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Pre-concentration of pesticide residues in environmental water samples using Silica nanoparticles and identification of residues By GC-MS method

Tentu. Nageswara Rao1*, A. Muralidhar Reddy2, SNVS. Murthy3, Prathipati Revathi1 and K. Suneel Kumar4

1Department of Chemistry, Krishna University, Machilipatnam, Andhra Pradesh, India.

2Department of Chemistry, SKVP and Dr.K.S Raju Arts and Science College, Penugonda, AP, India.

3Department of Organic Chemistry, D.L.R. P.G. College, Gollalamamidada, AP, India.

4Techno Global University, Shillong, Maghalaya, India.

Corresponding Author Email: tentu6581@rediffmail.com

DOI : http://dx.doi.org/10.13005/ojc/320454

Article Publishing History
Article Received on :
Article Accepted on :
Article Published : 23 Aug 2016
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ABSTRACT:

The silica nanoparticles prepared by stober’s mechanism by reaction of tetraethylorthosilicate (TEOS) with ammonia was tested for their adsorption capacity in the pre-concentration of residues of pesticides in water. The synthesized nanoparticles were characterized by Scanning Electron Microscope (SEM), Transmission Electron Microscope (TEM) and X-Ray Diffraction (XRD). The size of the silica nanoparticles were 50 to 250 nm. The solid phase extraction (SPE) cartridges were prepared by filling the empty cartridges of 5.5 cm length and 0.3 cm i.d. with 200 mg of nanoparticles and protected between two polytetrafluroethylene (PTFE) frits. To avoid the passage of nanoparticles, 2% solution of polystyrene in chloroform was passed through PTFE frits and dried in air for two hours at room temperature before fitted into the cartridges. This process is to reduce the pore size of the PTFE frits. These cartridges are used in pre-concentration of different types of residues of pesticides in water. The pyrethroids tested for the pre-concentration are tetramethrin, lambda-cyhalothrin, cyphenothrin. The water samples were spiked with aliquots of pesticides and were passed through the cartridges. The amounts of the pesticides adsorbed on the cartridges were tested. The influence of temperature, sample volume, flow rate, pH and ionic strength on the performance of the cartridges was checked. The results of fortified sample analysis were compared with the data obtained from the commercially available C18 cartridges for the sample volume. The separation parameters were established for the simultaneous determination of residues using GC-EI-MS. The method was validated by means of linearity, precision, and assay accuracy. The limit of detection (LOD) and the limit of quantification (LOQ) were established based on the signal to noise ratio 3:1 and 10:1 respectively. An analytical method for the enrichment of residues using nanoparticles based SPE cartridges were developed and factors influencing the pre-concentration of residues of pyrethroids were studied and reported.

KEYWORDS:

Silica nanoparticles; Pyrethroids; Solid phase extraction; GC-EI-MS

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Rao T. N, Reddy A. M, Murthy SNVS, Revathi P, Kumar K. S. Pre concentration of pesticide residues in environmental water samples using Silica nanoparticles and identification of residues By GC-MS method. Orient J Chem 2016;32(4).


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Rao T. N, Reddy A. M, Murthy SNVS, Revathi P, Kumar K. S. Pre concentration of pesticide residues in environmental water samples using Silica nanoparticles and identification of residues By GC-MS method. Orient J Chem 2016;32(4). Available from: http://www.orientjchem.org/?p=20895


Introduction

Nanotechnology is an interdisciplinary area of research involving chemistry and physics which is growing rapidly for the past one decade. Nanoparticles have taken a key role in developing new drugs and pharmaceuticals for their smart delivery in selected tissue and organism. The widespread use of nanoparticles raised the eyebrows of many scientists to utilize their versatile applications in the field of aeronautics, agricultureenvironmental and health science1. The advantage of nanoparticles over other material is their smaller size and greater availability of surface area and lighter in weight. In the field of environmental science several nano catalysts2 are employed for the pre-concentration and selective decontamination of carcinogenic compounds. The residues of xenobiotics such as pesticides and relevant molecules which are likely to present in trace quantities have greater influence on the environment and human health3. The fate of pesticides used in the field depends on its properties such as evaporation; persistence, adsorption, leaching etc., and the presence of residues of pesticides contribute to the environmental water pollution mainly due to leaching and runoff4. Ground water is the most important source of drinking water; the accumulation of residues in the water reservoirs and other sources of water have direct effect not only on human population but also on aquatic organism5. Many pesticides have been shown to cause adverse effect in spite of their presence in trace quantities. To protect the environment from the toxic contaminants, several monitoring techniques are being employed. Continuous monitoring and the remedial measures are necessary to maintain the ecological balance in providing the human habitants a sustainable and safe living environment. In this process of modernization, the help of new techniques and technology has been derived to find for the new challenges. To detect the residues at nano and pico gram level it is necessary to enrich the residues from the bulk sample before subjected to the instrumentation techniques. Liquid – Liquid extraction is one method being used for the pre-concentration of residues past several decades6. Solid phase extraction (SPE) is the next development in enrichment of residues. The restrictions in use of organic solvent and their consumption in larger quantity have lead to the development of SPE techniques which is a simple solvent free technique. The SPE methods have become versatile due to the high adsorption capacity of the sorbent used and the preconcentration capacity of residues at nano gram level present in huge quantity of sample matrix. Nanoparticles are well known for the adsorption of many contaminants Solid phase extraction (SPE) is one such technique used widely for monitoring the environmental contaminations by enrichment of residues from the environmental substrates mainly from the aquatic strata7-8. This technique has the strength to quantify the environmental samples in larger quantity in a short span of time and does only limited resources. The residues present in several liters of water samples can be pre-concentrated within a small tiny cartridges subsequently can be eluted using small quantities of solvent for their estimation, minimizing the use of larger quantities of solvents. This process has the direct contribution to maintain sustainable clean and green environment apart from saving the money and time in doing such a critical analysis. The pre-concentration of residues of different type herbicides in water and at different pH conditions using nanoparticles based SPE cartridges9.  Nanoparticles are well known for the adsorption of many contaminants in water due to their high surface area. Alumina, Carbon10-11  and Silica particles are identified as well-known adsorbents. In recent years researchers discovered the capacity of nanoparticles in adsorbing many organic and inorganic contaminants present in the environmental substrates12-13 however still this need to be established applied for several such molecules. In view of the paucity of information, present study was conducted to investigate the capacity of silica nanoparticles as solid phase adsorbent in the pre-concentration of residues of pesticides. The lists of pyrethroids studied were tetramethrin, lambda-cyhalothrin, cyphenothrin. An analytical method was developed for the simultaneous determination of residues of pyrethroids using Liquid chromatography electro spray tandem mass spectrometry (GC-EI-MS).

Materials and Methods

Reference analytical standard of tetramethrin (purity 99.1%), cyhalothrin n (purity 99.6%) and cyphenothrin (purity 98.9%) were obtained from Sigma Aldrich. Tetraethylorthosilicate, Acetonitrile, Water HPLC grade, ammonia solution AR grade, and formic acid AR grade were obtained from the Merck India limited. Distilled water was purified by using the Milli-Q Plus apparatus (Millipore, Bedford, MA, USA). The environmental water samples were collected from different irrigation wells in Medak District, Telangana, India.

Preparation of silicananoparticles

Silica nanoparticles were synthesized following the method described by Stober. Tetraethylorthosilicate (0.1 ml) was dissolved in 10 ml of methanol and kept undisturbed at ~ 1°C for thirty minutes. To this solution 5 ml of 28% ammonium hydroxide solution was added drop wise. The contents were sonicated for 2 hours in floating ice bath. While sonication, slow formation of white precipitate can be seen. The resulting white precipitate at the end of two hour sonication was washed several times with milli Q water followed by methanol to remove the excess of ammonium hydroxide. The precipitate thus purified was centrifuged using a cooling centrifuge at 10°C and 7500 rpm. Collected the precipitate of silica nanoparticles by decanting the solvent and dried under nitrogen atmosphere in a desiccator.

Preparation of solid phase extraction cartridges (SPE) using nanoparticles

Two different SPE cartridges were prepared by filling the empty cartridges of size 0.3 mm i.d. and 5.5 cm length silica nanoparticles. The material was packed in between two PTFE frits. The normal pore sizes of these PTFE frits were found to be 0.2 μ, which is higher than the particle size of silica nanoparticles. To avoid the passage of nanoparticles, 2% solution of polystyrene in chloroform was passed through PTFE frits and dried in air for two hours at room temperature before fitted into the cartridges. This process is to reduce the pore size of the PTFE frits. The nanoparticles each 200 mg were packed in to the separate cartridges. The packed cartridges were conditioned with 10 ml of methanol, followed by 20 ml of milli Q water to remove the soluble impurities if any present in the cartridges. The conditioned cartridges thus prepared were used for the pre concentration of potential toxic pesticide residues present in water.

Preparation of Standard stock solutions

The stock solutions of reference analytical standards were prepared by weighing about 10 mg of respective herbicide of known purity in different 20 ml volumetric flasks using an analytical balance having accuracy of 0.01 mg. The content of each flask were dissolved using HPLC grade acetone and made up to the mark. A secondary stock solution was prepared in 20 mL volumetric flask by mixing the stock solutions together in appropriate volumes using micro micropipette and made up to the mark with acetonitrile.

Preparation of calibration solutions

The secondary stock solution thus prepared was diluted serially using HPLC grade acetone to give the calibration solutions. The linearity of the method was studied by analyzing standard solutions of at least six different concentrations in the range from 0.005 to 200 ng/mL. Presented the details of calibration solutions for the construction of linear graph in Table 1.

Table 1: Details of the calibration solutions used for the construction of linear graphs

SNo. Pyrethroids Concentrations in ng/mL
1 Tetramethrin  0.05, 0.1, 2.0, 5.0, 10.0, 50.0 & 100.0
2 Lambda-cyhalothrin 0.05, 0.1, 2.0, 5.0, 10.0, 50.0 & 100.0
3 Cyphenothrin 0.05, 0.1, 2.0, 5.0, 10.0, 50.0 & 100.0

 

Experimental

GC-EI-MS conditions for the determination and confirmation of residues of pyrethroids

The configuration of GC–MS system used includes a (Agilent/ 6890N) gas chromatograph coupled with 5975C Mass-Selective Detection (MSD) and Chemstation software, the detector was set in selective ion monitoring mode (EI) mode. The peaks separation were obtained on a DB-1 capillary column (30 m length, 0.25 mm internal diameter, 0.25µm film thickness). The injection system was operated in split mode with a split ratio of 10:1. The injector and the transfer line temperatures were 295ºC and 300ºC, respectively. column oven temperature was programmedfrom 100°C for 3 minutes, increased at 10°C to 290°C. The carrier gas used was helium (GC grade) at a flow rate of 1.0 ml /min and the sample volume injected onto the column was 1.0 µL. A Agilent Chemstation Software was used for acquisition of data and calculation of peak areas. The retention time of tetramethrin, lambda-cyhalothrin, cyphenothrin were about 7.9 min, 9.5 and 10.5 min and the total time of chromatographic analysis was 8.0 min.

Preparation of calibration curves

A calibration curve was plotted between concentrations of standard solutioninjected and peak area observed (Figure. 1). The LOD was established based on thesignal to noise ratio 3:1. No peak overlapping was observed while quantifying theresidues of pyrethroids using this method. All the residues of pyrethroids are presented with an abundant molecular ion peak. Residues were quantified using the molecular ion peak fragments. At least two molecular ion fragments were used for quantification of pyrethroid residues in water. The details regarding the limit of detection by GC-MS, retention time, molecular mass, fragmentation ions used for quantification of residues were presented in Table 2.

Table 2: The details of linear calibration range, Limit of detection, Fragment ions used in  MRM  mode for different pyrethroids.  

             Pyrethroids Retention time (min) Linearity range (ng/mL) R2 LOD (ng/mL) Molecular mass (m/Z) Fragment ions (m/Z) used for Quantification
Tetramethrin 7.9 0.05 – 100 0.9995 0.05 331 164, 123
Lambda-cyhalothrin 9.5 0.05 – 100 0.9998 0.05 449 181, 197
Cyphenothrin 10.5 0.05 – 100 0.9999 0.05 375 123, 181

Assay accuracy and repeatability

The assay accuracy of the method was evaluated by spiking two different concentrations 0.05 and 0.5 ng/mL of herbicide mixture in 500 mL of milli Q water. The repeatability of the method was determined by analyzing six replicate samples at each concentration level along with two controls for the identification of interferences. The concentration of the solvent present in the spiked water sample was not exceeded 0.1%. After spiking, the water samples were mixed thoroughly, equilibrated and maintained at 20 + 2°C in temperature controlled water bath and passed through the cartridges by means of suction with flow rate 3 to 4 ml per minute. The cartridges were dried under vacuum and residues were then eluted using 5 ml of HPLC grade acetone. Based on the recovery percentage the limit of quantification was established. The average recovery percentage for each pyrethroid in milli Q water was presented in Table 3. The representative GC-EI-MS total ion chromatogram of recovery sample is presented in Figure. 2 and GC-EI-MS spectra for each compound were presented in Figure. 3.

Table 3:  Average recovery of herbicide residues using nanoparticles based SPE cartridges

Pyrethroids Recovery % in Silica nanoparticles
0.05 µg/mL 0.5 µg/mL
Tetramethrin 83 90
Lambda-cyhalothrin 85 92
Cyphenothrin 84 94
 Figure. 1. Calibration of pyrethroids using GC-EI-MS Figure 1: Calibration of pyrethroids using GC-EI-MS 


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Figure. 2. Representative GC-EI-MS total ion chromatogram – recovery of pyrethroids by using silica nanoparticles cartridge Figure 2: Representative GC-EI-MS total ion chromatogram – recovery of pyrethroids by using silica nanoparticles cartridge

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Figure. 3. GC-EI -MS mass spectra of pyrethroids Figure 3: GC-EI -MS mass spectra of pyrethroids

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Effect of flow rate

The influence of flow rate in pre-concentration of residues was checked by conducting recovery study at flow rates 1-2 mL, 3-4 mL, 5-6 mL and 8-10 mL/min. The flow rates were controlled using vacuum attached to SPE manifold. At these flow rates, 0.1 µg/mL concentration level of samples were passed through the cartridges and quantified the adsorbed residues in the cartridges by eluting the residues with acetonitrile. Presented the results graphically in Figure 4.

 Analysis of pre-concentration capacity of SPE cartridges – influence of sample volume

The efficiency of cartridges was tested with different sample volumes from 500 mL to 3000 mL. The efficiency of these nanoparticles based cartridges was compared with conventional C18 cartridges. The results are presented graphically in Figure. 5.

Figure. 4. Effect of flow rate in pre-concentration of pyrethroid residues Figure 4: Effect of flow rate in pre-concentration of pyrethroid residues

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 Figure. 5. Effect of sample volume in pre-concentration of pyrethroid residues Figure 5: Effect of sample volume in pre-concentration of pyrethroid residues 


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Effect of pH, ionic strength and temperature

The influence of pH in pre-concentration of residues was investigated by adjusting pH of the water samples using 0.1% hydrochloric acid and 0.1% sodium hydroxide solutions. After adjusting the desired pH, spiked the water samples at 0.01 and 0.1 ng/mL levels of herbicide mixture. The spiked sample (500 mL) was passed through the cartridges. During this experiment the temperature of the water was maintained at 20 + 2°C. The experiment was carried out at four different pH levels 5, 6, 7, and 8. The influence of pH in pre-concentration of herbicide residues was presented graphically in Figure. 6. The effect of ionic strength was checked by spiking the residues of pyrethroids in 0.1% and 1% sodium chloride solution in distilled water at 20 + 2°C. The influence of ionic strength in the pre-concentration of residues using nanoparticles based cartridges was presented graphically in Figure. 7. The effect of temperature on the adsorption of the residues by nanoparticles based SPE cartridges was tested in the range 10 to 50°C. After spiking, the water samples were allowed to equilibrate in temperature controlled water bath for 30 minutes. After equilibration 500 mL of sample solution was passed through the cartridges at the flow rate of 3 – 4 mL/minute. The experiment was conducted at five different temperatures viz., 10 + 2, 20 + 2, 30 + 2, 40 + 2 and 50 + 2°C. The effect of temperature was presented graphically in Figure. 8.

Figure. 6. Effect of pH in pre-concentration of herbicide residues Figure 6: Effect of pH in pre-concentration of herbicide residues

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Figure. 7. Influence of ionic strength in pre-concentration of pyrethroid residues Figure 7: Influence of ionic strength in pre-concentration of pyrethroid residues

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Figure. 8. Effect of temperature in pre-concentration of pyrethroid residues Figure 8: Effect of temperature in pre-concentration of pyrethroid residues

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Results and Discussion

Description of silica nanoparticles

The characterizations of the nanoparticles were done by the SEM, TEM and XRD. The size of silica nanoparticles 50 to 250 nm length. The scanning electron microscope (SEM), transmission electron microscope (TEM) and X-ray diffraction (XRD) images of silica nanoparticles were presented in Figure. 9, Figure. 10 and Figure. 11.  Using the XRD pattern the size of the nanoparticles were calculated by “Debye scherrer” equation Where, D is the average crystalline size, λ the X – ray wavelength, β the angular line width at half maximum intensity, θ Bragg’s angle.

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Figure. 9. Scanning Electron Microscope image of Silica nanoparticles Figure 9: Scanning Electron Microscope image of Silica nanoparticlesClick here to View figure

 

Effect of flow rate

The effect of flow rate in pre-concentration of residues of pyrethroids was tested with nanoparticles based silica nanoparticles based SPE cartridges. The study result shows that the increase in flow rate decreases the pre-concentration efficiency of the SPE cartridges. The recovery of pyrethroids was found to be higher with the flow rates 1 to 4 mL/minute. The nominal flow rate for the pre-concentration of pyrethroids in water was established as 3-4 mL/minute. The increase in flow rate > 5 mL/min showed decrease in recovery percentage.

Sample volume – adsorption capacity

A comparative study of nanoparticles based SPE cartridges with conventional C18 cartridges was conducted to determine the effect of silica nanoparticles based SPE cartridges against C18 cartridges. From the analysis it was observed that the silica nanoparticles based cartridges exhibited more capacity to trap the residues of herbicide when compared with the conventional C18 cartridges. The adsorption capacity of the C18 cartridges and silica nanoparticles based cartridges was reduced after passing 1000 mL of fortified water samples. The nominal sample volume for these two cartridges was 1000 mL.

Figure. 10. Transmission Electron Microscope image of Silica nanoparticles

Figure 10: Transmission Electron Microscope image of Silica nanoparticles

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Effect of pH

The effect of pH in pre-concentration of herbicide residues was studied by adjusting pH of water samples using 0.1% hydrochloric acid or 0.1% sodium hydroxide solution. From the study it was observed that the nominal pH for the pre concentration of pyrethroids is 5 to 8. The reduction in recovery percentage was observed at pH < 5 and pH > 8.

Effect of ionic strength

From the result it was observed that no significant change in the pre concentration capacity of residues was observed due to variation in ionic strength. The recovery of pyrethroids in silica nanoparticles based cartridges is in the range 85 to 97dx%.

Figure. 11. XRD patterns of Silica nanoparticles Figure 11: XRD patterns of Silica nanoparticlesClick here to View figure

 

Effect of temperature

The study on the effect of temperature on the adsorption of residues indicated decrease in recovery of the pyrethroids at high temperature. The recoveries of the pyrethroids are found stable when conducted the studies between 10 to 40°C. The tested concentrations were 0.01 and 0.1 ng/mL. The recovery of triazine pyrethroids in silica nanoparticles based SPE cartridges were in the range 84 to 97% with milli Q water equilibrated at 10 + 2 and 20 + 2°C; 81 to 95% at 30 + 2°C and 40 + 2°C. The percentage of recovery reduced to 56 to 71% when analyzed the sample at 50 + 2°C.

Conclusions

The study on applications of nanoparticles in the pre-concentration of residues of certain pyrethroids in water showed silica nanoparticles have the capacity to adsorb the residues of pyrethroids in water. The results are comparable with C18 cartridges. The recovery of residues was not influenced by pH or temperature. However extreme pH’s and temperatures reduces the recovery to a greater extent. The ionic strength, flow rate and sample volume has moderate impact on the recovery. The new analytical method developed for the simultaneous determination of residues of pyrethroids by GC-EI/ MS has the LOD and LOQ at sub-nano gram level as evidenced by recovery study conducted in water samples. From the analysis it was concluded that the nanoparticles based SPE cartridges was found successful in the pre-concentration of residues of pesticides in water. The performance of silica nanoparticles based cartridges was shown high recoveries. Thus silica nanoparticles very good option to utilize as solid support for the pre concentration of residues of environmental toxicants in water. The cartridges withstands high load of water samples to pass through for the pre-concentration of residues at trace levels which is an advantage over other conventional columns.

Acknowledgement

The authors are thankful to the Dr. B. Gowtam Prasad, SVV University for keen interest to conduct the experiment.

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