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eISSN: 2378-3184

Aquaculture & Marine Biology

Short Communication Volume 6 Issue 5

Cultivation of the Microalga Thalassiosira weissflogii to feed the Rotifer Brachionus rotundiformis

AA Ortega Salas,1 Pedro Flores Nava2

1Unidad Acad mica Mazatl n Instituto de Ciencias del Mar y Limnolog a M xico
2Facultad de Ciencias del Mar Universidad Aut noma de Sinaloa M xico

Correspondence: AA Ortega Salas Unidad Acad mica Mazatl n Instituto de Ciencias del Mar y Limnolog a UNAM Calzada Joel M M xico

Received: November 09, 2017 | Published: December 7, 2017

Citation: Ortega-Salas AA, Nava PF (2017) Cultivation of the Microalga Thalassiosira weissflogii to feed the Rotifer Brachionus rotundiformis . J Aquac Mar Biol 6(5): 00169 DOI: 10.15406/jamb.2017.06.00169

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Abstract

The microalga Thalassiosira weissflogii (Grunow) Fryxell and Hasle, 1977 was cultivated to find its adequate concentration to feed the rotifer Brachionus rotundiformis Tschugunoff, 1921. The microalgae and rotifers were reared separately; microalgae cultures used Guillard and Ryther F/2 medium in transparent 19 L plastic bottles, yielding 16 L of the useful crop; agitation was kept constant by bubbling compressed air filtered at 1 µm; lighting was continuous through six white daylight fluorescent lamps. The temperature ranged between 23.1° and 24.9°C, and disinfection was with commercial sodium hypochlorite at5%, which was eliminated at a rate of 0.06 gL-1 sodium thiosulfate, then the F/2 nutrients were added. Rotifers in 15 L plastic containers were fed daily on T. weissflogii at 2.469 x 105cells∙mL1; Crops were harvested every third day (48 h). T.weissflogii cultures maintained for 48h achieved concentrations adequate to feed these rotifers.

Keywords: Cultivation; Food of rotifers; Nutrient addition; Microalgae density; Thalassiosira weissflogii

Introduction

Rotifers are a useful source of food in aquaculture [1]. Their nutritional content is enhanced if they are fed on algae, particularly in terms of vitamins and essential fattyacids. The algal genera most frequently used for this purpose are Chaetoceros, Thalassiosira, Isochrysis, Nannochloropsis and Tetraselmis [2]. The diatom T. weissflogii (size 6-15μm x 20 μm) is used as food for shrimp and in the production of bivalve larvae. This alga is considered by several hatcheries to be the best for growing shrimp larvae since it is a rich source of eicosapentaenoic acid (EPA) and docosahexaenoic acid DHA, essentials for growth and development of marine organisms [3-6].

Emmerson [3] reported that Penaeus indicus larvae at the zoea 1 stage ingested T.weissflogii at a rate of 2.5x103cells•ind-1•h-1.

In this work, the microalga Thalassiosira weissflogii (Grunow) Fryxell and Hasle, 1977 was cultivated under conditions that sought to improve its production rate and to achieve a concentration adequate to feed the rotifer Brachionus rotundiformis Tschugunoff, 1921under laboratory conditions.

Materials and Methods

The diatom T.weisflogii (collection keyTH-W-1) was obtained from the collection of the Department of Aquaculture, Center for Scientific Research and Higher Education, Ensenada, Baja California. Culture used F/2 medium [5] with twice metasilicate. Seawater was pumped from the Bay of Mazatlán and passed through a filter system in series, with progressive particle retention of 10,5 and 1μm; an additional activated carbon filter removed organic compounds.

The temperature ranged between 23.1 and 24.9±0.52°C. The water was disinfected with1 mL•L-1 commercial sodium hypochloriteat 5%, at least24 h before use. Free chlorine residues were removed with 0.06g of sodium thiosulfate per liter of water, accelerating the process of neutralization by vigorous shaking aeration for 20 to25 minutes. Subsequently, the absence of free chlorine was confirmed by the traditional colorimetric technique using a commercial kit with ortho-toluidineasa indicator. Nutrient solutions were added until the F formulation was achieved.

In order to have the required daily amount of microalgal biomass, T.weissflogii cultures were maintained in F medium for 48h to obtain adequate concentrations of microalgae to feed rotifers. Cultures were performed in clear plastic bottles of 19L, with16 L of a useful crop; stirring was kept constant by bubbling with filtered compressed airat1 micron. This served to keep the algae in suspension, and encouraged mixing, which was intended to accelerate the exchange of gases between the culture medium and the atmosphere, removing excess photosynthetic oxygen and facilitating the dissolution of CO2 in the medium. Lighting was continuous through six white day light fluorescent lamps.

Before rotifers were fed, the adequate cell concentration of the T. weissflogii was verified by direct counts in a compound microscope using a hemocytometer 0.1 mm deep, equipped with a Neubauer rule. Every 24 h, samples of the culture were taken to check their condition and their stability by optical density reading sina Hach DR 5000spectrophotometerata wavelength of 550 μm. The viability of the culture was monitored by pH readings of each culture vessel with a portable potentiometer rCHEK-MITE Corning model pH-10, pre-calibrated with buffers of 7.0 and10.0units; this was done in order to prevent high pH values​​ due to a rapid use of bicarbonates, leading to a limitation of substrates for photosynthesis and hence to maturation of the crop before harvest time, or a switch to the stationary phase or death. Cells were counted at 24 and 48 h and were harvested at 48 h when the cultures were in the exponential growth phase.

Results

An initial concentration of 0.101x 105cells∙mL-1 increased to 0.723x105cells∙mL-1 at 24h and to 2.469x105cells∙mL-1 at 48h, the end of each set of cultures (Table 1). Crops were harvested every third day. These cell concentrations indicated that 2.854 T.weissflogii cell divisions had occurred in the first 24h, and a further 1.772 at 48h, a total of 4.626 at the time of harvesting.

Hours

CC

pH

OD

0

0.101 ± 0.008

8.094 ± 0.253

0.044 ± 0.003

24

0.723 ± 0.164

8.422 ± 0.171

0.062 ± 0.004

48

2.469 ± 0.522

9.084 ± 0.183

0.110 ± 0.006

Table 1: Culture of T.weissflogii: cell concentration (CC, 105cells∙mL-1), pH and optical density (OD).Values: average ​​± standard deviation.

The cultures from which the samples were obtained to estimate the weight of the microalgae had a cell concentration of1.903x105cells∙mL-1; these crops produced at the time of harvest at 48 ha dry biomass of 114.131mg∙mL-1, and the organic content was 66.681mg∙mL-1. With the above values, the unit dry biomass is estimated at 603.363±52.896pg∙cells-1, and unit organic content of352.801±29.697pg∙ cells-1, and 58 511% of the dry weight was organic matter (Table 2).

CC

DW

OW

DWU

OWU

OW/DW

105cells∙mL-1

µg∙mL-1

µg∙mL-1

pg∙cells-1

pg∙cells-1

%

1.903 ± 0.171

114.131 ± 6.645

66.681 ± 2.200

603.363 ± 52.896

352.801 ± 29.692

58.511 ± 1.687

Table 2: Thalassiosira weissflogii sampled after 48 h culture for weight determinations: cell concentration(CC, 105cells∙mL-1), dry weight (DW) and organic weight (OW) inmg∙mL-1, dry weight per unit (DWU) and organic weight unit(OWU) pg∙cells-1, percentage of organic matter in the dry weight(OW/ DW).Values: Average ± standard deviation.

B.rotundiformis cultures were maintained at a temperature of 26.6±0.771 and 27.8±0.830°C. The pH values ​​in all recipients ranged from 7.85 to 8.19, with a mean value of 8.03. Average daily rotifer density obtained was 131.5±14.153rot∙mL-1; this amount was enough to feed three stages of mysislarvae of Litopenaeus vannamei (Boone, 1931). pH values increased from 8.094 at 0 h to 9.084 at 48 h. The optical density increased from 0.044 at 0 h to 0.110 at 48 h.

Discussion

Bermúdez-Lizárraga [1] also used T. weissflogii to feed rotifers, but the present study has confirmed that after culture for 48 h under the conditions described here, the crop is of sufficient concentration to feed rotifers and larvae of shrimp.

Flores-Nava [4] found that the density of T.weissflogii supplied to zoe a larvae of L.vannamei did not influence the growth, survival, and development of the larvae.

The diatom T.pseudonana (Cleve, 1873) is the only diet that has been found to produce rotifers with the required complement of n3 polyunsaturated fatty acids suitable for larval fish rearing [6], but here we have used T. weissflogii to feed rotifers with good results.

Conclusion

T.weissflogiicultures maintained for 48h achieved adequate concentrations to feed the rotifer B. rotundiformis which later can be used to feed shrimp larvae.

Acknowledgements

To the Faculty of Marine Science of the Autonomous University of Sinaloa for provision of equipment and laboratory facilities, and to Dr. Pablo Piña Valdez, Director of the Master of Science thesis of the second coauthor. Thankful to Dr. Ann Grant help us to write this paper.

Conflict of Interest

None.

References

  1. Bermudez Lizárraga JF (2009) Evaluación de Brachionusrotundiformis como alimento vivo para las larvas de Litopenaeus vannamei. Tesis de Maestría en Ciencia en pesquerías sustentables. Instituto Tecnológico de Mazatlá Mazatlán, Sinaloa, México pp.55.
  2. Duerr EOA Molnar, V Sato (1998) Cultured microalgae as aquaculture feeds. Journal of Marine. Biotechnology 7: 65-70.
  3. Emmerson WD (1980) Ingestion, growth and development of Penaeusindicus larvae as a function of Thalassiosira weissflogii cells concentration. Marine Biology 58(1): 65-73.
  4. Flores Nava P (2008) Crecimiento, desarrollo y supervivencia de larvas zoea de Litopenaeus vannamei alimentadas con Thalassiosira weissflogii. Tesis de Licenciatura Biólogo Pesquero. Facultad de Ciencias del Mar. UAS, Mazatlán, Sinaloa, México pp. 41
  5. Guillard RRL, Ryther JH (1962) Studies of marine planktonic diatoms, Cyclotella nana (Hustedt) and Detonula confervacea (Cleve) Can J Microbiology 8: 229-239.
  6. White JNC, Nagata WD (1990) Carbohydrate and fatty acid composition of the rotifer, Brachionus plicatilis, fed monospecific diets of yeast or phytoplankton. Aquaculture 89 (3-4): 263-272.
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