Sains Malaysiana 41(5)(2012): 573–583

 

Penggunaan Biomonitor Multispesies Air Tawar dalam Menilai Perubahan Kelakuan Ikan Gapi,

Poecilia reticulata dan Udang Air Tawar, Macrobrachium lanchesteri Terhadap

Air Larut Resap  dari Tapak Pelupusan Sampah

(Use of Multispecies Freshwater Biomonitor to Assess Behavioural Changes of Guppy, Poecilia reticulata  and Freshwater Prawn, Macrobrachium lanchesteri in Response to Leachate from Landfill)

 

Z. Nurul-Akhma, M. Shuhaimi-Othman* & M. Azmah

Pusat Pengajian Sains Sekitaran dan Sumber Alam, Fakulti Sains dan Teknologi,

Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Selangor D.E. Malaysia

 

Received: 18 August 2011 / Accepted: 18 November 2011

 

 

ABSTRAK

 

Biomonitor Multispesies Air Tawar (MFB) digunakan bagi mengukur dan menganalisis pelbagai kelakuan daripada pelbagai jenis organisma akuatik untuk memantau kualiti air dalam ekosistem air tawar. Isyarat gerak balas udang air tawar (Macrobrachium lanchesteri) dan ikan gapi (Poecilia reticulata) dikaji di dalam makmal bagi menentukan respons yang spesifik terhadap pendedahan kepekatan air larut resap yang berbeza (1%, 3% dan 5%) bagi kedua-dua organisma. Perubahan perilaku organisma (pergerakan dan ventilasi) direkodkan dengan menggunakan Biomonitor Multispesies Air Tawar (MFB) selama 24 jam. Hasil yang diperoleh menunjukkan terdapat trend peningkatan respons pergerakan dan ventilasi yang jelas dengan peningkatan kepekatan pendedahan air larut resap bagi udang air tawar. Manakala respons yang ditunjukkan oleh ikan gapi adalah tidak begitu jelas walaupun terdapat trend pengurangan pergerakan dengan peningkatan kepekatan pendedahan air larut resap dan trend peningkatan ventilasi dengan peningkatan kepekatan pendedahan. Kajian ini menunjukkan M. lanchesteri memberikan respons yang lebih sensitif kepada air larut resap berbanding P. reticulata dan organisma ini lebih sesuai digunakan sebagai organisma penunjuk untuk MFB.

 

Kata kunci: Kelakuan; Macrobrachium lanchesteri; pencemaran air; poecilia reticulata

 

 

ABSTRACT

 

The Multispecies Freshwater Biomonitor (MFB) was used to measure and analyse different types of behaviours from different aquatic organisms for monitoring water quality in freshwater ecosystems. The signal response of freshwater shrimp (Macrobrachium lanchesteri) and guppy fish (Poecilia reticulata) was studied in the laboratory to determine the specific response of both organisms to different concentrations of leachate (1%, 3% and 5%). Behavioural changes were recorded by using Multispecies Freshwater Biomonitor (MFB) for 24 h. Our results showed that the behavioural and ventilation responses of freshwater shrimp increased with increasing exposure to concentrations of leachate. However, the responses shown by guppy fish was not clear although there was a trend of reduction in the behavioural responses with increasing exposure and increasing ventilation responses with increasing exposure to leachate. Results also showed that the M. lanchesteri was more sensitive to leachate than P. reticulata and this organism was more suitable as indicator organism for the MFB.

 

Keywords: Behaviour; Macrobrachium lanchesteri; Poecilia reticulata; water pollution

 

REFERENCES

 

Agamuthu, P. 2001. Solid Wastes: Principles and Management with Malaysian Case Studies. Kuala Lumpur: University of Malaya Press.

Akta Kualiti Alam Sekeliling. 1974. Peraturan-Peraturan Kualiti Alam Sekeliling (Kumbahan dan Effluen-Effluen Perindustrian) 1979. Kuala Lumpur International Law Book Services.

Alabaster, J.S. & Lloyd, R. 1980. Water Quality Criteria for Freshwater Fish for the Food and Agricultural Organisation. Butterworths: United Nations.

Ali, S. 2009. Kawasan Pelupusan Sampah Negara Semakin Krikital? http://www.kpdnkk.gov.my/.html [1 Mei 2011].

Alkassasbeh, J.Y.M., Heng, L.Y. & Surif, S. 2009. Toxicity testing and the effect of landfill leachate in Malaysia on behavior on Common Carp (Cyprinus carpio L., 1758; Pisces, Cyprinidae). American Journal Environmental Sciences 5 (3): 209-217.

APHA. 1992. Standard Methods for the Examination of Water and Wastewater. 18th edition. Washington American Public Health Association (APHA).

Bagchi, A. 1994. Design, Construction and Monitoring of Landfills. Edisi ke-2. New York: John Wiley & Sons.

Berge, N.D., Reinhart, D.R. & Townsed, T.G. 2005. The fate of nitrogen in bioreactor landfills. Journal of Critical Reviews in Environmental Science and Technology 35: 365-399.

Cairns, J.Jr. & Van der Schalie, W.H. 1980. Biological monitoring part I: early warning system.Water Resources 14: 1179-1196.

Crutcher, A.J. & Yardley, J.R. 1992. Implications of changing refuse quantities andcharacteristics on future landfill design and operations. Dlm. Municipal Solid Waste Management: Making Decissions in the Face of Uncertainty, disunting oleh Haight, M.E. hlm.171-195. Waterloo Ontario: University of Waterloo Press.

DeLonay, A.J., Little, E.E., Lipton, J. & Hansen, J.A. 1997. Behavioral avoidance asevidence of injury to fishery resources: applications to natural resource damage assessments. Dlm. Environmental Toxicology and Risk Assessment: Biomakers and Risk Assessment, disunting oleh LaPoint T.W., Price, F.T. Little E.E., 4th vol. ASTM STP 1262, hlm. 268-280. Philadelphia: American Society of Testing and Materials (ASTM).

DOE (Department of Environment Malaysia). 2002. Malaysia Environmental Quality Report 2001. Department of Environment, Ministry of Science, Technology and Environment Malaysia

Futta, D., Yoscos, C., Haralambous, K.J. & Loizidou, M. 1997. An assessment of the effect of landfill leachate on groundwater quality. Proceeding Sardina 97. Sixth. International Landfill Symposium: 181 – 187.

Gerhardt, A. 1992. Review of heavy metals on stream invertebrates with special emphasis o acid conditions. Water Air Soil Pollution 66: 289-314.

Gerhardt, A. 1998. A new biomonitor system based on magnetic inductivity for freshwater and marine environment. Environment International 24(7): 699-701.

Gerhardt, A., Clostermann, M., Frilund, B., Svensson, E. 1994. Monitoring of behavioral patterns of aquatic organisms with an impedance conversion technique. Environment International 20: 209-219.

Gerhardt, A., Janssens de Bisthoven, L., Mo, Z., Wang, C., Yang, M. & Wang, Z. 2002. Short- term responses of Oryzias latipes (Pisces: Andrianichthyidae) and Macrobrachiumnipponese (Crustacea: Palaemonidae) to municipal and pharmaceutical wastewater in Beijing, China: survival, behavior, biochemical biomarkers. Chemosphere 47: 35-47.

Gerhardt, A., Janssens de Bisthoven, L. & Soares, A.M.W.M. 2004. Macroinvertebrate responses to acid mine drainage: community and on-line behavioral toxicity bioassay. Environmental Pollution 130: 120-131.

Gerhardt, A., Janssens de Bisthoven, L. & Soares, A.M.W.M. 2005. Evidence for thestepwise stress model: Gambusia holbrooki and Daphnia magna under acid mine drainage and acidified reference water stress. Environmental Science and Technology 39: 4150-4158.

Girard, J. 2005. Principles of Environmental Chemistry. Canada: Jones and Bartlett Publishers.

Gruber, D., Frago, C.H. & Rasnake, W.J. 1994. Automated biomonitors-first line of defense. Journal of Aquatic Ecosystem Health 3: 87-92.

HACH. 2003. The Handbook of DR/2500 Laboratory Spectrophotometer. HACH Company, USA.

Hammer, M.J. 1996. Waste and Wastewater Engineering. New Jersey: Prentince Hall Inc.

Isidori, M., Lavorgna, M., Nardelli, A. & Parrella, A. 2003. Toxicity identification evaluation of leachates from municipal solid waste landfills: a multispesies approach. Chemosphere 52: 85-94.

Janssens de Bisthoven, L., Gerhardt, A., Guhr, K. & Soares, A.M.V.M. 2006. Behavioral changes and acute toxicity to the freshwater shrimp Atyaephyra desmaresti Millet (Decapoda: Natantia) from exposure to acid mine drainage. Exotoxicology 15: 215-227.

Jokela, J.P.Y. & Rintala, J.A. 2003. Anaerobic solubilisation of nitrogen from municipal solid waste (MSW). Reviews in Environmental Science and Biotechnology 2: 67–77.

Karnchanawong, S. & Limpiteeprakan P. 2006. Heavy metal contamination in leachate caused by spent household batteries in municipal wastes. Journal of Research in Engineering and Technology 3: 279-289.

Kjeldsen, P., Barlaz, M.A., Roxker, A.P., Baun, A., Ledin, A. & Christensen, T.H. 2002. Present and long-term composition on MSW landfill leachate: a review. Critical Reviews in Environmental Science and Technology 32(4): 297-336.

Koshy, L., Paris, E., Ling, S., Jones, T. & BéruBé, K. 2007. Bioreactivity of leachate from municipal solid waste landfill – assessment of toxicity. Journal of Science of the Total Environment 384: 171-181.

McBean, E.A., Frank, F.A. & Farquhar, G.J. 1995. Solid Waste Landfill Engineering and Design. New Jersey: Prentice-Hall PTR.

Ministry of Housing and Local Government, Malaysia (MHLG), 2005. National Strategic Plan for Solid Waste Management. vol. 1. The Strategic Plan. Kuala Lumpur Local Government Department.

Penders, E.J.M, Nieuwegein, W.R.K., Hoogenboezem, W. & Haarlem, P.W.N. 2001 Biological Tests, A Suitable Instrument for the Quality Control of Surface Water? Association of River Waterworks – RIWA.

Renou, S., Givaudan, J.G., Poulain, S., Dirassouyan, F. & Moulin, P. 2008. Landfill leachate treatment: review and opportunity. Journal of Hazardous Materials 150: 468-493.

Shuhaimi-Othman, M., Azmah, M. & Ahmad, A.K. 2010a. Penggunaan biopenunjuk multispesies air tawar dalam menilai perubahan kelakuan ikan gapi, Poecilia reticulate dan udang air tawar, Macrobrachium lanchesteri terhadap logam kadmium. Sains Malaysiana 39(4): 549-555.

Shuhaimi-Othman, M., Nadzifah, Y. & Ahmad, A.K. 2010b. Toxicity of Copper and Cadmium to Freshwater Fishes. World Academy of Science and Technology 65: 1173-1176.

Shuhaimi-Othman, M., Nadzifah, Y., Nur-Amalina, R. & Ahmad, A. 2011. Sensitivity of thefreshwater prawn, Macrobrachium lanchesteri (Crustacea: Decapoda), to heavy metals Toxicology and Industrial Health 27(6): 523-530.

Yusof, N., Haraguchi, A., Hassan, M.A., Othman, M.R., Wakisaka, M. & Shirai, Y. 2009. Measuring organic carbon, nutrients and heavy metals in rivers receiving leachate from controlled and uncontrolled municipal solid waste (MSW) landfills. Waste Managment 29: 2966-2680.

 

 

*Corresponding author; e-mail: shuhaimi@ukm.my

 

 

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