lake for a 180-day period. The results indicate that cyst and biomass culture and production in the local specie are more suitable than the imported one and 80 and 66 kg/hectare of cyst were produced from Ghom’s local and A. franciscana imported species, respectively. 2,800 and 2,200 kg of biomass were also achieved from Ghom’s local and A. franciscana imported species, respectively during the study period. The final result of this study showed that adaptability of the local species with the local growing natural environments conditions was cost-effective. On the other hand, the results indicated that the suitable species for culturing in any given region is the relevant local species, which preserving the genetic reserves in each region also, the invasion of unwanted species is also prevented.

Keywords: Artemia; Ghom province; Ecological effects; Species

Introduction

Ghom Province is situated in 34.8’ latitude and 52,6’ longitude in central Iran and has been classified in terms of climatic identify as per Silianov and Ambroge classification as cold arid and semi-arid region with annual rainfall of 127+/-5 mm and temperature range of 8.1~44^C in Jamkaran and Serasuon meteorological stations, which has an average 68 days of freezing weather. According to synoptic stations studies, Ghom Province has dominant southern wind blow with a speed of 6~9 knots. The main water supply source of the same is through river and Ghom Road, each 200 MCBM/annum and Jajroud and Shoush rivers of 130 and 80 MCBM/annum, respectively [1,2]. This study was performed to: compare cysts and biomass production between an imported Artemia species (A. franciscana) with a native species (A. parthenogenetica). Use bare lands in arid and semi-arid regions with salty underground water for Artemia culture.

Materials and Methods

This study was conducted in Shams Abad drainage margin located in Coast of Ghom Lake. In this study, 6 ponds (each 100 sq.m. in area, h: 1.5m for water filling volume of 1m) were designed and constructed (i.e. each Artemia species in a triplicate repetition). Water filling the ponds was made using the regional drainage waters dissolved with saline of 15ppt and the salinities of each was adjusted to reach 50 ppt. The tested ponds area was totally fenced to prevent from entering the birds and unwanted animals. Protection from entering of unwanted animals was conducted by taking benefit from physical protectors on the inlets of pounds. Fertilizing and enriching the culturing ponds were achieved by standard method [3]. Nitrate and phosphate and urea fertilizers were used in a dose of 50kg/hectare, while chicken fertilizer was also applied. Regional local Artemia cysts and those of Artemia franciscana (of cultured type) were obtained from Ghom Province Lake and A.P.T Company (Vietnam), respectively. The cysts were then hatched and released as the relevant standard method [4]. In this method, cysts disinfection was conducted by hypochlorite solution (200 mg/lit) for 20 minutes accompanied by suitable aeration and then they were washed and hatched by a 125 micron lace and freshwater. The hatching method was based on the standard method conducted by Van Stepan et al. [4].

Physicochemical factors such as temperature, oxygen and clarity, pH, BOD and COD on all ponds were similar. The environmental factors were measured according to the method explained by Ajorlo & Abdullah [5]. Combinations of Artemia partenogenetica and A. franciscana were sampled and determined fortnightly from all the surfaces of the pond. Later on, their biological stages including number of cysts, nauplii and eggs in the female uterine bag were determined. Dry and wet weights of the samples were also examined. By taking benefit from 100 micron fence the biomass per CBM of pond water was measured. The culture period per treatments was 6 months, during which water salinity was kept around 50±5 mg/L. In order to compensate the water evaporation and penetrability, the relevant reduction was calculated. After completion of culture period, the entire ponds water was demolished by 6% kozation disinfectant solution to prevent dispersion of Artemia and then the ponds bottoms were completely dried and plowed as suggested by Azari et al. [6].

In order to the grow the species in the further stages a green pond (pond in which Dunaliella sp was grown by standard conditions) was applied by taking benefit from chemical and biologic fertilizers of di ammonium phosphate and chicken fertilizer. 50 kg of urea chemical fertilizer together with 50 kg di-ammonium phosphate fertilizer and 100 kg chicken fertilizer mortar were added per time of harvesting microalgae (three times a week). Releasing was conducted as per a rate of 25 nauplii/L of pond water by 100 lit plastic bags and after homogenizing thermal conditions.

Results and Discussion

The factors of each hydrological time periods of the ponds during the culture period were obtained as Table 1. As can be seen in Table 1, the calcium carbonate (CaCo3) was the salt which had the highest concentration in the ponds. Calcium (Ca++) and magnesium (Mg++) were two cations with high concentrations, respectively. The lowest values were related to the NH3, N-NH4. Hardness, acidity and salinity evaluated as 9500 mg / lit, 96 mg / lit and 5054ppt, respectively.

Unit

Factor

Unit

Factor

1 mm

depth

mg/2230± 26

Ca++

Clay loam

text

Mg1215± 15

Mg++

100 ds/ m

ec

10800± 146

CaCo3

6128 mg/ lit

t.d.s

1.4± 0.2

NH3

9500 mg/ lit

Total hardness

8.5± 0.56

No2

96 mg/ lit

Total Alkalinity

7.9± 0.60

Acidity

12.3

P-Po4

1.4± 0.15

N-NH4

27.6

Cl

6.5± 0.42

No3

5.54

So4

5.2± 0.21

Salinity

107831cell/ lit

Total seaweed qty

Table 1: ponds hydrological factors during culture period.

According to Table 2, the highest and the lowest population density of microalgae in the pond were observed for Navicula sp. & Scenedesmus dimorphus, respectively. In total, the highest densities of microalgae in the culture pond were Navicula sp, Nitzschia sp. and Gophonema sp, respectively.

Cell/lit

Agar type

16002± 201

Gophonema sp.

47125± 632

Navicula sp.

17883± 145

Nitzschia sp.

105± 6.3

Scenedes musdimorphus

6503± 101

Cymbella sp.

2005± 185

Amphora sp.

1959± 18.5

Tetraselmis sp.

Table 2: Analysis of combination and population density of microalgae produced in pounds during husbandry term.

According to the weight estimating results, showed in Table 3, always with the exception of 75th day, the growth line of A. parthenogenetica was 10- 40% higher than A. franciscana. Growth difference on the days15, 90 and 180 were less but on other days the difference had been growing. Also on the day 75th, on the contrary of other days, A. parthenogenetica's weight was more than A. franciscana.

Most of the A. parthenogenetica nauplii were obtained in 60th day. But then it was reduced up to 180th day. The largest numbers of A. parthenogenetica cysts were obtained in 75th day which have decreased until 180th day. The process of gradual reduction during the term had reached the least amount at 180th day (Table 4).

A. franciscana Wet Weight- gr

Husbandry Term- Days

A. partenogenetica Wet Weight- gr

50± 2.9

15

45

58± 4.5

30

32

55± 7.8

45

28

49± 6.1

60

38

49±2.3

75

53

41±3.5

90

37

56± 7.1

120

35

60± 5.0

150

47

63± 10.5

180

56

Table 3: Results of napulii weight and growth period population combination.

No. of Cysts

No. of Nauplii

Day

40±3

5± 0.35

15

151±10

11± 0.84

30

231±24

81± 9.1

45

254±30

97± 11.8

60

354±29

40± 6.5

75

158±17

19± 2.2

90

168±20

40± 5.1

105

170±25

33± 2.1

120

155±21

22± 1.2

150

140±17

11± 3.5

180

Table 4: Results of growth period population combination of Artemia species during the culture period of local Artermia (Artemia partenogenetica).

Results showed that the highest number of A. franciscana nauplii and cysts were obtained at day 45th. This production system of cysts and nauplious was gradually reduced and the lowest rate was reached at 180th day (Table 5).

No. of Cysts

No. of Nauplii

Day

82± 10.2

24± 2

15

125± 5.8

53± 6.1

30

226± 14.5

56± 8.5

45

139± 21.5

41± 2.8

60

110± 18.1

33± 1.9

75

103± 12.2

48± 6.2

90

86± 6.3

38± 6.8

106

98± 7.1

31± 8.2

120

90± 10.6

26± 1.3

150

73±11.2

25± 1.9

180

Table 5: Results of population combination of Artemia species during the culture period of A. franciscana.

The physicochemical factors of the trial pond (table 1), was determined according to the recommended procedure to measure the environmental factors [7].

Importance of Artemia as the live food source has been recognized as of 1930’s in aquaculture. For the time being, shrimp, various decorative and sea and caviar fish husbandry industry depend on Artemia [1,8], so that annually, more than 10000 tons of the same is produced and consumed in various countries all over the world. Whereas harvesting the Artemia cysts from global natural water sources such as Great Salt Lake, Urmia Lake and other relevant natural habitats indicate a significant decline due to a variety of reasons, therefore during recent year Artemia culture in pound, ponds and salty lakes and water drainages of the countries, especially those with arid and semi-arid climates is of high importance. Through culturing the Artemia species, while optimized utilizing the salty water sources of such countries, the same will be resulted in economic and social development and improves the employment and income conditions [9]. Using Iranian local and resistant Artemia specie is one of the reasons of achieving success in this regard. Therefore, in this study one of the Iranian local Artemia species together with globally commercial species, namely Artemia franciscana, were assessed in terms of production efficiency under similar culturing conditions. The results indicated that on 5% probability level (P<0.05), there is meaningful difference between the two species on the average daily cysts production during the culturing period and the local specie commences cysts generation after summer and in early fall in its natural environment, while it is not true in the case of Artemia franciscana. Such difference on cyst production is meaningful and indicates that A. franciscana species loses its cyst generation ration in comparison to local species.

Average number of nauplii during the first two months of husbandry is referred to the fact that local Artemia generates more nauplii than A. franciscana (Tables 4&5), which shows that the latter has less adaptability to the regional environment and also this situation gives similar results for the living conditions of meta nauplious, juveniles and adults. Local Artemia biomass production level during each term of culturing was equal to 3 ton/hectare, while the figure for A. franciscana ia 1.8 ton/hectare (table 3) and these figures are agreed with the studies conducted by Browne & Wanigasekera [10]. Therefore, development of local species husbandry centers in this region of Iran is more suitable and cost-effective for the economic purposes.

Introduction of non local races to the natural environments both damaging the local races genetic reserves and generates competitive biological interference between the two species. These results had compliance with those of the previous researches [11,9].

Considering the current conditions in most of the Middle Eastern and Central Asian countries and due to climatic changes, severe water sources loss, culturing Artermia local species for any region by taking benefit from the relevant salty water drainages creates development and increases the local people income as well as increases the employment and capital and decreases pressure implied to the relevant natural habitats. Meanwhile, this study is also agreed with the studies reported by van Stepan et al. [4] in other continents.

Each kilogram of Artemia is sold for 100 USD on average depending on the quality [2]. Growing the Artemia cysts in arid and semi-arid areas has a final cost ranging between 30 and 40 USD, and this is a cost-effective aquaculture and results in an increase in country’s power in the bottom line of aquaculture industry.
Development of rural areas, decreased unemployment and development of agriculture in arid and semi –arid countries having salty and semi-salty water sources is seen as one of the principal stapes in this regard [12]. In Artemia husbandry certain, water sources are used which have no application for agriculture and/or drinking industry [13].

Growing Artemia in saline and dead areas in any country with arid and semi-arid climate results in environmental protection (Table 1). Through economic assessments conducted on Artemia culturing showed that such farms are developed in areas exceeding 10000 hectares and the same will have an economic value of 5000 USD per 10 hectares for 10 employees.

Today, in addition to aquaculture industry, Artemia is also used for nanotechnology, pharmaceutics, as a source of human protein, radio-biology and production of pure salt as well as toxicology [4].

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