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Sains Malaysiana 46(12)(2017): 2339–2348 http://dx.doi.org/10.17576/jsm-2017-4612-10
Optimization Method for
Simultaneous Extraction and Detection of Imazapic and Imazapyr Herbicides in Soil and Water Using HPLC-UV with Verification of LC-MS
(Kaedah Pengoptimuman bagi Mengekstrak dan Mengesan Herbisid Imazapic dan Imazapyr secara Serentak dalam Tanah dan Air Menggunakan HPLC-UV dengan Ujian Pengesahan LC-MS)
BAJRAI, F.S.M.,* ISMAIL, B.S.
& MARDIANA-JANSAR, K.
School of Environmental and
Natural Resource Sciences, Faculty of Science & Technology
Universiti Kebangsaan Malaysia, 43600 UKM
Bangi, Selangor Darul Ehsan, Malaysia
Received: 5 December 2016/Accepted:
22 March 2017
ABSTRACT
The residual activity of
herbicides in soil and water may be detrimental to the environment. This issue
has caught the attention of environmentalists and among the herbicides
concerned are a mixture of Imazapic and Imazapyr, also known as OnDuty®,
which is currently being used in the Clearfield® Production System. These
herbicides are widely used to control weedy rice in rice fields. In order to
determine their residues in both soil and water, an accurate and simple method
of extraction has to be developed. In the present study, extraction processes
followed by HPLC-UV separation was developed and validated for
simultaneous determination of imazapic and imazapyr in two matrices, namely soil and water.
Verification of chemical compounds was then determined by using LC-MS (ToF). Recovery values of imazapic and imazapyr using 10 μM ammonium acetate extraction from blank samples spiked at levels between 1 mg L-1 and
10 mg L-1 in soil and water were 83% to 106% (with RSD ≤9%).
The limit of detection (LOD) ranged from 0.25 to 0.46 mg L−1 while
the limit of quantification (LOQ) was from 0.74 to 1.37 mg L-1. LC-MS (ToF) mass spectrum analyses of imazapyr and imazapic were
obtained at m/z 262.12 with the retention time of 2.39 min and m/z 276.13 with
the retention time of 3.06 min, respectively. This method would be helpful in
determining the level of pesticides in soil and water in a shorter time (< 6
min).
Keywords: Herbicides; HPLC-UV; LC-MS (ToF); imazapyr; imazapic
ABSTRAK
Aktiviti sisa herbisid di dalam tanah dan air boleh memudaratkan alam sekitar. Isu ini telah mendapat perhatian daripada pencinta alam sekitar dan antara herbisid berkenaan adalah campuran Imazapic dan Imazapyr, juga dikenali sebagai OnDuty®, yang kini digunakan dalam Sistem Pengeluaran Clearfield®. Herbisid ini digunakan secara meluas untuk mengawal rumpai padi di sawah padi. Dalam usaha untuk menentukan sisa racun tersebut dalam kedua-dua tanah dan air, maka satu kaedah yang tepat dan mudah untuk pengekstrakan perlu dibangunkan. Dalam kajian ini, satu kaedah pengekstrakan menggunakan 10 μM ammonium asetat diikuti oleh pemisahan HPLC-UV telah dibangunkan dan disahkan untuk penentuan serentak terhadap imazapic dan imazapyr dalam dua matrik, iaitu tanah dan air. Selanjutnya, ujian pengesahan sebatian kimia dilakukan dengan menggunakan LC-MS (ToF). Nilai pemulihan imazapic dan imazapyr dicapai dalam sampel kosong yang disuntik pada kepekatan antara 1 dan 10 mg L-1 di dalam tanah dan air adalah 83% hingga 106% (dengan RSD ≤9%) dengan had pengesanan (LOD) antara 0.25 hingga 0.46 mg
L-1 manakala had kuantifikasi (LOQ) adalah daripada 0.74 kepada 1.37 mg L-1. Analisis LC-MS (ToF) bagi mengenal pasti berat spektrum imazapyr dan imazapic masing- masing dapat dicapai pada m/z 262.12 dengan masa penahanan 2.39 min dan m/z 276.13 dengan masa penahanan 3.06 min. Kaedah ini akan dapat membantu dalam menentukan tahap herbisid dalam tanah dan air dalam masa yang singkat (<6 min).
Kata kunci: Herbisid; HPLC-UV; LC-MS (ToF); imazapic; imazapyr
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*Corresponding
author; email: ismail@ukm.edu.my
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